ArticleFebruary 11, 2026

Surface Chemistry in the Initial Stages of Titanium Nitride Atomic Layer Deposition Using Operando Ambient Pressure X-ray Photoelectron Spectroscopy
Click to copy article linkArticle link copied!

Pamburayi Mpofu*
Pamburayi Mpofu
Department of Physics, Chemistry and Biology, Linköping University, 581 83 Linköping, Sweden
*[email protected]
More by Pamburayi Mpofu
https://orcid.org/0000-0003-0878-9248
Peggy Bagherzadeh Tabrizi
Peggy Bagherzadeh Tabrizi
Department of Physics, Chemistry and Biology, Linköping University, 581 83 Linköping, Sweden
More by Peggy Bagherzadeh Tabrizi
Houyem Hafdi
Houyem Hafdi
Department of Physics, Chemistry and Biology, Linköping University, 581 83 Linköping, Sweden
More by Houyem Hafdi
Premrudee Promdet
Premrudee Promdet
Department of Physics, Chemistry and Biology, Linköping University, 581 83 Linköping, Sweden
More by Premrudee Promdet
Jonas Lauridsen
Jonas Lauridsen
Seco Tools AB, 737 82 Fagersta, Sweden
More by Jonas Lauridsen
Oscar Alm
Oscar Alm
Seco Tools AB, 737 82 Fagersta, Sweden
More by Oscar Alm
Tommy Larsson
Tommy Larsson
Seco Tools AB, 737 82 Fagersta, Sweden
More by Tommy Larsson
Rosemary Jones
Rosemary Jones
MAX IV Laboratory, Lund University, Box 118, 221 00 Lund, Sweden
Division of Synchrotron Radiation Research, Department of Physics, Lund University, Box 118, 221 00 Lund, Sweden
More by Rosemary Jones
https://orcid.org/0000-0001-6273-4243
Esko Kokkonen
Esko Kokkonen
MAX IV Laboratory, Lund University, Box 118, 221 00 Lund, Sweden
More by Esko Kokkonen
https://orcid.org/0000-0002-3674-7486
Joachim Schnadt
Joachim Schnadt
MAX IV Laboratory, Lund University, Box 118, 221 00 Lund, Sweden
Division of Synchrotron Radiation Research, Department of Physics, Lund University, Box 118, 221 00 Lund, Sweden
NanoLund, Lund University, Box 118, 221 00 Lund, Sweden
More by Joachim Schnadt
https://orcid.org/0000-0001-9375-831X
Henrik Pedersen*
Henrik Pedersen
Department of Physics, Chemistry and Biology, Linköping University, 581 83 Linköping, Sweden
*[email protected]
More by Henrik Pedersen
https://orcid.org/0000-0002-7171-5383

Open PDF Supporting Information (1)

Chemistry of Materials

Cite this: Chem. Mater. 2026, 38, 4, 1902–1914

Click to copy citationCitation copied!

https://doi.org/10.1021/acs.chemmater.5c02974

Published February 11, 2026

CC-BY 4.0 .

Abstract

Click to copy section linkSection link copied!

Studies of the surface chemistry of the first few cycles of atomic layer deposition (ALD) using in situ and time-resolved operando techniques are attractive for realizing, understanding, and obtaining true mechanistic information during the deposition. However, the latter techniques are yet to be applied to ALD of metal nitrides. Here, we present a surface-chemistry investigation through a time-resolved ambient pressure X-ray photoelectron spectroscopy (APXPS) study of the initial growth of titanium nitride (TiN). The Ti 2p, O 1s, N 1s, C 1s, and Si 2p core-level spectra recorded at different stages during the deposition show that chemisorption occurs immediately on the silicon dioxide surface due to the interaction of tetrakis(dimethylamido)titanium(IV) (TDMAT) with the surface. A delay in nucleation on the TDMAT-terminated surface was observed during the NH₃ pulse. The intensity of the Ti 2p and N 1s core levels began to increase after four ALD cycles, showing that the surface was coated with Ti and N atoms and no Si signals were observed with time. The results show that ligand exchange reactions take place before transamination reactions. This was verified using the periodic changes in the intensity and peak positions of the above-mentioned spectra and complemented by residual gas analysis using mass spectrometry. These results can provide insights into the ALD surface growth of not only TiN but also other metal nitrides.

This publication is licensed under

CC-BY 4.0 .

License Summary*
You are free to share(copy and redistribute) this article in any medium or format and to adapt(remix, transform, and build upon) the material for any purpose, even commercially within the parameters below:
- Creative Commons (CC): This is a Creative Commons license.
- Attribution (BY): Credit must be given to the creator.
View full license
*Disclaimer
This summary highlights only some of the key features and terms of the actual license. It is not a license and has no legal value. Carefully review the actual license before using these materials.
License Summary*
You are free to share(copy and redistribute) this article in any medium or format and to adapt(remix, transform, and build upon) the material for any purpose, even commercially within the parameters below:
- Creative Commons (CC): This is a Creative Commons license.
- Attribution (BY): Credit must be given to the creator.
View full license
*Disclaimer
This summary highlights only some of the key features and terms of the actual license. It is not a license and has no legal value. Carefully review the actual license before using these materials.

Subjects

1. Introduction

Click to copy section linkSection link copied!

Atomic layer deposition (ALD) is a thin-film synthesis technique defined by a series of sequential, self-terminating surface reactions involving a precursor and a reactive gas. (1) Under optimal conditions, these reactions reach saturation, thereby providing numerous benefits for the film quality, including excellent conformality, repeatability, uniformity over large areas, and precise and straightforward film-thickness control. (2) ALD is suitable for depositing a range of materials, including metals, metal oxides, and metal nitrides.

Although there have been many studies of ALD process developments, the mechanistic details of the interaction, reactivity, nucleation, and growth chemistry are still not well understood in most cases, particularly in the initial stages. Understanding the early interaction behavior of specific precursors is not only crucial for ALD process optimization purposes (since these mechanisms will govern the growth of the material) (3) but also because nucleation impacts the entirety of the growth process, hence significantly affecting the material’s properties and its functionality. (4)

Many ALD processes typically initiate with a nucleation phase, which is characterized by the formation and growth of islands. (5) After a varying number of cycles, influenced by the chemistry of the precursor and substrate interface, these islands merge to form a continuous film. However, the initial stages, or first few ALD cycles, are challenging to characterize using conventional techniques due to the complexity of the nucleation process, which becomes significantly easier to analyze once the steady-state growth regime is established. Performing in situ and time-resolved or operando measurements during deposition is the only way to gain accurate mechanistic information. In the context of ALD, the term in situ generally denotes experiments in which film growth is monitored intermittently between cycles, typically under vacuum and within the same reactor, thus preventing exposure of the sample to air. By contrast, we use the term operando to describe time-resolved characterization performed concurrently with film growth under realistic or near-realistic pressure conditions, thereby distinguishing it from in situ approaches that do not provide temporal resolution. (6) For decades, in situ measurements (7) have been performed primarily using mass spectrometry, infrared spectroscopy, quartz crystal microbalance measurements, optical emission spectrometry, spectroscopic ellipsometry, and ultrahigh vacuum (UHV) XPS. Operando experiments, e.g., operando ambient pressure X-ray photoelectron spectroscopy (APXPS), provide dynamic insights into chemical reactions during film growth under realistic temperature and pressure regimes similar to those in a reactor. Operando APXPS, which has gained much attention for time-resolved measurements in recent years, is conducted concurrently with the dosing of the precursor, i.e., monitoring the chemical environment of the substrate and film surface while pulsing the ALD precursors. (8−10) As opposed to the more common in situ XPS experiments that are performed after ALD half-cycles and at times under nonrealistic conditions (e.g., high vacuum), operando APXPS closely mimics or replicates actual processing environments, such as atmospheric or near-pressurized conditions. (11)

Titanium nitride (TiN) is one of the more widely studied ALD systems due to its desirable properties for numerous applications in the protective hard coatings industry and in semiconductor device manufacturing. Applications of TiN films include aluminum diffusion barriers, seed layers for copper plating, and gate electrodes in metal-oxide-semiconductor (MOS) devices. (12−14) In addition to these uses, TiN is widely employed as a diffusion barrier for catalytic metals in the growth of carbon nanotubes and the deposition of self-organized metallic particles. (15−18) TiN films are also well-known for their appealing golden hue, making them suitable for decorative purposes. (19,20) These applications make use of TiN properties such as the high melting point (∼3000 °C) and hardness (28 GPa at 25 °C) in combination with high thermal and electrical conductivity (23 W/mK and 135 μΩ/cm respectively). (21,22)

So far, operando APXPS surface chemistry studies of initial ALD stages have been limited to metals, e.g., Pt (10) and oxides e.g., HfO₂ (6,9,23,24) and TiO₂. (8) No APXPS investigations on nitrides have been reported yet. In contrast, using other techniques, several studies on the ALD of nitrides such as TiN have previously been published. (25−29) Here we present, for the first time, a surface-chemistry investigation through a comprehensive time-resolved APXPS study of the initial stages of TiN ALD, during an ongoing thermal ALD process using tetrakis(dimethylamido)titanium(IV) (Ti(NMe₂)₄, TDMAT) and ammonia (NH₃) on a natively oxidized Si surface. The Si 2p, C 1s, O 1s, N 1s, and Ti 2p core-level spectra recorded at different stages of deposition (before, during, and after) and the observed periodic changes of the above-mentioned spectra intensity and peak positions help us understand that during the TiN ALD surface reactions, TDMAT readily chemisorbs through a ligand exchange mechanism with surface hydroxyls (||−OH) and a possible insertion reaction, while NH₃ takes time to initiate the transamination reaction. The Ti 2p and N 1s spectra exhibit clear signatures of successful nitridation, evidenced by the emergence of Ti–O–N and Ti–N bonding, which become most pronounced after at least four ALD cycles. These findings provide a pathway to understand the surface reactions happening during metal nitride deposition by ALD.

2. Methods

Click to copy section linkSection link copied!

Employing time-resolved APXPS for surface and gas phase analysis, in conjunction with mass spectrometry as demonstrated in this study, offers an excellent approach for identifying reaction intermediates or metastable surface species that are challenging to detect using standard XPS techniques. Ultimately, we showcase the capability to monitor dynamic alterations in surface chemistry associated with nitride ALD, which could be highly beneficial for development and control in various applications.

2.1. APXPS

A specialized ALD reaction cell developed for the SPECIES beamline at the MAX IV synchrotron in Lund, Sweden was used for the experiments. (30,31) The ALD reaction cell is contained within a UHV chamber and can be filled to a pressure of up to 20 mbar while still maintaining high vacuum conditions in the outer chamber and allowing simultaneous XPS measurements. Specific details regarding the ALD setup can be found in the comprehensive description by Kokkonen et al., (32) while an overall description of the SPECIES beamline and the endstation is provided in earlier publications. (30,33) The APXPS measurements were conducted using either the snapshot or swept mode of the electron energy analyzer. In the snapshot mode, electron spectra with a limited energy range – defined by the pass energy of the analyzer – are acquired with high time resolution. The benefit of time resolution comes at a cost in that the varying efficiency across the detector is not averaged out and that, therefore, the spectrum is affected by incorrect relative intensities at different energies. In the swept mode a variation in efficiency is averaged out since each kinetic energy is measured in each channel of the detector. This renders the relative intensities accurate, but spectrum acquisition is relatively slow. During the half-cycles, the O 1s, Ti 2p, N 1s, C 1s, and Si 2p core-level spectra were measured in snapshot mode using a photon energy of 680 eV. The swept spectra were measured at different photon energies with each resulting in approximately the same electron kinetic energies, allowing us to probe each core level with the same probing depth. The overall spectral resolution, given by

\sqrt{{({Δ E}_{A})}^{2} + {({Δ E}_{B L})}^{2}}

(where ΔE_A represents the analyzer resolution and ΔE_BL is the beamline-dependent photon energy resolution), was approximately 250 and 350 meV for swept-mode and snapshot-mode measurements, respectively. To minimize the occurrence of X-ray induced effects in the spectra, the sample was continuously moved by automatically scanning it to new positions for each XPS measurement. This movement resulted in slight variations in the overall signal intensity due to minor drifts of the sample in and out of the optimal focus position of the electron energy analyzer.

2.2. Film Deposition

Crystalline Si(100) wafers, covered with a native oxide layer, served as substrates for the ALD process. Before being introduced into the APXPS system, the substrates underwent cleaning in an ultrasonic bath using deionized water, ethanol, and acetone. Subsequently, the sample was transferred into the UHV chamber of the AXPS system and into the ALD cell. A TDMAT container (acquired from Sigma-Aldrich) was attached to the gas system of the setup and heated to about 70 °C. The process temperature of the sample was set to around 250 °C, as monitored by a thermocouple attached to the sample holder close to the sample. A total pressure of approximately 0.8 mbar (being the sum of either the vapor pressure of the TDMAT precursor or its coreactant NH₃ and the Ar carrier gas) was maintained in the ALD cell during deposition. For both half and full ALD cycles, 5 × 5 s pulses of TDMAT and 5 × 50 ms NH₃ with 30 and 5 s purge times, respectively, were used. Purge times were made long enough to ensure adequate separation between the two precursor pulses and allow enough time to obtain adequate XPS signal statistics.

2.3. Data Analysis

The binding energy scale in all instances and in the first spectrum of the time-resolved series was calibrated using the Si 2p_3/2 peak of bulk silicon, which is found at 99.3 eV, (34) aligning well with values reported in the literature. (35−37) The TDMAT signal was designated as the starting point of a cycle, for the back-to-back cycles. Intensity calibration of the time-resolved spectra was performed by dividing the swept spectrum by the corresponding snapshot spectrum to obtain channel-dependent calibration factors. All 200 data points in each snapshot scan were multiplied with the corresponding factor. Linear or polynomial backgrounds were removed from all spectra. For peak position evolution, a Voigt function was fitted to the region around the local maximum, and the resulting peak centers were plotted as a function of time. All data were acquired using SpecsLab Prodigy 4. The CasaXPS software was used to fit the swept XPS data with Gaussian–Lorentzian lineshapes and linear backgrounds. The fit parameters can be found in Tables S1–S4 in the Supporting Information. Origin 2019 was used for refined plotting.

2.4. Residual Gas Analysis

To support the APXPS data regarding the reactions occurring during TiN ALD, we used residual gas analysis (RGA) with a time-of-flight mass spectrometer (ToF-MS). The ToF-MS was located on the first differentially pumped section of the electron analyzer; thus, we assume that the ToF-MS data is rather sensitive to the gaseous products released from the sample during the half-cycle reactions. However, determining the exact contribution of observed data from the sample surface versus the chamber walls remains unknown.

3. Results

Click to copy section linkSection link copied!

First ALD Half-Cycle: TDMAT

Figure 1 shows the time-resolved O 1s, Ti 2p, N 1s, C 1s, and Si 2p ambient pressure X-ray photoelectron (APXP) spectra measured on the Si substrate surface in the first half-cycle, i.e., before, during, and after exposure to TDMAT at 250 °C. The dashed horizontal lines indicate the starting time of the Ar carrier gas flow followed by the 5 × 5 s TDMAT pulses.

Figure 1. Time-resolved a) O 1s, b) Ti 2p, c) N 1s, d) C 1s, and e) Si 2p APXP spectra measured during the TDMAT half-cycle at 250 °C while f) shows the peak position evolution of the main peak regions in C 1s and Ti 2p plots as a function of time during the TDMAT pulse. The spectra were measured using a photon energy of 680 eV. The color scale shows how the intensity of the indicated core levels changes with time. For ease of visibility, the Ti 2p, N 1s, and C 1s intensities were multiplied by factors, as indicated, relative to the Si 2p intensity.

The O 1s and Si 2p spectra of the initial substrate surface indicate that the SiO₂ surface is possibly hydroxylated, (36,38) while the intensities decrease when Ar carrier gas starts to flow and further decreases during the TDMAT pulses. Contrary to common assumptions, SiO₂ surfaces are rarely fully hydroxylated, and the true extent of hydroxylation remains difficult to quantify with XPS. While defects readily undergo hydroxylation, the inherent resistance of silica to full hydroxylation (40,41) challenges the conventional view of a uniformly hydroxylated surface. High O 1s and Si 2p intensities alone are insufficient to infer hydroxyl coverage, as oxide and hydroxide contributions are difficult to disentangle spectroscopically. (40) Careful comparison to reference studies such as Miyaji et al., (42) which differentiates oxide and hydroxyl peaks, and Namiki et al., (39) which positions the O 1s oxide peak relative to Si 2p, provides a framework for a more rigorous assessment of surface hydroxylation in initial ALD cycles.

The apparent shift of the entire O 1s spectrum to lower binding energy after the TDMAT pulses is due to a new peak that is in agreement with the formation of titanium oxide. (43,44) As expected, no signal is seen in the Ti 2p spectrum of the initial surface. It appears gradually during the 5 × 5 s TDMAT pulses before it increases after the pulsing is completed. A clear correlation is observed between the Ti 2p signal and the N 1s and C 1s signals, accompanied by a 0.1 eV shift in the Si 2p peak. As no spectral calibration was applied beyond the one based on the Si 2p position in the first spectrum of the time-resolved measurement (cf. Methods), this shift is attributed to band bending effects rather than to calibration artifacts. Low N 1s and C 1s intensities are shown to appear on the initial surface as adsorbed species, which reduce in intensity when Ar carrier gas flows. Increased intensities are seen with a C 1s displacement toward higher binding energy by approximately 1.3 eV during the TDMAT pulses. These signals decrease again when the first half-cycle is completed. An interesting point is that the reaction is not immediate; instead a clear delay in Ti incorporation is observed. This is evidenced by the change in Ti 2p signal intensity between the period during the TDMAT pulses and the period following the TDMAT pulses. The initial N 1s binding energy (∼399 eV) during TDMAT pulses agrees with that of the amide ligand. (45) The increase in the observed N 1s peak (∼399 eV) (46) and C 1s peak (∼286 eV) (47) intensities during the pulses indicates the adsorption of surface complex species from the methylamido precursor. (48) The Ti 2p peak looks different (during and after TDMAT pulses) which could be a sign of different oxidation states that coalesce into the titanium oxide-like features creating an apparent increase of intensity. More likely, the signal is characteristic of the intact surface-adsorbed precursor prior to ligand removal. It might also be due to the TDMAT gas phase signal. Afterward, the decrease of these two peak intensities seems to be correlated with the increase of the Ti 2p peak intensity (∼459 eV) (49) after the TDMAT pulses are completed. A plausible explanation for this is the removal of amido ligands (which contain both N and C) during purging, leaving behind Ti bonded to the initial substrate surface oxide species. (50) In other words, the increase in Ti 2p is due to the removal of the DMA^– ligands, and so the titanium signal becomes less attenuated.

Second ALD Half-Cycle: NH₃

Figure 2 displays the time-resolved O 1s, Ti 2p, N 1s, C 1s, and Si 2p APXPS signal intensities measured during the second half-cycle of ALD of TiN, i.e., the NH₃ pulsing. The horizontal lines indicate the starting times for two NH₃ pulse trains. The first pulse train consisted of one set of 5 × 50 ms NH₃ pulses. The second pulse train comprised 10 sets of 5 × 50 ms NH₃ pulses.

Figure 2. Time-resolved a) O 1s, b) Ti 2p, c) N 1s, d) C 1s, and e) Si 2p APXPS spectra measured during the NH₃ half-cycle at 250 °C while f) shows the center of gravity plot as a function of time during the first and second NH₃ pulse trains to visualize the dynamic changes. The spectra were measured using a photon energy of 680 eV. The color scale shows how the intensity of the indicated core levels changes with time. For ease of visibility, the Ti 2p, N 1s, and C 1s intensities were multiplied by factors, as indicated, relative to the Si 2p intensity.

The evolution of the spectral signals can be followed the same way as in the first half-cycle, both in terms of the intensity and binding energy. The intensities do not show any apparent trends from the beginning to the end of the NH₃ half-cycle pulses. From Figure 2, it is clear that prior to the Ar carrier gas and the two NH₃ pulses, the surface had titanium adsorbed from the TDMAT pulse in the first half-cycle as shown by the Ti 2p intensity map. While changes are observed in the C 1s region, the O 1s signal remains largely unchanged. The variation in C 1s is therefore more plausibly attributed to the accumulation of unreacted (“free”) ligands from the gas phase on the surface. In addition, the carrier gas was turned off between the two half-cycles shown in Figures 1 and 2, which may also influence the observed signals. The C 1s peak position appears to be constant before and after the NH₃ exposure, shown by the stability of the C 1s center of gravity (Figure 2f), which accounts for the absence of a measurable decrease or increase during the NH₃ pulses. To resolve this more clearly, intensity evolution extracted at defined time points from the image plots would allow a more direct comparison of the temporal evolution indicating that no ligand removal is evident in the second half-cycle through NH₃-assisted ligand exchange surface reactions. This is shown in Figure 3.

Figure 3. a) N 1s and b) C 1s intensity evolutions extracted at defined time points from the image plots in Figure 2c) and d), respectively, allowing a more direct comparison of the temporal evolution indicating that no ligand removal is evident in the second half-cycle through NH₃-assisted ligand exchange surface reactions.

Interestingly, the failure to remove precursor ligands in the second half-cycle deviates from observations in our other SiO₂ experiments (even though for oxides), suggesting that variations in the initial surface state (e.g., differences in surface hydroxyl density and defect concentration) may have altered the reaction. (9) Such differences could reflect modified ligand desorption kinetics or alternative reaction pathways, potentially influencing the nucleation behavior and early growth mode of the TiN film. It is worthwhile noting that carbon-containing species are detected at the onset of the second half-cycle, despite their low intensity at the end of the first half-cycle. The observed binding energy is too low to correspond to nitrogen-bonded amido ligands, suggesting the presence of aliphatic carbon likely originating from residual chamber gases. No nitrogen is detected in the snapshot spectra, which rules out an assignment to methyl–methylenimine or other N-containing species. (6,51) The appearance of such adventitious carbon between half-cycles may influence the initial surface chemistry by transiently passivating reactive sites, and this possibility will be further examined in the context of the swept spectra. The Ti 2p signal is strong from the beginning, after the first half-cycle (TDMAT exposure), consistent with the presence of Ti on the surface. The relatively constant binding energy and intensity suggest Ti 2p (∼459 eV) (49,52) remains in a stable Ti–O environment and is not significantly altered during NH₃ exposure. N 1s shows a noisy background signal at lower binding energy regions indicating that there is no direct evidence of nitrogen incorporation occurring, i.e., NH₃ may not strongly chemisorb or decompose on the surface in just one-half-cycle.

An important consideration is the time interval between ALD half-cycles. In our experiments, the waiting time was 41 min between the initial TDMAT half-cycle and the subsequent NH₃ half-cycle and 44 min between completion of the NH₃ half-cycle and the initiation of additional ALD cycles. Longer delays between half-cycles increase the likelihood of impurity incorporation, whereas shorter intervals reduce this risk.

Three Additional ALD Cycles: 3 × (TDMAT + NH₃)

The time-resolved APXPS data recorded during three subsequent ALD cycles at 250 °C are displayed in Figure 4, illustrating the evolution of the O 1s, Ti 2p, N 1s, C 1s ,and Si 2p APXP spectra as the deposition progresses. The Ar carrier gas flow was kept open after the second half-cycle, and we continued to initiate three additional full ALD cycles, meaning that we studied four full ALD cycles in total in this investigation.

Figure 4. Time-resolved a) O 1s, b) Ti 2p, c) N 1s, d) C 1s, and e) Si 2p APXP spectra measured during three additional cycles at 250 °C, while f) and g) show the peak position evolution of the main peak regions in Ti 2p and C 1s plots as a function of time during the ALD cycles. The color scale shows how the intensity of the indicated core levels changes over time. The spectra were measured using a photon energy of 680 eV. The time at which each ALD half-cycle starts is marked by horizontal dashed lines and denoted TDMAT or NH₃ to symbolize when each corresponding half-cycle starts and ends. Note that this is a continuation of Figures 1 and 2, hence precursor pulsing starts at TDMAT (2). We can clearly see the five short pulses of TDMAT in each of the TDMAT pulse trains as drops in Ti 2p intensity (this is superimposed on the raster-induced intensity changes). The dotted red line on the Ti 2p map shows the shift toward lower binding energies during the three ALD cycles with time, indicating a shift from oxide toward nitride character in the films. The oscillating behavior shown on the maps has nothing to do with the ALD process itself but emanates from the continuous movement of the sample during analysis as mentioned in the Methods section. For ease of visibility, the O 1s intensity was multiplied by a factor of 2 relative to the Si 2p intensity.

Most notably, the Ti 2p spectra indicate approximately a 1.3 eV shift toward lower binding energy after the second TDMAT pulse compared to after the first TDMAT pulse. Here we need to be aware that the deposited TDMAT (see Figure 1 and Figure 5b) has a similar Ti 2p binding energy as TiN, from the adsorbed Ti–N(CH₃)₂ species. (53) The Ti 2p peak center of gravity is stable after the second TDMAT pulse, with negligible shift in the peak position after the third cycle, suggesting a new chemical state of Ti at this stage of the deposition, i.e., the Ti–N increases while the Ti–O decreases.

Figure 5. APXPS core level scans of the a) O 1s, b) Ti 2p, c) N 1s, and d) C 1s lines at 250 °C from an initial substrate surface until after the three additional ALD cycles. The spectra were measured using photon energies of 680 eV for the O 1s and Ti 2p lines, while 550 and 410 eV were used in the measurement of the N 1s and C 1s spectra, respectively. To make incorporation of N and Ti more visible and easier to follow, the corresponding survey spectrum for each of the four conditions is available in the Supporting Information. For ease of identification of minor components, the relevant spectra were multiplied by corresponding factors as shown.

The N 1s and the C 1s both show spectra with increased intensities during the TDMAT pulse showing that both N and C emanate from the precursor ligands. Following TDMAT exposure, distinct spectral signatures corresponding to adsorbed amido ligands are evident. Subsequent pulsing of NH₃ results in the systematic disappearance of these signals, consistent with the reactive removal of the amido species - likely via transamination and hydrogenation pathways. However, experimental artifacts, most notably the intensity fluctuations due to sample rastering, complicate the precise quantification of these transformations. A major component which could be attributed to carbon-containing groups (ligands, -NMe₂) is observed during a TDMAT pulse, while in the N 1s signal the lower binding energy at ∼397 eV (54) associated with Ti–N was observed as more TDMAT and NH₃ pulses were made. This suggests that the NH₃ reacts with TDMAT to form TiN with the ligand removed intact. Notably, there is also a 0.3 eV shift toward lower binding energy for O 1s when more cycles are executed, indicating a transition from silicon oxide to titanium oxide and finally to an oxynitride, i.e., that the process is incorporating N. This can be followed more clearly in Figure 5 on the fitted high-resolution core level spectra collected after each of the depositions shown in Figures 1–4.

Combining Figures 1–4 with Figure 5, from TDMAT pulse 2 to NH₃ pulse 4, the time-resolved APXPS data shows clear signatures of the ALD growth mechanism for TiN. During each TDMAT pulse, there is a noticeable increase in the Ti 2p and C 1s signals, indicating adsorption of TDMAT along with its organic ligands. The Ti 2p peak appears shifted from 459 eV to a lower binding energy of 458.5 eV, consistent with a reduced Ti environment. Upon introduction of NH₃, the N 1s signal increases, providing direct evidence of nitrogen incorporation. Notably, the N 1s peak not only increases in intensity but also stabilizes in position near 396.7 eV, (54) which is characteristic of metal-nitride bonding, confirming the formation of Ti–N bonds rather than weakly bound or physisorbed nitrogen species. During the subsequent NH₃ half-cycle, the C 1s signal decreases, reflecting the removal of ligands, while the Ti 2p peak shifts slightly to lower binding energy. This cycle-dependent evolution is consistent with progressive ligand elimination and reduction of the Ti species, ultimately leading to TiN formation. Within the ALD cycle, TDMAT exposure introduces Ti–N(CH₃)₂ surface species, whereas the subsequent NH₃ half-cycle promotes ligand removal, evidenced by a decrease in the C 1s signal. Concurrently, the Ti 2p peak shifts to lower binding energy, indicating progressive reduction of the Ti center. This cyclic sequence of ligand adsorption and removal is consistent with the stepwise evolution toward TiN formation. The O 1s intensity tends to decrease during NH₃ exposure, suggesting the elimination of oxygen contamination on the surface. Throughout these cycles, the gradual attenuation of the Si 2p signal confirms the progressive buildup of the TiN film on the Si substrate.

Figure 5 shows the deconvoluted O 1s, Ti 2p, N 1s, and C 1s core-level spectra, illustrating how the chemical environment changes from the initial surface before pulsing any precursors, to the half-cycles of TDMAT and NH₃, before three full additional ALD cycles were initiated. The peak shifts, positions, and intensities speak to the transition toward TiN formation. All measurements were taken with substrate at 250 °C.

O 1s

Fitted peaks in Figure 5a confirm the presence of a native silicon oxide layer on the initial substrate surface, with a peak located at 532.3 eV, (55,56) which disappears after four full ALD cycles and subsequently the appearance of the oxynitride component. It is also important to mention that the peak at approximately 532.0 eV can also be assigned to surface hydroxyl (Si–OH) (49,57−59) groups; as discussed previously, the degree of hydroxylation cannot be determined in an easy and straightforward manner since it depends on the exact state of the surface. After the first TDMAT pulse, two environments are observed: the higher binding energy component for Si–O as already mentioned and a new lower-energy component peak appearing at ∼530.6 eV (49,60) that is attributed to lattice oxygen coordinated to a metal in a manner similar to that found in TiO₂. (58,59,61) After the TDMAT and NH₃ pulses on the third ALD cycle, the higher-energy component of TiO₂ is still visible; however a new higher binding energy feature located at 531.1 eV emerges and corresponds to Ti–O–N oxynitride type of bonding from nitrogen incorporation into the films. (62) This peak assignment is based on the electronegativity differences among O (3.4), N (3.0), and Ti (1.5). However, other studies on the O 1s XPS features attributed to oxide versus oxynitride components in TiN films exhibit substantial inconsistency. For instance, one investigation attributes features at binding energies of 530.4 ± 0.2 eV and 531.5 ± 0.2 eV to Ti–N–O and Ti–O species, respectively, (62) while Cherono et al. assigned the oxide (O–Ti) peak at ∼529.97 eV, the oxynitride (O–Ti–N) feature at ∼531.20 eV, and adsorbed oxygen species such as hydroxyls at ∼533.65 eV, highlighting how peak positions shift depending on film composition and processing conditions. (64) These discrepancies underscore the lack of consensus and the sensitivity of peak assignments to film stoichiometry and analytical approach. (65)

Ti 2p

In the Ti 2p region (Figure 5b), a clear stepwise chemical evolution is observed across the initial ALD cycles. During the first and second half-cycles, the Ti 2p peak is centered at ∼459.0 eV, characteristic of Ti–O bonding environments typical of oxidized species, and by the third ALD cycle, this feature shifts toward lower binding energies, with distinct contributions at approximately 458.3 eV (Ti–O–N) and 456.5 eV (Ti–N). (66) This progression indicates a gradual transformation of the interfacial chemistry from oxygen-rich, oxidized titanium species toward a more nitrogen-rich TiN-like environment as the film nucleates and grows. Such a stepwise evolution suggests that the initial cycles involve ligand exchange reactions with residual surface oxygen/hydroxyl species (67) (which are expected to persist even under high-vacuum conditions due to the ubiquitous presence of trace water and its strong tendency to adsorb on surfaces), while subsequent cycles increasingly favor the formation of stoichiometric Ti–N bonding environments. The binding energy of titanium during the first half-cycle in adsorbed TDMAT (in which Ti is still bonded to amido ligands) has been reported and can be assigned at around 457 eV. (53,68) The Ti 2p spectral deconvolution after four full ALD cycles reveals additional features. A secondary peak at approximately 456.5 eV, attributed to TiN bonding, is labeled Ti–N. (69,70) The appearance of the Ti 2p peak associated with TiN at such lower binding energy signifies the presence of nitrogen in the bonding environment, suggesting a Ti–N interaction. Meanwhile, the peak near 458.3 eV is associated with titanium oxynitride (TiO_xN_y) and is designated as Ti–O–N. (70−72) This additional intermediate peak indicates a mixed bonding scenario where both nitrogen and oxygen are present around titanium atoms. This component emerges when oxygen is incorporated during the film growth, leading to a substitution of nitrogen by oxygen. (52) Even after four ALD cycles, a minor Ti component may remain bonded to residual amido species (e.g., Ti–DMA or Ti–MMI), as evidenced by distinct features in the N 1s spectrum indicating the presence of such nitrogen-containing ligands.

N 1s

Peak fittings for the N part are shown in Figure 5c. The initial surface exhibits two peaks, one at ∼401 eV and another one at ∼399 eV. The small peak at 401.3 eV is possibly residual dimethylamine (45) in the chamber from prior experiments done with TDMAT, while the peak at 398.5 eV can be assigned to chemisorbed N surface species designated as Si–O–N. (73) Upon pulsing TDMAT on the first half-cycle, amine, imine, and adsorbed TDMAT species features at 400.4 eV, 397.5, and 396.7 eV, respectively, are observed. When NH₃ is dosed, the N 1s binding energy with three contributions is observed at ∼401 eV, 398, and 397 eV. Of these binding energies, 401.4 eV can be attributed to hydrogen bonded/protonated amines. (74,75) The other peak at 399 eV is from NH_x termination, (76) and lastly, 397.5 eV is assigned to an imine. (45) As the film grows, features of Ti–N and Ti–O–N at 396.7 eV (77) and 398.4 eV, (63) respectively, become apparent. After four ALD cycles, deconvolution of the N 1s region reveals four distinct components within the binding energy range of approximately 396–401 eV. Consistently, the final spectra acquired in snapshot mode display an almost similar set of features. This agreement supports their assignment, as measurements performed in swept mode could be affected by adventitious adsorption of residual TDMAT-related species during the temporal delay preceding spectral acquisition. The highest binding energy feature at 400.4 eV is designated as the amine species. (45,75) This peak is associated with the presence of amine precursor ligands as nitrogen-containing contaminant surface species. (78) The remaining three peaks are linked to Ti–O–N, imine, and Ti–N bonding. The peaks at 398.9 and 397.2 eV are attributed to Ti–O–N (79) and imine respectively, while the lower binding energy peak near 396.7 eV corresponds to Ti–N. (52,63,80) However, the exact positions of these peaks can vary depending on the chemical environment and the stoichiometry of the oxynitride. (65) The peak assignments in the Ti 2p, N 1s, and O 1s regions are consistent and align well: indicating the presence of amounts of Ti–O–N, a significant concentration of Ti–N bonding, and suppressed amounts of Ti–O after four ALD cycles.

C 1s

With reference to a similar ligand system study using tetrakis(dimethylamino)hafnium(IV) (TDMAHf), (6) the carbon configuration observed during the dosing of TDMAT possibly corresponds to two organic ligand components: methyl methylenimine (MMI, N(CH₃)(CH₂)) and dimethylamine (DMA, HN(CH₃)₂). MMI features carbon atoms in two environments: CH₃ and CH₂ (typically either a three-membered ring or between adjacent surface complexes). (45) In contrast, both carbon atoms in DMA are present only as CH₃ groups. C 1s signal starts by revealing two components, with the higher binding energy peak position assigned to DMA remaining constant over time; possibly a result of both preceding experiments in the same experimental setup and ligand exchange or transamination reactions. The C peak assigned to C contamination disappears during the TDMAT pulse and reappears during the NH₃ pulse, while the C peak assigned to DMA decreases during the NH₃ pulse. Notably NH₃ then seems to ‘‘clean’’ the reaction surface as well as removing ligands from the TDMAT. We can attribute the lower binding energy peak (285.3 eV) in Figure 5d, during the TDMAT pulse, to the presence of MMI from an insertion reaction (81) in which a β-hydrogen from one dimethylamido ligand on TDMAT transfers to the titanium center and then inserts into another dimethylamido ligand’s N–C bond, releasing dimethylamine as a byproduct. (82) This process necessitates two different carbon species and, consequently, two peaks at varying binding energies that should change over time. Therefore, we assign the higher binding energy peak (286.4 eV) component to DMA, indicating the presence of either the intact TDMAT molecule, a ligand reaction, and insertion reaction or a transamination product on the surface.

Mass Spectrometry

We conducted time-of-flight mass-spectral analysis of residual gases during the pulsing of precursors into the APXPS chamber, focusing on the evolution of specific masses over time to emphasize the significance of the different chemical reactions to provide excellent complementary information to the time-resolved XPS data, shedding light on the gaseous byproducts during each ALD cycle. Figure 6 displays specific mass trends which are used to illustrate changes in reaction byproducts during TiN deposition using TDMAT and NH₃. Alternating green and purple shaded regions denote the TDMAT and NH₃ pulse windows, respectively. The intensity traces of key gas-phase species – including DMA, MMI, NH₃, and minor byproducts such as CH₄ and N₂ are shown as a function of time. Clear periodic peaks of DMA and MMI (which can be an ionized version of the protonated ligand) coincide with each TDMAT pulse, consistent with ligand desorption and precursor decomposition. In contrast, sharp NH₃ spikes and transient increases in CH₄ and N₂ follow NH₃ pulses, indicating nitrogen delivery and ligand cleanup. This figure complements the APXPS data by capturing the volatile chemical dynamics of the ALD process. The introduction of NH₃ results in a clear increase in signals at m/z 17 (NH₃), 16 (CH₄), and 28 (N₂), along with very minor contributions from CH₃ (partly from CH₄) at m/z 15 and O₂ at m/z 32.

Figure 6. Time-of-flight mass spectrometric behavior of detected species during TiN ALD from TDMAT and NH₃.

It is, however, important to note that the mass resolution is generally moderate, resulting in spectral crosstalk, with overlapping signals that complicate accurate quantification of individual masses in the trend plots.

4. Discussion

Click to copy section linkSection link copied!

Neither the Ti 2p nor N 1s spectra show any Ti–N bonding peaks during the first and second half-cycles. However, TiN is observed after four full ALD cycles where the N 1s spectrum indicates nitrogen bound to titanium at 396.6 eV and the Ti 2p spectrum showing titanium to nitrogen bonding at 456.6 eV.

Nitrides from various other X[N(CH₃)₂)]_n references, where X represents a metal and n the oxidation number of the metal, found in the NIST database (83) have been shown to have nitrogen peaks between 398 and 401 eV. The N 1s peak at 400.4 eV during the TDMAT half-cycle can be assigned to HN(CH₃)₂ species. (84) While DMA species would not be expected to persist at elevated temperatures ─ consistent with our previous observations showing no DMA-related signals at 280 °C (6) ─ literature reports indicate that such species can remain stable even up to approximately 250 °C under certain conditions. (68) When combined with Fourier transform infrared spectroscopy (FTIR), evidence of incorporated imine, N(CH₃–CH₂) in TiN deposited in another study (85) of the TDMAT/NH₃ process was found, where the second N 1s peak at 397.5 eV corresponds to the imine from an insertion reaction involving two amide ligands. (45) Additionally, the intensity of the nitrogen peak associated with incorporated protonated ligands (HN(CH₃)₂) gets lower during the NH₃ pulse, suggesting that this half-cycle is effective in removing precursor ligands from the surface. However, during the first NH₃ half-cycle, there is no evidence of either a ligand exchange or transamination reaction toward nitridation because the titanium spectrum still shows bonding to lattice oxygen. It is important to note, though, that the bonding of titanium to lattice oxygen (TiO₂) at 458.9 eV (86,87) during the first half-cycle is possibly a result of ligand exchange between the substrate surface hydroxyl (−OH) groups when exposed to TDMAT. Clearly, there is also the insertion reaction toward MMI (see C 1s spectrum), which also allows for Ti–O bonds to be formed. Thereafter, transamination of *TiN(CH₃)₂ surface species occurs when exposed to NH₃, releasing protonated ligands as dimethyl amine shown at 400.4 eV (45,74) This is still not enough to cause Ti–N bond formation at this point. However, after four ALD cycles, the presence of a N 1s peak at 396.7 eV (84) confirms nitrogen bound to titanium.

Reaction Mechanisms

From our results above, we formulate a suggested surface chemical mechanism for the ALD process of TiN from TDMAT and NH₃. Reactions occur immediately on silicon native oxide due to the ready interaction of TDMAT with the surface hydroxyl (−OH) groups, which means that the initial TDMAT ligand exchange reactivity is governed by the available surface −OH groups. These hydroxyl groups are replaced by dimethylamino ligands, releasing dimethylamine as a byproduct.

‐ x {OH}^{*} + Ti {({NMe}_{2})}_{4} \to ‐ O_{x} ‐ Ti ‐ {({NMe}_{2})}_{4 ‐ x}^{*} + x {HNMe}_{2} (g)

(1)

However, the detection of MMI during the first half-cycle provides strong evidence that a parallel reaction pathway is active, proceeding independently of surface hydroxyl groups. This observation implies that the density of surface hydroxyls is insufficient to fully react with all adsorbed TDMAT species. Instead, a fraction of TDMAT appears to undergo insertion or decomposition reactions (illustrated later in reactions 5 and 6) directly on nonhydroxylated surface sites, resulting in MMI formation, likely through a bimolecular reaction pathway. (6) This challenges the often-assumed hydroxyl-saturation model for initial ALD nucleation and highlights the need to consider alternative surface reaction pathways that become accessible when hydroxyl coverage is limited.

The kinetics of the reaction is lower during the NH₃ pulse. The reaction between TDMAT and NH₃ is known to be ‘rapid even at room temperature’; (88) however, these rapid reactions were not observed in the early ALD stages studied in this work. There is a delay in nucleation or bonding on the TDMAT-terminated surface, after which the growth rate or the Ti–N bonding character is expected to increase as the surface becomes coated with both Ti and N atoms. Nucleation delay is commonly attributed to factors such as the density of reactive surface sites, exchange reactions, and the presence of persistent ligands. (89) These effects are expected to diminish with increasing ALD cycles, leading to a gradual increase in the growth per cycle (GPC) until a steady state is reached. (5) In the second half-cycle, more dimethylamine is released upon reaction with NH₃ ligands, leaving behind an -NH₂-terminated ‘oxynitride’ surface.

‐ O_{x} ‐ Ti ‐ {({NMe}_{2})}_{4 ‐ x}^{*} + (4 ‐ x) {NH}_{3} \to ‐ O_{x} ‐ Ti ‐ {({NH}_{2})}_{4 ‐ x} + (4 ‐ x) {HNMe}_{2} (g)

(2)

This can be supported by the N 1s peak at ∼400.4 eV, shown in Figure 5c, which is consistent with amine species. (74,75) Release of amine species happens in both the first and second half-cycles and is observed in the nitrogen spectra throughout the cycles. A simplified illustration of this mechanism is shown in Figure 7.

Figure 7. A simplified illustration of the early stages of TiN ALD showing TDMAT reacting with an OH-terminated surface, emitting the protonated ligand, dimethylamine, leaving the surface terminated in titanium dimethylamide, completing the first half of the reaction. In the second half, the introduced ammonia removes the surface bound dimethylamide as dimethylamine, resulting in an NH₂-terminated surface.

In our previous study, (90) we have shown that dimethylamido metal precursors such as TDMAT follow more complex reaction pathways other than the common and expected ligand exchange reactions including ligand decomposition, disproportionation, and hydrogenation. Other byproducts from a ‘partial’ ligand exchange combined with protonation of the methyl part of the ligand, as confirmed by mass spectrometry shown in Figure 6, include CH₄ (methane) upon interaction with NH₃. The result of this reaction leaves behind an amino group bonded to the Ti and possibly an unreacted methyl reaction site.

‐ O_{x} ‐ Ti ‐ {({NMe}_{2})}_{4 ‐ x}^{*} + x {NH}_{3} \to ‐ O_{x} ‐ Ti ‐ ({NMe}_{x}) {({NH}_{2})}_{4 ‐ 2 x} + x {CH}_{4} (g)

(3)

As more precursor pulses are initiated, the amino-terminated N part may act as an additional reaction site, which would release more CH₄ with more NH₃ exposure.

Referring to Figure 4, the C 1s signal is markedly more intense during the first half-cycle than during the second half-cycle, suggesting a higher surface coverage of carbon-containing species during the initial precursor exposure compared to the subsequent coreactant step. A plausible explanation for this is the possible partial decomposition of the precursor, at temperatures higher than 200 °C (28,91,92) as well as 80–85% dissociation of the adsorbed TDMAT, releasing different fragments, as verified by previous XPS studies. (68)

Ti {[N {(Me)}_{2}]}_{4} \to ‐ {NMe}_{2} + {CH}_{4} + {({Me}_{2} N)}_{2} Ti = NMe

(4)

Another possible source of carbon is MeN=CH₂ (MMI) in the films through a β-hydride elimination process or an insertion reaction which leads to a three-membered ring or dimer. (81,93)

Ti {[N {(Me)}_{2}]}_{4} \to H ‐ Ti {[N {(Me)}_{2}]}_{3} + MeN = {CH}_{2}

(5)

Ti {[N {(Me)}_{2}]}_{4} \to Ti ({NMeCH}_{2}) {({NMe}_{2})}_{2} + {HNMe}_{2} \to HTi ({NMeCH}_{2}) ({NMe}_{2}) + MeN = {CH}_{2}

(6)

Spectroscopically, distinguishing between the source of MMI as a β-hydride elimination or an insertion reaction pathway is likely challenging. A more detailed consideration of the possible reaction products is therefore warranted to enable reliable interpretation of the observed signals.

The decrease in the C 1s signal after the pulse of NH₃, which alters the chemistry involved, is seen to eliminate carbon contamination from the resulting TiN thin film, through formation of HNMe₂ from transamination and amine elimination reactions. (94)

3 Ti {({NMe}_{2})}_{4} + 4 {NH}_{3} \to 3 TiN + 12 {HNMe}_{2} + \frac{1}{2} N_{2}

(7)

Mass spectrometry results (Figure 6) indicate that when NH₃ is pulsed there is a noticeable increase in DMA^– and DMA signals, along with a significant rise in the m/z 43 (MMI) signal, as confirmed by DFT that insertion reactions are viable involving amido complexes via the β-hydride insertion pathway. (6) During the NH₃ pulse, β-hydride transfer from one dimethylamido ligand on TDMAT to the titanium center can be followed by hydride insertion into the N–C bond of another dimethylamido ligand, leading to the release of dimethylamine (DMA); NH₃ facilitates this insertion-driven decomposition by protonating the departing amido fragments, thereby accelerating ligand elimination as amines. This observation aligns well with the APXPS results (Figure 5c and 5d), which reveal their adsorption onto the sample surface and possible presence of these species in the gas phase.

The increase in CH₄ at m/z 16, during the NH₃ pulse, suggests another reactive pathway for methane removal from the surface, reaction 4. However, it is important to note that, in processes that use NH₃ as a coreactant, m/z 16 can either be CH₄, NH₂, or a combination of both. (95) Distinguishing between these two species can be challenging. Although we could only detect volatile species using residual gas analysis, there is clear evidence of release of different species that corroborate the interactions and reactions stimulated by this TiN ALD process on a silicon surface. It is important to consider the pumping efficiency and sticking probability of each gas, as NH₃ typically takes a long time to evacuate since it adheres more readily to the walls. Thus, we may be overestimating the concentration of heavier or less polar organics (carbonaceous species from the precursor) in the analysis relative to the amount of NH₃ released, since it adheres more readily to the walls when the pressure equilibrium shifts. As a result, relatively less of NH₃ is measured in the gas phase, even though it might be present in larger quantities. On the other hand, the carbonaceous species may remain ‘artificially’ in the gas phase, skewing measurements.

ToF-MS results seem to support the APXPS results quite well. The mass spectrometry data provides clear evidence of surface reactions through the detection of volatile byproducts. However, it is noteworthy to take extra caution with interpretation of these results. For example, m/z 16, 17, and 18 probably all contain each other’s masses. So, when we talk about an increase of CH₄ (16) during NH₃ (17) pulses, that could suggest different reaction pathways than the ones already mentioned. We do not really know how much of the m/z 16 signal actually contains CH₄. All this points to the difficulty in distinguishing between different species, especially those with closely linked mass-to-charge ratios. Each TDMAT pulse is marked by prominent signals from DMA, its deprotonated form (DMA^–), and (MMI), indicating ligand desorption and possible precursor fragmentation. These species appear consistently across the TDMAT pulses, confirming the delivery of TDMAT and associated organics to the surface. In contrast, during the NH₃ pulses, the signals for DMA and MMI drop significantly, while NH₃ peaks rise sharply, indicating successful introduction of the nitrogen source. A moderate rise in N₂ and CH₄ during this step suggests additional gas-phase reactions, possibly from the breakdown of residual ligands. This pattern strongly supports and aligns well with APXPS observations of ligand removal and nitrogen incorporation.

5. Conclusions

Click to copy section linkSection link copied!

TiN deposition by ALD on silicon with a native oxide layer was investigated during the initial cycles by APXPS. The reactivity on the silicon oxide surface is higher during the first half-cycle (TDMAT), likely due to the presence of hydroxyl groups on the surface which serve as reactive sites for TiN nucleation, forming a layer of Si–O–Ti bonding at the SiO₂/TiN interface. Furthermore, the observed MMI during TDMAT pulses indicated the possibility of an insertion reaction. In contrast, during the second half-cycle (NH₃), the presence of NH_x species is inferred from the XPS results, confirming that an NH_x termination occurs during this stage of the ALD process. After four ALD cycles, the TiN bond formation becomes evident. The first visible incorporation of the nitride character in the form of TiN/TiON bonds was found after the fourth ALD cycle. Signals of carbonaceous species DMA, MMI, and CH₄ among other reaction products were observed from both APXS and mass spectrometry. These results have shown that there are other significant reaction mechanisms and pathways that take place during the formation of nitrides from alkylamido precursors other than the more generalized and expected ligand exchange reactions. We find these results to be a useful indicator of how time-resolved APXPS is a remarkable tool to fundamentally understand how reactions occur during TiN ALD, in real time and without exposure to external environments. On top of providing important mechanistic insights, the use of time-resolved APXPS during ALD from dimethylamido precursors may provide a simple method to control their reaction with NH₃ to improve the properties of TiN and related nitride materials.

Supporting Information

Click to copy section linkSection link copied!

The Supporting Information is available free of charge at https://pubs.acs.org/doi/10.1021/acs.chemmater.5c02974.

Additional details from the APXPS measurements (PDF)

cm5c02974_si_001.pdf (738.39 kb)

Terms & Conditions

Most electronic Supporting Information files are available without a subscription to ACS Web Editions. Such files may be downloaded by article for research use (if there is a public use license linked to the relevant article, that license may permit other uses). Permission may be obtained from ACS for other uses through requests via the RightsLink permission system: http://pubs.acs.org/page/copyright/permissions.html.

Author Information

Click to copy section linkSection link copied!

Corresponding Authors
- Pamburayi Mpofu - Department of Physics, Chemistry and Biology, Linköping University, 581 83 Linköping, Sweden; https://orcid.org/0000-0003-0878-9248; Email: [email protected]
- Henrik Pedersen - Department of Physics, Chemistry and Biology, Linköping University, 581 83 Linköping, Sweden; https://orcid.org/0000-0002-7171-5383; Email: [email protected]
Authors
- Peggy Bagherzadeh Tabrizi - Department of Physics, Chemistry and Biology, Linköping University, 581 83 Linköping, Sweden
- Houyem Hafdi - Department of Physics, Chemistry and Biology, Linköping University, 581 83 Linköping, Sweden
- Premrudee Promdet - Department of Physics, Chemistry and Biology, Linköping University, 581 83 Linköping, Sweden
- Jonas Lauridsen - Seco Tools AB, 737 82 Fagersta, Sweden
- Oscar Alm - Seco Tools AB, 737 82 Fagersta, Sweden
- Tommy Larsson - Seco Tools AB, 737 82 Fagersta, Sweden
- Rosemary Jones - MAX IV Laboratory, Lund University, Box 118, 221 00 Lund, Sweden; Division of Synchrotron Radiation Research, Department of Physics, Lund University, Box 118, 221 00 Lund, Sweden; https://orcid.org/0000-0001-6273-4243
- Esko Kokkonen - MAX IV Laboratory, Lund University, Box 118, 221 00 Lund, Sweden; https://orcid.org/0000-0002-3674-7486
- Joachim Schnadt - MAX IV Laboratory, Lund University, Box 118, 221 00 Lund, Sweden; Division of Synchrotron Radiation Research, Department of Physics, Lund University, Box 118, 221 00 Lund, Sweden; NanoLund, Lund University, Box 118, 221 00 Lund, Sweden; https://orcid.org/0000-0001-9375-831X
Notes
The authors declare no competing financial interest.

Acknowledgments

Click to copy section linkSection link copied!

We gratefully acknowledge financial support by Seco Tools, by Vinnova, through the project “Surface chemical mechanisms during atomic layer deposition of hard nitrides” (2023-02815) and by the Stiftelsen för Strategisk Forskning (Swedish foundation for Strategic Research, SSF) through the project ‘‘Time-resolved low temperature CVD for III-nitrides’’ (SSF-RMA 15-0018). H.P. acknowledge financial support from the Swedish Government Strategic Research Area in Materials Science on Advanced Functional Materials at Linköping University (Faculty Grant SFO-Mat-LiU No. 2009-00971). P.M. is grateful to Marcus Lorentzon for supplying the MIST code. J.S. acknowledges support by Vetenskapsrådet (Swedish Research Council, VR) under project grant no. 2023-03492. We acknowledge the MAX IV Laboratory for beamtime on the SPECIES beamline under proposal 20231261. Research conducted at MAX IV, a Swedish national user facility, is supported by VR under contract 2018-07152, Vinnova (Swedish Governmental Agency for Innovation Systems) under contract 2018-04969 and Formas under contract 2019-02496.

References

Click to copy section linkSection link copied!

This article references 95 other publications.

1
Puurunen, R. L. Surface Chemistry of Atomic Layer Deposition: A Case Study for the Trimethylaluminum/Water Process. J. Appl. Phys. 2005, 97, 121301 DOI: 10.1063/1.1940727
Google Scholar
There is no corresponding record for this reference.
2
Ritala, M.; Leskelä, M. Atomic Layer Deposition. In Handbook of Thin Films Materials: Deposition and Processing of Thin Films, Nalwa, H. S., Ed.; Academic Press: United Kingdom, 2002; Vol. 1, pp 103– 159.
Google Scholar
There is no corresponding record for this reference.
3
Richey, N. E.; De Paula, C.; Bent, S. F. Understanding Chemical and Physical Mechanisms in Atomic Layer Deposition. J. Chem. Phys. 2020, 152, 040902 DOI: 10.1063/1.5133390
Google Scholar
There is no corresponding record for this reference.
4
Langereis, E.; Heil, S. B. S.; Van De Sanden, M. C. M.; Kessels, W. M. M. Initial Growth and Properties of Atomic Layer Deposited TiN Films Studied by in Situ Spectroscopic Ellipsometry. Phys. Status Solidi C Conf. 2005, 2, 3958– 3962, DOI: 10.1002/pssc.200562218
Google Scholar
There is no corresponding record for this reference.
5
Puurunen, R. L.; Vandervorst, W. Island Growth as a Growth Mode in Atomic Layer Deposition: A Phenomenological Model. J. Appl. Phys. 2004, 96, 7686– 7695, DOI: 10.1063/1.1810193
Google Scholar
There is no corresponding record for this reference.
6
D’Acunto, G.; Tsyshevsky, R.; Shayesteh, P.; Gallet, J. J.; Bournel, F.; Rochet, F.; Pinsard, I.; Timm, R.; Head, A. R.; Kuklja, M.; Schnadt, J. Bimolecular Reaction Mechanism in the Amido Complex-Based Atomic Layer Deposition of HfO2. Chem. Mater. 2023, 35, 529– 538, DOI: 10.1021/acs.chemmater.2c02947
Google Scholar
There is no corresponding record for this reference.
7
Knapas, K.; Ritala, M. In Situ Studies on Reaction Mechanisms in Atomic Layer Deposition. Crit. Rev. Solid State Mater. Sci. 2013, 38, 167– 202, DOI: 10.1080/10408436.2012.693460
Google Scholar
There is no corresponding record for this reference.
8
Jones, R.; Kokkonen, E.; Eads, C.; Küst, U. K.; Prumbs, J.; Knudsen, J.; Schnadt, J. Time-Resolved Ambient Pressure x-Ray Photoelectron Spectroscopy: Advancing the Operando Study of ALD Chemistry. Surf. Sci. 2025, 753, 122656 DOI: 10.1016/j.susc.2024.122656
Google Scholar
There is no corresponding record for this reference.
9
Jones, R.; D’Acunto, G.; Shayesteh, P.; Pinsard, I.; Rochet, F.; Bournel, F.; Gallet, J.-J.; Head, A.; Schnadt, J. Operando Study of HfO2 Atomic Layer Deposition on Partially Hydroxylated Si(111). J. Vac. Sci. Technol. A 2024, 42, 022404 DOI: 10.1116/6.0003349
Google Scholar
There is no corresponding record for this reference.
10
Kokkonen, E.; Nieminen, H.; Rehman, F.; Miikkulainen, V.; Putkonen, M.; Ritala, M.; Huotari, S.; Schnadt, J.; Urpelainen, S. Ambient Pressure X-Ray Photoelectron Spectroscopy Study on the Initial Atomic Layer Deposition Process of Platinum. J. Vac. Sci. Technol. A 2024, 42, 062406 DOI: 10.1116/6.0003871
Google Scholar
There is no corresponding record for this reference.
11
Starr, D. E.; Liu, Z.; Hävecker, M.; Knop-Gericke, A.; Bluhm, H. Investigation of Solid/Vapor Interfaces Using Ambient Pressure X-Ray Photoelectron Spectroscopy. Chem. Soc. Rev. 2013, 42, 5833– 5857, DOI: 10.1039/c3cs60057b
Google Scholar
There is no corresponding record for this reference.
12
Kim, H. Atomic Layer Deposition of Metal and Nitride Thin Films: Current Research Efforts and Applications for Semiconductor Device Processing. J. Vac. Sci. Technol. B Microelectron. Nanom. Struct. Process. Meas. Phenom. 2003, 21, 2231– 2261, DOI: 10.1116/1.1622676
Google Scholar
There is no corresponding record for this reference.
13
Wang, C. Y.; Chou, C. Y.; Shiue, H. F.; Chen, H. Y.; Ling, C. H.; Shyue, J. J.; Chen, M. J. Atomic Layer Annealing for Modulation of the Work Function of TiN Metal Gate for N-Type MOS Devices. Appl. Surf. Sci. 2022, 585, 152748 DOI: 10.1016/j.apsusc.2022.152748
Google Scholar
There is no corresponding record for this reference.
14
Lima, L. P. B.; Dekkers, H. F. W.; Lisoni, J. G.; Diniz, J. A.; Van Elshocht, S.; De Gendt, S. Metal Gate Work Function Tuning by Al Incorporation in TiN. J. Appl. Phys. 2014, 115, 074504 DOI: 10.1063/1.4866323
Google Scholar
There is no corresponding record for this reference.
15
Chourasia, A. R.; Chopra, D. R. X-Ray Photoelectron Study of TiN/SiO2 and TiN/Si Interfaces. Thin Solid Films 1995, 266, 298– 301, DOI: 10.1016/0040-6090(95)06651-9
Google Scholar
There is no corresponding record for this reference.
16
Jouan, P.-Y.; Lemp, G.; Peignon, C. Characterisation of TiN Coatings and of the TiN/Si Interface by X-Ray Photoelectron Spectroscopy and Auger Electron Spectroscopy. Appl. Surf. Sci. 1993, 68, 595– 603, DOI: 10.1016/0169-4332(93)90241-3
Google Scholar
There is no corresponding record for this reference.
17
Morales, M.; Cucatti, S.; Acuña, J. J. S.; Zagonel, L. F.; Antonin, O.; Hugon, M. C.; Marsot, N.; Bouchet-Fabre, B.; Minea, T.; Alvarez, F. Influence of the Structure and Composition of Titanium Nitride Substrates on Carbon Nanotubes Grown by Chemical Vapour Deposition. J. Phys. D. Appl. Phys. 2013, 46, 155308 DOI: 10.1088/0022-3727/46/15/155308
Google Scholar
There is no corresponding record for this reference.
18
Morales, M.; Merlo, R. B.; Droppa, R.; Alvarez, F. Self-Organized 2D Ni Particles Deposited on Titanium Oxynitride-Coated Si Sculpted by a Low Energy Ion Beam. J. Phys. D. Appl. Phys. 2014, 47, 195303 DOI: 10.1088/0022-3727/47/19/195303
Google Scholar
There is no corresponding record for this reference.
19
López, J. M.; Gordillo-Vázquez, F. J.; Böhme, O.; Albella, J. M. Low Grain Size TiN Thin Films Obtained by Low Energy Ion Beam Assisted Deposition. Appl. Surf. Sci. 2001, 173, 290– 295, DOI: 10.1016/S0169-4332(00)00912-0
Google Scholar
There is no corresponding record for this reference.
20
Duan, G.; Zhao, G.; Wu, L.; Lin, X.; Han, G. Structure, Electrical and Optical Properties of TiN x Films by Atmospheric Pressure Chemical Vapor Deposition. Appl. Surf. Sci. 2011, 257, 2428– 2431, DOI: 10.1016/j.apsusc.2010.11.180
Google Scholar
There is no corresponding record for this reference.
21
Pierson, H. O. A Review of the Chemical Vapor Deposition (Cvd) of the Refractory Compounds Of Titanium - A Unique Family Of Coatings. Mater. Manuf. Process. 1993, 8, 519– 534, DOI: 10.1080/10426919308934855
Google Scholar
There is no corresponding record for this reference.
22
Yokota, K.; Nakamura, K.; Kasuya, T.; Tamura, S.; Sugimoto, T.; Akamatsu, K.; Nakao, K.; Miyashita, F. Relationship between Hardness and Lattice Parameter for TiN Films Deposited on SUS 304 by an IBAD Technique. Surf. Coat. Technol. 2002, 158–159, 690– 693, DOI: 10.1016/S0257-8972(02)00245-1
Google Scholar
There is no corresponding record for this reference.
23
D’Acunto, G.; Troian, A.; Kokkonen, E.; Rehman, F.; Liu, Y. P.; Yngman, S.; Yong, Z.; McKibbin, S. R.; Gallo, T.; Lind, E.; Schnadt, J.; Timm, R. Atomic Layer Deposition of Hafnium Oxide on InAs: Insight from Time-Resolved in Situ Studies. ACS Appl. Electron. Mater. 2020, 2, 3915– 3922, DOI: 10.1021/acsaelm.0c00775
Google Scholar
There is no corresponding record for this reference.
24
D’Acunto, G.; Jones, R.; Pérez Ramírez, L.; Shayesteh, P.; Kokkonen, E.; Rehman, F.; Lim, F.; Bournel, F.; Gallet, J. J.; Timm, R.; Schnadt, J. Role of Temperature, Pressure, and Surface Oxygen Migration in the Initial Atomic Layer Deposition of HfO2 on Anatase TiO2(101). J. Phys. Chem. C 2022, 126, 12210– 12221, DOI: 10.1021/acs.jpcc.2c02683
Google Scholar
There is no corresponding record for this reference.
25
Sobell, Z. C.; George, S. M. Electron-Enhanced Atomic Layer Deposition of Titanium Nitride Films Using an Ammonia Reactive Background Gas. Chem. Mater. 2022, 34, 9624– 9633, DOI: 10.1021/acs.chemmater.2c02341
Google Scholar
There is no corresponding record for this reference.
26
Musschoot, J.; Xie, Q.; Deduytsche, D.; Van den Berghe, S.; Van Meirhaeghe, R. L.; Detavernier, C. Atomic Layer Deposition of Titanium Nitride from TDMAT Precursor. Microelectron. Eng. 2009, 86, 72– 77, DOI: 10.1016/j.mee.2008.09.036
Google Scholar
There is no corresponding record for this reference.
27
Zhu, Y.; Zhou, Z.; Zhang, X.; Xu, R.; Wang, Y.; Xu, L.; Xiao, H.; Li, X.; Li, A.; Fang, G. Surface Reaction Mechanism of Atomic Layer Deposition of Titanium Nitride Using Tetrakis(Dimethylamino)Titanium and Ammonia. Surfaces and Interfaces 2023, 36, 102579 DOI: 10.1016/j.surfin.2022.102579
Google Scholar
There is no corresponding record for this reference.
28
Cho, G.; Rhee, S.-W. Effect of the Amido Ti Precursors on the Atomic Layer Deposition of TiN with NH3. J. Vac. Sci. Technol. A Vacuum, Surfaces, Film. 2013, 31, 01A117 DOI: 10.1116/1.4764898
Google Scholar
There is no corresponding record for this reference.
29
Park, K.; Mun, G.; Cho, J.; Lee, S.; Min, G.; Hong, S. Properties of TiN Thin Films Deposited by ALD Using TDMAT Precursor in Low-Temperature Processes. J. Semicond. Dispersion Technol. 2024, 23, 14– 20
Google Scholar
There is no corresponding record for this reference.
30
Schnadt, J.; Knudsen, J.; Andersen, J. N.; Siegbahn, H.; Pietzsch, A.; Hennies, F.; Johansson, N.; Mårtensson, N.; Öhrwall, G.; Bahr, S.; Mähl, S.; Schaff, O. The New Ambient-Pressure X-Ray Photoelectron Spectroscopy Instrument at MAX-Lab. J. Synchrotron Radiat. 2012, 19, 701– 704, DOI: 10.1107/S0909049512032700
Google Scholar
There is no corresponding record for this reference.
31
Knudsen, J.; Andersen, J. N.; Schnadt, J. A Versatile Instrument for Ambient Pressure X-Ray Photoelectron Spectroscopy: The Lund Cell Approach. Surf. Sci. 2016, 646, 160– 169, DOI: 10.1016/j.susc.2015.10.038
Google Scholar
There is no corresponding record for this reference.
32
Kokkonen, E.; Kaipio, M.; Nieminen, H. E.; Rehman, F.; Miikkulainen, V.; Putkonen, M.; Ritala, M.; Huotari, S.; Schnadt, J.; Urpelainen, S. Ambient Pressure X-Ray Photoelectron Spectroscopy Setup for Synchrotron-Based in Situ and Operando Atomic Layer Deposition Research. Rev. Sci. Instrum. 2022, 93, 013905 DOI: 10.1063/5.0076993
Google Scholar
There is no corresponding record for this reference.
33
Kokkonen, E.; Da Silva, F. L.; Mikkela, M. H.; Johansson, N.; Huang, S. W.; Lee, J. M.; Andersson, M.; Bartalesi, A.; N. Reinecke, B.; Handrup, K.; Tarawneh, H.; Sankari, R.; Knudsen, J.; Schnadt, J.; Sathe, C.; Urpelainen, S. Upgrade of the SPECIES Beamline at the MAX IV Laboratory. J. Synchrotron Radiat. 2021, 28, 588– 601, DOI: 10.1107/S1600577521000564
Google Scholar
There is no corresponding record for this reference.
34
Tissot, H.; Gallet, J. J.; Bournel, F.; Naitabdi, A.; Pierucci, D.; Bondino, F.; Magnano, E.; Rochet, F.; Finocchi, F. Silicon Monomer Formation and Surface Patterning of Si(001)-2 × 1 Following Tetraethoxysilane Dissociative Adsorption at Room Temperature. J. Phys. Chem. C 2014, 118, 1887– 1893, DOI: 10.1021/jp407411k
Google Scholar
There is no corresponding record for this reference.
35
Kim, J. W.; Yeom, H. W.; Chung, Y. D.; Jeong, K.; Whang, C. N.; Lee, M. K.; Shin, H. J. Chemical Configuration of Nitrogen in Ultrathin Si Oxynitride on Si(100). Phys. Rev. B - Condens. Matter Mater. Phys. 2002, 66, 035312, DOI: 10.1103/PhysRevB.66.035312
Google Scholar
There is no corresponding record for this reference.
36
Verdaguer, A.; Weis, C.; Oncins, G.; Ketteler, G.; Bluhm, H.; Salmero, M. Growth and Structure of Water on SiO2 Films on Si Investigated by Kelvin Probe Microscopy and in Situ X-Ray Spectroscopies. Langmuir 2007, 23, 9699– 9703, DOI: 10.1021/la700893w
Google Scholar
There is no corresponding record for this reference.
37
Kim, Y. K.; Hyun, S. L.; Yeom, H. W.; Ryoo, D. Y.; Huh, S. B.; Lee, J. G. Nitrogen Bonding Structure in Ultrathin Silicon Oxynitride Films on Si(100) Prepared by Plasma Nitridation. Phys. Rev. B - Condens. Matter Mater. Phys. 2004, 70, 165320 DOI: 10.1103/PhysRevB.70.165320
Google Scholar
There is no corresponding record for this reference.
38
Simonsen, M. E.; Sønderby, C.; Li, Z.; Søgaard, E. G. XPS and FT-IR Investigation of Silicate Polymers. J. Mater. Sci. 2009, 44, 2079– 2088, DOI: 10.1007/s10853-009-3270-9
Google Scholar
There is no corresponding record for this reference.
39
Namiki, A.; Tanimoto, K.; Nakamura, T.; Ohtake, N.; Suzaki, T. XPS Study on the Early Stages of Oxidation of Si(100) by Atomic Oxygen. Surf. Sci. 1989, 222, 530– 554, DOI: 10.1016/0039-6028(89)90377-4
Google Scholar
There is no corresponding record for this reference.
40
Yang, J.; Wang, E. G. Reaction of Water on Silica Surfaces. Curr. Opin. Solid State Mater. Sci. 2006, 10, 33– 39, DOI: 10.1016/j.cossms.2006.02.001
Google Scholar
There is no corresponding record for this reference.
41
Rignanese, G. M.; Charlier, J. C.; Gonze, X. First-Principles Molecular-Dynamics Investigation of the Hydration Mechanisms of the (0001) α-Quartz Surface. Phys. Chem. Chem. Phys. 2004, 6, 1920– 1925, DOI: 10.1039/B311842H
Google Scholar
There is no corresponding record for this reference.
42
Miyaji, F.; Iwai, M.; Kokubo, T.; Nakamura, T. Chemical Surface Treatment of Silicone for Inducing Its Bioactivity. J. Mater. Sci. Mater. Med. 1998, 9, 61– 65, DOI: 10.1023/A:1008886729050
Google Scholar
There is no corresponding record for this reference.
43
Göpel, W.; Anderson, J. A.; Frankel, D.; Jaehnig, M.; Phillips, K.; Schäfer, J. A.; Rocker, G. Surface Defects of TiO2(110): A Combined XPS, XAES AND ELS Study. Surf. Sci. 1984, 139, 333– 346, DOI: 10.1016/0039-6028(84)90054-2
Google Scholar
There is no corresponding record for this reference.
44
Saha, N. C.; Tompkins, H. G. Titanium Nitride Oxidation Chemistry: An x-Ray Photoelectron Spectroscopy Study. J. Appl. Phys. 1992, 72, 3072– 3079, DOI: 10.1063/1.351465
Google Scholar
There is no corresponding record for this reference.
45
Head, A. R.; Chaudhary, S.; Olivieri, G.; Bournel, F.; Andersen, J. N.; Rochet, F.; Gallet, J. J.; Schnadt, J. Near Ambient Pressure X-Ray Photoelectron Spectroscopy Study of the Atomic Layer Deposition of TiO2 on RuO2(110). J. Phys. Chem. C 2016, 120, 243– 251, DOI: 10.1021/acs.jpcc.5b08699
Google Scholar
There is no corresponding record for this reference.
46
Jansen, R. J. J.; van Bekkum, H. XPS of Nitrogen-Containing Functional Groups on Activated Carbon. Carbon N. Y. 1995, 33, 1021– 1027, DOI: 10.1016/0008-6223(95)00030-H
Google Scholar
There is no corresponding record for this reference.
47
Bruggeman, M.; Zelzer, M.; Dong, H.; Stamboulis, A. Processing and Interpretation of Core-Electron XPS Spectra of Complex Plasma-Treated Polyethylene-Based Surfaces Using a Theoretical Peak Model. Surf. Interface Anal. 2022, 54, 986– 1007, DOI: 10.1002/sia.7125
Google Scholar
There is no corresponding record for this reference.
48
Cao, X.; Hamers, R. J. Silicon Surfaces as Electron Acceptors: Dative Bonding of Amines with Si(001) and Si(111) Surfaces. J. Am. Chem. Soc. 2001, 123, 10988– 10996, DOI: 10.1021/ja0100322
Google Scholar
There is no corresponding record for this reference.
49
Peña-Juárez, M. G.; Robles-Martínez, M.; Méndez-Rodríguez, K. B.; López-Esparza, R.; Pérez, E.; Gonzalez-Calderon, J. A. Role of the Chemical Modification of Titanium Dioxide Surface on the Interaction with Silver Nanoparticles and the Capability to Enhance Antimicrobial Properties of Poly(Lactic Acid) Composites. Polym. Bull. 2021, 78, 2765– 2790, DOI: 10.1007/s00289-020-03235-y
Google Scholar
There is no corresponding record for this reference.
50
Ngoc Van, T. T.; Jang, D.; Jung, E.; Noh, H.; Moon, J.; Kil, D. S.; Chung, S. W.; Shong, B. Role of Cyclopentadienyl Ligands of Group 4 Precursors toward High-Temperature Atomic Layer Deposition. J. Phys. Chem. C 2022, 126, 18090– 18099, DOI: 10.1021/acs.jpcc.2c04425
Google Scholar
There is no corresponding record for this reference.
51
Li, K.; Li, S.; Li, N.; Klein, T. M.; Dixon, D. A. Tetrakis(Ethylmethylamido) Hafnium Adsorption and Reaction on Hydrogen-Terminated Si(100) Surfaces. J. Phys. Chem. C 2011, 115, 18560– 18571, DOI: 10.1021/jp111600v
Google Scholar
There is no corresponding record for this reference.
52
Trenczek-Zajac, A.; Radecka, M.; Zakrzewska, K.; Brudnik, A.; Kusior, E.; Bourgeois, S.; de Lucas, M. C. M.; Imhoff, L. Structural and Electrical Properties of Magnetron Sputtered Ti(ON) Thin Films: The Case of TiN Doped in Situ with Oxygen. J. Power Sources 2009, 194, 93– 103, DOI: 10.1016/j.jpowsour.2008.12.112
Google Scholar
There is no corresponding record for this reference.
53
Killampalli, A. S.; Ma, P. F.; Engstrom, J. R. The Reaction of Tetrakis (Dimethylamido) Titanium with Self-Assembled Alkyltrichlorosilane Monolayers Possessing. J. Am. Chem. Soc. 2005, 127, 6300– 6310, DOI: 10.1021/ja047922c
Google Scholar
There is no corresponding record for this reference.
54
Peng, Z.; Chen, G.; Zhao, Y.-P.; Zhang, X.; Song, Y.-T.; Shirkov, G.; Karamysheva, G.; Karamyshev, O.; Calabretta, L.; Caruso, A. Investigation of TiN Film on an RF Ceramic Window by Atomic Layer Deposition. J. Vac. Sci. Technol. A Vacuum, Surfaces, Film. 2020, 38, 052401 DOI: 10.1116/6.0000159
Google Scholar
There is no corresponding record for this reference.
55
Nguyen, T. P.; Lefrant, S. XPS Study of SiO Thin Films and SiO-Metal Interfaces. J. Phys.: Condens. Matter 1989, 1, 5197– 5204, DOI: 10.1088/0953-8984/1/31/019
Google Scholar
There is no corresponding record for this reference.
56
Desbiens, E.; Dolbec, R.; El Khakani, M. A. Reactive Pulsed Laser Deposition of High- k Silicon Dioxide and Silicon Oxynitride Thin Films for Gate-Dielectric Applications. J. Vac. Sci. Technol. A Vacuum, Surfaces, Film. 2002, 20, 1157– 1161, DOI: 10.1116/1.1467357
Google Scholar
There is no corresponding record for this reference.
57
Ketteler, G.; Yamamoto, S.; Bluhm, H.; Andersson, K.; Starr, D. E.; Ogletree, D. F.; Ogasawara, H.; Nilsson, A.; Salmeron, M. The Nature of Water Nucleation Sites on TiO2(110) Surfaces Revealed by Ambient Pressure X-Ray Photoelectron Spectroscopy. J. Phys. Chem. C 2007, 111, 8278– 8282, DOI: 10.1021/jp068606i
Google Scholar
There is no corresponding record for this reference.
58
Walle, L. E.; Borg, A.; Johansson, E. M. J.; Plogmaker, S.; Rensmo, H.; Uvdal, P.; Sandell, A. Mixed Dissociative and Molecular Water Adsorption on Anatase TiO 2(101). J. Phys. Chem. C 2011, 115, 9545– 9550, DOI: 10.1021/jp111335w
Google Scholar
There is no corresponding record for this reference.
59
Walle, L. E.; Borg, A.; Uvdal, P.; Sandell, A. Experimental Evidence for Mixed Dissociative and Molecular Adsorption of Water on a Rutile TiO2 (110) Surface without Oxygen Vacancies. Phys. Rev. B - Condens. Matter Mater. Phys. 2009, 80, 235436 DOI: 10.1103/PhysRevB.80.235436
Google Scholar
There is no corresponding record for this reference.
60
Esaka, F.; Furuya, K.; Shimada, H.; Imamura, M.; Matsubayashi, N.; Sato, H.; Nishijima, A.; Kawana, A.; Ichimura, H.; Kikuchi, T. Comparison of Surface Oxidation of Titanium Nitride and Chromium Nitride Films Studied by X-Ray Absorption and Photoelectron Spectroscopy. J. Vac. Sci. Technol. A Vacuum, Surfaces, Film. 1997, 15, 2521– 2528, DOI: 10.1116/1.580764
Google Scholar
There is no corresponding record for this reference.
61
Jaeger, D.; Patscheider, J. Single Crystalline Oxygen-Free Titanium Nitride by XPS. Surf. Sci. Spectra 2013, 20, 1, DOI: 10.1116/11.20121107
Google Scholar
There is no corresponding record for this reference.
62
Chan, M. H.; Lu, F. H. X-Ray Photoelectron Spectroscopy Analyses of Titanium Oxynitride Films Prepared by Magnetron Sputtering Using Air/Ar Mixtures. Thin Solid Films 2009, 517, 5006– 5009, DOI: 10.1016/j.tsf.2009.03.100
Google Scholar
There is no corresponding record for this reference.
63
Robinson, K. S.; Sherwood, P. M. A. X-Ray Photoelectron Spectroscopic Studies of the Surface of Sputter Ion Plated Films. Surf. Interface Anal. 1984, 6, 261– 266, DOI: 10.1002/sia.740060603
Google Scholar
There is no corresponding record for this reference.
64
Cherono, S.; Chris-Okoro, I.; Liu, M.; Kim, R. S.; Nalawade, S.; Akande, W.; Maria-Diana, M.; Mahl, J.; Hale, C.; Yano, J.; Aravamudhan, S.; Crumlin, E.; Craciun, V.; Kumar, D. Transformation of TiN to TiNO Films via In-Situ Temperature-Dependent Oxygen Diffusion Process and Their Electrochemical Behavior. Metals (Basel). 2025, 15, 497, DOI: 10.3390/met15050497
Google Scholar
There is no corresponding record for this reference.
65
Kuznetsov, M. V.; Zhuravlev, J. F.; Zhilyaev, V. A.; Gubanov, V. A. XPS Study of the Nitrides, Oxides and Oxynitrides of Titanium. J. Electron Spectrosc. Relat. Phenom. 1992, 58, 1, DOI: 10.1016/0368-2048(92)80001-O
Google Scholar
There is no corresponding record for this reference.
66
Kabachkov, E.; Kurkin, E.; Vershinin, N.; Balikhin, I.; Berestenko, V.; Michtchenko, A.; Shulga, Y. Synthesis and Properties of Pt/TiN Catalyst for Low-Temperature Air Purification from Carbon Monoxide. J. Adv. Mater. Technol. 2021, 6, 131– 143, DOI: 10.17277/jamt.2021.02.pp.131-143
Google Scholar
There is no corresponding record for this reference.
67
George, S. M. Atomic Layer Deposition: An Overview. Chem. Rev. 2010, 110, 111– 131, DOI: 10.1021/cr900056b
Google Scholar
There is no corresponding record for this reference.
68
Corneille, J. S.; Chen, P. J.; Truong, C. M.; Oh, W. S.; Goodman, D. W. Surface Spectroscopic Studies of the Deposition of TiN Thin Films from Tetrakis-(Dimethylamido)-Titanium and Ammonia. J. Vac. Sci. Technol. A Vacuum, Surfaces, Film. 1995, 13, 1116– 1120, DOI: 10.1116/1.579596
Google Scholar
There is no corresponding record for this reference.
69
Xiong, H.; Wu, L.; Liu, Y.; Gao, T.; Li, K.; Long, Y.; Zhang, R.; Zhang, L.; Qiao, Z. A.; Huo, Q.; Ge, X.; Song, S.; Zhang, H. Controllable Synthesis of Mesoporous TiO2 Polymorphs with Tunable Crystal Structure for Enhanced Photocatalytic H2 Production. Adv. Energy Mater. 2019, 9, 1901634 DOI: 10.1002/aenm.201901634
Google Scholar
There is no corresponding record for this reference.
70
Peng, F.; Cai, L.; Huang, L.; Yu, H.; Wang, H. Preparation of Nitrogen-Doped Titanium Dioxide with Visible-Light Photocatalytic Activity Using a Facile Hydrothermal Method. J. Phys. Chem. Solids 2008, 69, 1657– 1664, DOI: 10.1016/j.jpcs.2007.12.003
Google Scholar
There is no corresponding record for this reference.
71
Zhang, H.; Wang, B.; Brown, B. Atomic Layer Deposition of Titanium Oxide and Nitride on Vertically Aligned Carbon Nanotubes for Energy Dense 3D Microsupercapacitors. Appl. Surf. Sci. 2020, 521, 146349 DOI: 10.1016/j.apsusc.2020.146349
Google Scholar
There is no corresponding record for this reference.
72
Mpofu, P.; Niiranen, P.; Alm, O.; Lauridsen, J.; Larsson, T.; Pedersen, H. Atomic Layer Deposition of AlxTi1-XN via Co-Evaporation of Metal Precursors. J. Vac. Sci. Technol. A 2025, 43, 032405 DOI: 10.1116/6.0004420
Google Scholar
There is no corresponding record for this reference.
73
Jintsugawa, O.; Sakuraba, M.; Matsuura, T.; Murota, J. Thermal Nitridation of Ultrathin SiO2 on Si by NH3. Surf. Interface Anal. 2002, 34, 456– 459, DOI: 10.1002/sia.1337
Google Scholar
There is no corresponding record for this reference.
74
Graf, N.; Yegen, E.; Gross, T.; Lippitz, A.; Weigel, W.; Krakert, S.; Terfort, A.; Unger, W. E. S. XPS and NEXAFS Studies of Aliphatic and Aromatic Amine Species on Functionalized Surfaces. Surf. Sci. 2009, 603, 2849– 2860, DOI: 10.1016/j.susc.2009.07.029
Google Scholar
There is no corresponding record for this reference.
75
Dietrich, P. M.; Graf, N.; Gross, T.; Lippitz, A.; Krakert, S.; Schüpbach, B.; Terfort, A.; Unger, W. E. S. Amine Species on Self-Assembled Monolayers of ω-Aminothiolates on Gold as Identified by XPS and NEXAFS Spectroscopy. Surf. Interface Anal. 2010, 42, 1184– 1187, DOI: 10.1002/sia.3224
Google Scholar
There is no corresponding record for this reference.
76
Solís, R. R.; Gómez-Avilés, A.; Belver, C.; Rodriguez, J. J.; Bedia, J. Microwave-Assisted Synthesis of NH2-MIL-125(Ti) for the Solar Photocatalytic Degradation of Aqueous Emerging Pollutants in Batch and Continuous Tests. J. Environ. Chem. Eng. 2021, 9, 106230 DOI: 10.1016/j.jece.2021.106230
Google Scholar
There is no corresponding record for this reference.
77
Endle, J. P.; Sun, Y.; White, J. M.; Ekerdt, J. G. X-Ray Photoelectron Spectroscopy Study of TiN Films Produced with Tetrakis(Dimethylamido)Titanium and Selected N-Containing Precursors on SiO2. J. Vac. Sci. Technol. A 1998, 16, 1262– 1267, DOI: 10.1116/1.581271
Google Scholar
There is no corresponding record for this reference.
78
Quesada-Cabrera, R.; Sotelo-Vazquez, C.; Darr, J. A.; Parkin, I. P. Critical Influence of Surface Nitrogen Species on the Activity of N-Doped TiO2 Thin-Films during Photodegradation of Stearic Acid under UV Light Irradiation. Appl. Catal. B Environ. 2014, 160–161, 582– 588, DOI: 10.1016/j.apcatb.2014.06.010
Google Scholar
There is no corresponding record for this reference.
79
Asghar, M.; Yousaf, M.; Huwaimel, B.; Iqbal, T.; Ahmed, I.; Qureshi, M. T.; Abrar, M.; Shafiq, M.; Almohammedi, A.; Hameed, R. A.; AlElaimi, M.; Maryam, M.; Afsheen, S. Synthesis of Biocompatible Coating on Ni-Cr Alloy by Cathodic Cage Plasma Processing Technique as Anti-Pathogenic Bacteria for Medicinal Applications. Phys. Scr. 2023, 98, 055920 DOI: 10.1088/1402-4896/acc908
Google Scholar
There is no corresponding record for this reference.
80
Braic, L.; Vasilantonakis, N.; Mihai, A.; Villar Garcia, I. J.; Fearn, S.; Zou, B.; Alford, N. M. N.; Doiron, B.; Oulton, R. F.; Maier, S. A.; Zayats, A. V.; Petrov, P. K. Titanium Oxynitride Thin Films with Tunable Double Epsilon-Near-Zero Behavior for Nanophotonic Applications. ACS Appl. Mater. Interfaces 2017, 9, 29857– 29862, DOI: 10.1021/acsami.7b07660
Google Scholar
There is no corresponding record for this reference.
81
Li, K.; Li, S.; Li, N.; Dixon, D. A.; Klein, T. M. Tetrakis(Dimethylamido)Hafnium Adsorption and Reaction on Hydrogen Terminated Si(100) Surfaces. J. Phys. Chem. C 2010, 114, 14061– 14075, DOI: 10.1021/jp101363r
Google Scholar
There is no corresponding record for this reference.
82
Ruhl, G.; Rehmet, R.; Knfžvá, M.; Vepřek, S. In Situ XPS Studies of the Deposition of Thin Films from Tetrakis(Dimethylamido)Titanium Organometallic Precursor for Diffusion Barriers. MRS Online Proc. Libr. 1993, 309, 461– 466, DOI: 10.1557/PROC-309-461
Google Scholar
There is no corresponding record for this reference.
83
NIST NIST Standard Reference Database Number 20. https://dx.doi.org/10.18434/T4T88K (accessed Apr 7, 2025).
Google Scholar
There is no corresponding record for this reference.
84
Longrie, D.; Deduytsche, D.; Haemers, J.; Smet, P. F.; Driesen, K.; Detavernier, C. Thermal and Plasma-Enhanced Atomic Layer Deposition of TiN Using TDMAT and NH3 on Particles Agitated in a Rotary Reactor. ACS Appl. Mater. Interfaces 2014, 6, 7316– 7324, DOI: 10.1021/am5007222
Google Scholar
There is no corresponding record for this reference.
85
Elam, J. W.; Schuisky, M.; Ferguson, J. D.; George, S. M. Surface Chemistry and Film Growth during TiN Atomic Layer Deposition Using TDMAT and NH3. Thin Solid Films 2003, 436, 145– 156, DOI: 10.1016/S0040-6090(03)00533-9
Google Scholar
There is no corresponding record for this reference.
86
Biesinger, M. C.; Lau, L. W. M.; Gerson, A. R.; Smart, R. S. C. Resolving Surface Chemical States in XPS Analysis of First Row Transition Metals, Oxides and Hydroxides: Sc, Ti, V, Cu and Zn. Appl. Surf. Sci. 2010, 257, 887– 898, DOI: 10.1016/j.apsusc.2010.07.086
Google Scholar
There is no corresponding record for this reference.
87
Methaapanon, R.; Bent, S. F. Comparative Study of Titanium Dioxide Atomic Layer Deposition on Silicon Dioxide and Hydrogen-Terminated Silicon. J. Phys. Chem. C 2010, 114, 10498– 10504, DOI: 10.1021/jp1013303
Google Scholar
There is no corresponding record for this reference.
88
Weiller, B. H. Chemical Vapor Deposition of TiN from Tetrakis(Dimethylamido)Titanium and Ammonia: Kinetics and Mechanistic Studies of the Gas-Phase Chemistry. J. Am. Chem. Soc. 1996, 118, 4975– 4983, DOI: 10.1021/ja953468o
Google Scholar
There is no corresponding record for this reference.
89
Hughes, K. J.; Engstrom, J. R. Nucleation Delay in Atomic Layer Deposition on a Thin Organic Layer and the Role of Reaction Thermochemistry. J. Vac. Sci. Technol. A Vacuum, Surfaces, Film. 2012, 30, 01A102 DOI: 10.1116/1.3625564
Google Scholar
There is no corresponding record for this reference.
90
Mpofu, P.; Hafdi, H.; Lauridsen, J.; Alm, O.; Larsson, T.; Pedersen, H. A Mass Spectrometrical Surface Chemistry Study of Aluminum Nitride ALD from Tris-Dimethylamido Aluminum and Ammonia. Mater. Adv. 2024, 5, 9259– 9269, DOI: 10.1039/D4MA00922C
Google Scholar
There is no corresponding record for this reference.
91
Lee, W. J.; Yun, E. Y.; Lee, H. B. R.; Hong, S. W.; Kwon, S. H. Dataset for TiN Thin Films Prepared by Plasma-Enhanced Atomic Layer Deposition Using Tetrakis(Dimethylamino)Titanium (TDMAT) and Titanium Tetrachloride (TiCl4) Precursor. Data Br. 2020, 31, 105777 DOI: 10.1016/j.dib.2020.105777
Google Scholar
There is no corresponding record for this reference.
92
Yun, J.; Park, M.; Rhee, S. Comparison of Tetrakis(Dimethylamido)Titanium and Tetrakis(Diethylamido)Titanium as Precursors for Metallorganic Chemical Vapor Deposition of Titanium Nitride. J. Electrochem. Soc. 1999, 146, 1804– 1808, DOI: 10.1149/1.1391847
Google Scholar
There is no corresponding record for this reference.
93
Sen, K.; Banu, T.; Debnath, T.; Ghosh, D.; Das, A. K. Towards a Comprehensive Understanding of the Chemical Vapor Deposition of Titanium Nitride Using Ti(NMe2)4: A Density Functional Theory Approach. Dalt. Trans. 2014, 43, 8877– 8887, DOI: 10.1039/c4dt00690a
Google Scholar
There is no corresponding record for this reference.
94
Dubois, L. H.; Zegarski, B. R.; Girolami, G. S. Infrared Studies of the Surface and Gas Phase Reactions Leading to the Growth of Titanium Nitride Thin Films from Tetrakis(Dimethylamido)Titanium and Ammonia. J. Electrochem. Soc. 1992, 139, 3603– 3609, DOI: 10.1149/1.2087327
Google Scholar
There is no corresponding record for this reference.
95
Mpofu, P.; Hafdi, H.; Niiranen, P.; Lauridsen, J.; Alm, O.; Larsson, T.; Pedersen, H. Surface Chemistry in Atomic Layer Deposition of AlN Thin Films from Al(CH3)3 and NH3 Studied by Mass Spectrometry. J. Mater. Chem. C 2024, 12, 12818– 12824, DOI: 10.1039/D4TC01867B
Google Scholar
There is no corresponding record for this reference.

Cited By

Click to copy section linkSection link copied!

This article has not yet been cited by other publications.

Get e-Alerts

Chemistry of Materials

Cite this: Chem. Mater. 2026, 38, 4, 1902–1914

Click to copy citationCitation copied!

https://doi.org/10.1021/acs.chemmater.5c02974

Published February 11, 2026

CC-BY 4.0 .

Article Views

Altmetric

Citations

Learn about these metrics

Article Views are the COUNTER-compliant sum of full text article downloads since November 2008 (both PDF and HTML) across all institutions and individuals. These metrics are regularly updated to reflect usage leading up to the last few days.

Citations are the number of other articles citing this article, calculated by Crossref and updated daily. Find more information about Crossref citation counts.

The Altmetric Attention Score is a quantitative measure of the attention that a research article has received online. Clicking on the donut icon will load a page at altmetric.com with additional details about the score and the social media presence for the given article. Find more information on the Altmetric Attention Score and how the score is calculated.

Abstract
High Resolution Image
Download MS PowerPoint Slide
Figure 1
Figure 1. Time-resolved a) O 1s, b) Ti 2p, c) N 1s, d) C 1s, and e) Si 2p APXP spectra measured during the TDMAT half-cycle at 250 °C while f) shows the peak position evolution of the main peak regions in C 1s and Ti 2p plots as a function of time during the TDMAT pulse. The spectra were measured using a photon energy of 680 eV. The color scale shows how the intensity of the indicated core levels changes with time. For ease of visibility, the Ti 2p, N 1s, and C 1s intensities were multiplied by factors, as indicated, relative to the Si 2p intensity.
High Resolution Image
Download MS PowerPoint Slide
Figure 2
Figure 2. Time-resolved a) O 1s, b) Ti 2p, c) N 1s, d) C 1s, and e) Si 2p APXPS spectra measured during the NH₃ half-cycle at 250 °C while f) shows the center of gravity plot as a function of time during the first and second NH₃ pulse trains to visualize the dynamic changes. The spectra were measured using a photon energy of 680 eV. The color scale shows how the intensity of the indicated core levels changes with time. For ease of visibility, the Ti 2p, N 1s, and C 1s intensities were multiplied by factors, as indicated, relative to the Si 2p intensity.
High Resolution Image
Download MS PowerPoint Slide
Figure 3
Figure 3. a) N 1s and b) C 1s intensity evolutions extracted at defined time points from the image plots in Figure 2c) and d), respectively, allowing a more direct comparison of the temporal evolution indicating that no ligand removal is evident in the second half-cycle through NH₃-assisted ligand exchange surface reactions.
High Resolution Image
Download MS PowerPoint Slide
Figure 4
Figure 4. Time-resolved a) O 1s, b) Ti 2p, c) N 1s, d) C 1s, and e) Si 2p APXP spectra measured during three additional cycles at 250 °C, while f) and g) show the peak position evolution of the main peak regions in Ti 2p and C 1s plots as a function of time during the ALD cycles. The color scale shows how the intensity of the indicated core levels changes over time. The spectra were measured using a photon energy of 680 eV. The time at which each ALD half-cycle starts is marked by horizontal dashed lines and denoted TDMAT or NH₃ to symbolize when each corresponding half-cycle starts and ends. Note that this is a continuation of Figures 1 and 2, hence precursor pulsing starts at TDMAT (2). We can clearly see the five short pulses of TDMAT in each of the TDMAT pulse trains as drops in Ti 2p intensity (this is superimposed on the raster-induced intensity changes). The dotted red line on the Ti 2p map shows the shift toward lower binding energies during the three ALD cycles with time, indicating a shift from oxide toward nitride character in the films. The oscillating behavior shown on the maps has nothing to do with the ALD process itself but emanates from the continuous movement of the sample during analysis as mentioned in the Methods section. For ease of visibility, the O 1s intensity was multiplied by a factor of 2 relative to the Si 2p intensity.
High Resolution Image
Download MS PowerPoint Slide
Figure 5
Figure 5. APXPS core level scans of the a) O 1s, b) Ti 2p, c) N 1s, and d) C 1s lines at 250 °C from an initial substrate surface until after the three additional ALD cycles. The spectra were measured using photon energies of 680 eV for the O 1s and Ti 2p lines, while 550 and 410 eV were used in the measurement of the N 1s and C 1s spectra, respectively. To make incorporation of N and Ti more visible and easier to follow, the corresponding survey spectrum for each of the four conditions is available in the Supporting Information. For ease of identification of minor components, the relevant spectra were multiplied by corresponding factors as shown.
High Resolution Image
Download MS PowerPoint Slide
Figure 6
Figure 6. Time-of-flight mass spectrometric behavior of detected species during TiN ALD from TDMAT and NH₃.
High Resolution Image
Download MS PowerPoint Slide
Figure 7
Figure 7. A simplified illustration of the early stages of TiN ALD showing TDMAT reacting with an OH-terminated surface, emitting the protonated ligand, dimethylamine, leaving the surface terminated in titanium dimethylamide, completing the first half of the reaction. In the second half, the introduced ammonia removes the surface bound dimethylamide as dimethylamine, resulting in an NH₂-terminated surface.
High Resolution Image
Download MS PowerPoint Slide
References
This article references 95 other publications.
1. 1
  Puurunen, R. L. Surface Chemistry of Atomic Layer Deposition: A Case Study for the Trimethylaluminum/Water Process. J. Appl. Phys. 2005, 97, 121301 DOI: 10.1063/1.1940727
  There is no corresponding record for this reference.
2. 2
  Ritala, M.; Leskelä, M. Atomic Layer Deposition. In Handbook of Thin Films Materials: Deposition and Processing of Thin Films, Nalwa, H. S., Ed.; Academic Press: United Kingdom, 2002; Vol. 1, pp 103– 159.
  There is no corresponding record for this reference.
3. 3
  Richey, N. E.; De Paula, C.; Bent, S. F. Understanding Chemical and Physical Mechanisms in Atomic Layer Deposition. J. Chem. Phys. 2020, 152, 040902 DOI: 10.1063/1.5133390
  There is no corresponding record for this reference.
4. 4
  Langereis, E.; Heil, S. B. S.; Van De Sanden, M. C. M.; Kessels, W. M. M. Initial Growth and Properties of Atomic Layer Deposited TiN Films Studied by in Situ Spectroscopic Ellipsometry. Phys. Status Solidi C Conf. 2005, 2, 3958– 3962, DOI: 10.1002/pssc.200562218
  There is no corresponding record for this reference.
5. 5
  Puurunen, R. L.; Vandervorst, W. Island Growth as a Growth Mode in Atomic Layer Deposition: A Phenomenological Model. J. Appl. Phys. 2004, 96, 7686– 7695, DOI: 10.1063/1.1810193
  There is no corresponding record for this reference.
6. 6
  D’Acunto, G.; Tsyshevsky, R.; Shayesteh, P.; Gallet, J. J.; Bournel, F.; Rochet, F.; Pinsard, I.; Timm, R.; Head, A. R.; Kuklja, M.; Schnadt, J. Bimolecular Reaction Mechanism in the Amido Complex-Based Atomic Layer Deposition of HfO2. Chem. Mater. 2023, 35, 529– 538, DOI: 10.1021/acs.chemmater.2c02947
  There is no corresponding record for this reference.
7. 7
  Knapas, K.; Ritala, M. In Situ Studies on Reaction Mechanisms in Atomic Layer Deposition. Crit. Rev. Solid State Mater. Sci. 2013, 38, 167– 202, DOI: 10.1080/10408436.2012.693460
  There is no corresponding record for this reference.
8. 8
  Jones, R.; Kokkonen, E.; Eads, C.; Küst, U. K.; Prumbs, J.; Knudsen, J.; Schnadt, J. Time-Resolved Ambient Pressure x-Ray Photoelectron Spectroscopy: Advancing the Operando Study of ALD Chemistry. Surf. Sci. 2025, 753, 122656 DOI: 10.1016/j.susc.2024.122656
  There is no corresponding record for this reference.
9. 9
  Jones, R.; D’Acunto, G.; Shayesteh, P.; Pinsard, I.; Rochet, F.; Bournel, F.; Gallet, J.-J.; Head, A.; Schnadt, J. Operando Study of HfO2 Atomic Layer Deposition on Partially Hydroxylated Si(111). J. Vac. Sci. Technol. A 2024, 42, 022404 DOI: 10.1116/6.0003349
  There is no corresponding record for this reference.
10. 10
  Kokkonen, E.; Nieminen, H.; Rehman, F.; Miikkulainen, V.; Putkonen, M.; Ritala, M.; Huotari, S.; Schnadt, J.; Urpelainen, S. Ambient Pressure X-Ray Photoelectron Spectroscopy Study on the Initial Atomic Layer Deposition Process of Platinum. J. Vac. Sci. Technol. A 2024, 42, 062406 DOI: 10.1116/6.0003871
  There is no corresponding record for this reference.
11. 11
  Starr, D. E.; Liu, Z.; Hävecker, M.; Knop-Gericke, A.; Bluhm, H. Investigation of Solid/Vapor Interfaces Using Ambient Pressure X-Ray Photoelectron Spectroscopy. Chem. Soc. Rev. 2013, 42, 5833– 5857, DOI: 10.1039/c3cs60057b
  There is no corresponding record for this reference.
12. 12
  Kim, H. Atomic Layer Deposition of Metal and Nitride Thin Films: Current Research Efforts and Applications for Semiconductor Device Processing. J. Vac. Sci. Technol. B Microelectron. Nanom. Struct. Process. Meas. Phenom. 2003, 21, 2231– 2261, DOI: 10.1116/1.1622676
  There is no corresponding record for this reference.
13. 13
  Wang, C. Y.; Chou, C. Y.; Shiue, H. F.; Chen, H. Y.; Ling, C. H.; Shyue, J. J.; Chen, M. J. Atomic Layer Annealing for Modulation of the Work Function of TiN Metal Gate for N-Type MOS Devices. Appl. Surf. Sci. 2022, 585, 152748 DOI: 10.1016/j.apsusc.2022.152748
  There is no corresponding record for this reference.
14. 14
  Lima, L. P. B.; Dekkers, H. F. W.; Lisoni, J. G.; Diniz, J. A.; Van Elshocht, S.; De Gendt, S. Metal Gate Work Function Tuning by Al Incorporation in TiN. J. Appl. Phys. 2014, 115, 074504 DOI: 10.1063/1.4866323
  There is no corresponding record for this reference.
15. 15
  Chourasia, A. R.; Chopra, D. R. X-Ray Photoelectron Study of TiN/SiO2 and TiN/Si Interfaces. Thin Solid Films 1995, 266, 298– 301, DOI: 10.1016/0040-6090(95)06651-9
  There is no corresponding record for this reference.
16. 16
  Jouan, P.-Y.; Lemp, G.; Peignon, C. Characterisation of TiN Coatings and of the TiN/Si Interface by X-Ray Photoelectron Spectroscopy and Auger Electron Spectroscopy. Appl. Surf. Sci. 1993, 68, 595– 603, DOI: 10.1016/0169-4332(93)90241-3
  There is no corresponding record for this reference.
17. 17
  Morales, M.; Cucatti, S.; Acuña, J. J. S.; Zagonel, L. F.; Antonin, O.; Hugon, M. C.; Marsot, N.; Bouchet-Fabre, B.; Minea, T.; Alvarez, F. Influence of the Structure and Composition of Titanium Nitride Substrates on Carbon Nanotubes Grown by Chemical Vapour Deposition. J. Phys. D. Appl. Phys. 2013, 46, 155308 DOI: 10.1088/0022-3727/46/15/155308
  There is no corresponding record for this reference.
18. 18
  Morales, M.; Merlo, R. B.; Droppa, R.; Alvarez, F. Self-Organized 2D Ni Particles Deposited on Titanium Oxynitride-Coated Si Sculpted by a Low Energy Ion Beam. J. Phys. D. Appl. Phys. 2014, 47, 195303 DOI: 10.1088/0022-3727/47/19/195303
  There is no corresponding record for this reference.
19. 19
  López, J. M.; Gordillo-Vázquez, F. J.; Böhme, O.; Albella, J. M. Low Grain Size TiN Thin Films Obtained by Low Energy Ion Beam Assisted Deposition. Appl. Surf. Sci. 2001, 173, 290– 295, DOI: 10.1016/S0169-4332(00)00912-0
  There is no corresponding record for this reference.
20. 20
  Duan, G.; Zhao, G.; Wu, L.; Lin, X.; Han, G. Structure, Electrical and Optical Properties of TiN x Films by Atmospheric Pressure Chemical Vapor Deposition. Appl. Surf. Sci. 2011, 257, 2428– 2431, DOI: 10.1016/j.apsusc.2010.11.180
  There is no corresponding record for this reference.
21. 21
  Pierson, H. O. A Review of the Chemical Vapor Deposition (Cvd) of the Refractory Compounds Of Titanium - A Unique Family Of Coatings. Mater. Manuf. Process. 1993, 8, 519– 534, DOI: 10.1080/10426919308934855
  There is no corresponding record for this reference.
22. 22
  Yokota, K.; Nakamura, K.; Kasuya, T.; Tamura, S.; Sugimoto, T.; Akamatsu, K.; Nakao, K.; Miyashita, F. Relationship between Hardness and Lattice Parameter for TiN Films Deposited on SUS 304 by an IBAD Technique. Surf. Coat. Technol. 2002, 158–159, 690– 693, DOI: 10.1016/S0257-8972(02)00245-1
  There is no corresponding record for this reference.
23. 23
  D’Acunto, G.; Troian, A.; Kokkonen, E.; Rehman, F.; Liu, Y. P.; Yngman, S.; Yong, Z.; McKibbin, S. R.; Gallo, T.; Lind, E.; Schnadt, J.; Timm, R. Atomic Layer Deposition of Hafnium Oxide on InAs: Insight from Time-Resolved in Situ Studies. ACS Appl. Electron. Mater. 2020, 2, 3915– 3922, DOI: 10.1021/acsaelm.0c00775
  There is no corresponding record for this reference.
24. 24
  D’Acunto, G.; Jones, R.; Pérez Ramírez, L.; Shayesteh, P.; Kokkonen, E.; Rehman, F.; Lim, F.; Bournel, F.; Gallet, J. J.; Timm, R.; Schnadt, J. Role of Temperature, Pressure, and Surface Oxygen Migration in the Initial Atomic Layer Deposition of HfO2 on Anatase TiO2(101). J. Phys. Chem. C 2022, 126, 12210– 12221, DOI: 10.1021/acs.jpcc.2c02683
  There is no corresponding record for this reference.
25. 25
  Sobell, Z. C.; George, S. M. Electron-Enhanced Atomic Layer Deposition of Titanium Nitride Films Using an Ammonia Reactive Background Gas. Chem. Mater. 2022, 34, 9624– 9633, DOI: 10.1021/acs.chemmater.2c02341
  There is no corresponding record for this reference.
26. 26
  Musschoot, J.; Xie, Q.; Deduytsche, D.; Van den Berghe, S.; Van Meirhaeghe, R. L.; Detavernier, C. Atomic Layer Deposition of Titanium Nitride from TDMAT Precursor. Microelectron. Eng. 2009, 86, 72– 77, DOI: 10.1016/j.mee.2008.09.036
  There is no corresponding record for this reference.
27. 27
  Zhu, Y.; Zhou, Z.; Zhang, X.; Xu, R.; Wang, Y.; Xu, L.; Xiao, H.; Li, X.; Li, A.; Fang, G. Surface Reaction Mechanism of Atomic Layer Deposition of Titanium Nitride Using Tetrakis(Dimethylamino)Titanium and Ammonia. Surfaces and Interfaces 2023, 36, 102579 DOI: 10.1016/j.surfin.2022.102579
  There is no corresponding record for this reference.
28. 28
  Cho, G.; Rhee, S.-W. Effect of the Amido Ti Precursors on the Atomic Layer Deposition of TiN with NH3. J. Vac. Sci. Technol. A Vacuum, Surfaces, Film. 2013, 31, 01A117 DOI: 10.1116/1.4764898
  There is no corresponding record for this reference.
29. 29
  Park, K.; Mun, G.; Cho, J.; Lee, S.; Min, G.; Hong, S. Properties of TiN Thin Films Deposited by ALD Using TDMAT Precursor in Low-Temperature Processes. J. Semicond. Dispersion Technol. 2024, 23, 14– 20
  There is no corresponding record for this reference.
30. 30
  Schnadt, J.; Knudsen, J.; Andersen, J. N.; Siegbahn, H.; Pietzsch, A.; Hennies, F.; Johansson, N.; Mårtensson, N.; Öhrwall, G.; Bahr, S.; Mähl, S.; Schaff, O. The New Ambient-Pressure X-Ray Photoelectron Spectroscopy Instrument at MAX-Lab. J. Synchrotron Radiat. 2012, 19, 701– 704, DOI: 10.1107/S0909049512032700
  There is no corresponding record for this reference.
31. 31
  Knudsen, J.; Andersen, J. N.; Schnadt, J. A Versatile Instrument for Ambient Pressure X-Ray Photoelectron Spectroscopy: The Lund Cell Approach. Surf. Sci. 2016, 646, 160– 169, DOI: 10.1016/j.susc.2015.10.038
  There is no corresponding record for this reference.
32. 32
  Kokkonen, E.; Kaipio, M.; Nieminen, H. E.; Rehman, F.; Miikkulainen, V.; Putkonen, M.; Ritala, M.; Huotari, S.; Schnadt, J.; Urpelainen, S. Ambient Pressure X-Ray Photoelectron Spectroscopy Setup for Synchrotron-Based in Situ and Operando Atomic Layer Deposition Research. Rev. Sci. Instrum. 2022, 93, 013905 DOI: 10.1063/5.0076993
  There is no corresponding record for this reference.
33. 33
  Kokkonen, E.; Da Silva, F. L.; Mikkela, M. H.; Johansson, N.; Huang, S. W.; Lee, J. M.; Andersson, M.; Bartalesi, A.; N. Reinecke, B.; Handrup, K.; Tarawneh, H.; Sankari, R.; Knudsen, J.; Schnadt, J.; Sathe, C.; Urpelainen, S. Upgrade of the SPECIES Beamline at the MAX IV Laboratory. J. Synchrotron Radiat. 2021, 28, 588– 601, DOI: 10.1107/S1600577521000564
  There is no corresponding record for this reference.
34. 34
  Tissot, H.; Gallet, J. J.; Bournel, F.; Naitabdi, A.; Pierucci, D.; Bondino, F.; Magnano, E.; Rochet, F.; Finocchi, F. Silicon Monomer Formation and Surface Patterning of Si(001)-2 × 1 Following Tetraethoxysilane Dissociative Adsorption at Room Temperature. J. Phys. Chem. C 2014, 118, 1887– 1893, DOI: 10.1021/jp407411k
  There is no corresponding record for this reference.
35. 35
  Kim, J. W.; Yeom, H. W.; Chung, Y. D.; Jeong, K.; Whang, C. N.; Lee, M. K.; Shin, H. J. Chemical Configuration of Nitrogen in Ultrathin Si Oxynitride on Si(100). Phys. Rev. B - Condens. Matter Mater. Phys. 2002, 66, 035312, DOI: 10.1103/PhysRevB.66.035312
  There is no corresponding record for this reference.
36. 36
  Verdaguer, A.; Weis, C.; Oncins, G.; Ketteler, G.; Bluhm, H.; Salmero, M. Growth and Structure of Water on SiO2 Films on Si Investigated by Kelvin Probe Microscopy and in Situ X-Ray Spectroscopies. Langmuir 2007, 23, 9699– 9703, DOI: 10.1021/la700893w
  There is no corresponding record for this reference.
37. 37
  Kim, Y. K.; Hyun, S. L.; Yeom, H. W.; Ryoo, D. Y.; Huh, S. B.; Lee, J. G. Nitrogen Bonding Structure in Ultrathin Silicon Oxynitride Films on Si(100) Prepared by Plasma Nitridation. Phys. Rev. B - Condens. Matter Mater. Phys. 2004, 70, 165320 DOI: 10.1103/PhysRevB.70.165320
  There is no corresponding record for this reference.
38. 38
  Simonsen, M. E.; Sønderby, C.; Li, Z.; Søgaard, E. G. XPS and FT-IR Investigation of Silicate Polymers. J. Mater. Sci. 2009, 44, 2079– 2088, DOI: 10.1007/s10853-009-3270-9
  There is no corresponding record for this reference.
39. 39
  Namiki, A.; Tanimoto, K.; Nakamura, T.; Ohtake, N.; Suzaki, T. XPS Study on the Early Stages of Oxidation of Si(100) by Atomic Oxygen. Surf. Sci. 1989, 222, 530– 554, DOI: 10.1016/0039-6028(89)90377-4
  There is no corresponding record for this reference.
40. 40
  Yang, J.; Wang, E. G. Reaction of Water on Silica Surfaces. Curr. Opin. Solid State Mater. Sci. 2006, 10, 33– 39, DOI: 10.1016/j.cossms.2006.02.001
  There is no corresponding record for this reference.
41. 41
  Rignanese, G. M.; Charlier, J. C.; Gonze, X. First-Principles Molecular-Dynamics Investigation of the Hydration Mechanisms of the (0001) α-Quartz Surface. Phys. Chem. Chem. Phys. 2004, 6, 1920– 1925, DOI: 10.1039/B311842H
  There is no corresponding record for this reference.
42. 42
  Miyaji, F.; Iwai, M.; Kokubo, T.; Nakamura, T. Chemical Surface Treatment of Silicone for Inducing Its Bioactivity. J. Mater. Sci. Mater. Med. 1998, 9, 61– 65, DOI: 10.1023/A:1008886729050
  There is no corresponding record for this reference.
43. 43
  Göpel, W.; Anderson, J. A.; Frankel, D.; Jaehnig, M.; Phillips, K.; Schäfer, J. A.; Rocker, G. Surface Defects of TiO2(110): A Combined XPS, XAES AND ELS Study. Surf. Sci. 1984, 139, 333– 346, DOI: 10.1016/0039-6028(84)90054-2
  There is no corresponding record for this reference.
44. 44
  Saha, N. C.; Tompkins, H. G. Titanium Nitride Oxidation Chemistry: An x-Ray Photoelectron Spectroscopy Study. J. Appl. Phys. 1992, 72, 3072– 3079, DOI: 10.1063/1.351465
  There is no corresponding record for this reference.
45. 45
  Head, A. R.; Chaudhary, S.; Olivieri, G.; Bournel, F.; Andersen, J. N.; Rochet, F.; Gallet, J. J.; Schnadt, J. Near Ambient Pressure X-Ray Photoelectron Spectroscopy Study of the Atomic Layer Deposition of TiO2 on RuO2(110). J. Phys. Chem. C 2016, 120, 243– 251, DOI: 10.1021/acs.jpcc.5b08699
  There is no corresponding record for this reference.
46. 46
  Jansen, R. J. J.; van Bekkum, H. XPS of Nitrogen-Containing Functional Groups on Activated Carbon. Carbon N. Y. 1995, 33, 1021– 1027, DOI: 10.1016/0008-6223(95)00030-H
  There is no corresponding record for this reference.
47. 47
  Bruggeman, M.; Zelzer, M.; Dong, H.; Stamboulis, A. Processing and Interpretation of Core-Electron XPS Spectra of Complex Plasma-Treated Polyethylene-Based Surfaces Using a Theoretical Peak Model. Surf. Interface Anal. 2022, 54, 986– 1007, DOI: 10.1002/sia.7125
  There is no corresponding record for this reference.
48. 48
  Cao, X.; Hamers, R. J. Silicon Surfaces as Electron Acceptors: Dative Bonding of Amines with Si(001) and Si(111) Surfaces. J. Am. Chem. Soc. 2001, 123, 10988– 10996, DOI: 10.1021/ja0100322
  There is no corresponding record for this reference.
49. 49
  Peña-Juárez, M. G.; Robles-Martínez, M.; Méndez-Rodríguez, K. B.; López-Esparza, R.; Pérez, E.; Gonzalez-Calderon, J. A. Role of the Chemical Modification of Titanium Dioxide Surface on the Interaction with Silver Nanoparticles and the Capability to Enhance Antimicrobial Properties of Poly(Lactic Acid) Composites. Polym. Bull. 2021, 78, 2765– 2790, DOI: 10.1007/s00289-020-03235-y
  There is no corresponding record for this reference.
50. 50
  Ngoc Van, T. T.; Jang, D.; Jung, E.; Noh, H.; Moon, J.; Kil, D. S.; Chung, S. W.; Shong, B. Role of Cyclopentadienyl Ligands of Group 4 Precursors toward High-Temperature Atomic Layer Deposition. J. Phys. Chem. C 2022, 126, 18090– 18099, DOI: 10.1021/acs.jpcc.2c04425
  There is no corresponding record for this reference.
51. 51
  Li, K.; Li, S.; Li, N.; Klein, T. M.; Dixon, D. A. Tetrakis(Ethylmethylamido) Hafnium Adsorption and Reaction on Hydrogen-Terminated Si(100) Surfaces. J. Phys. Chem. C 2011, 115, 18560– 18571, DOI: 10.1021/jp111600v
  There is no corresponding record for this reference.
52. 52
  Trenczek-Zajac, A.; Radecka, M.; Zakrzewska, K.; Brudnik, A.; Kusior, E.; Bourgeois, S.; de Lucas, M. C. M.; Imhoff, L. Structural and Electrical Properties of Magnetron Sputtered Ti(ON) Thin Films: The Case of TiN Doped in Situ with Oxygen. J. Power Sources 2009, 194, 93– 103, DOI: 10.1016/j.jpowsour.2008.12.112
  There is no corresponding record for this reference.
53. 53
  Killampalli, A. S.; Ma, P. F.; Engstrom, J. R. The Reaction of Tetrakis (Dimethylamido) Titanium with Self-Assembled Alkyltrichlorosilane Monolayers Possessing. J. Am. Chem. Soc. 2005, 127, 6300– 6310, DOI: 10.1021/ja047922c
  There is no corresponding record for this reference.
54. 54
  Peng, Z.; Chen, G.; Zhao, Y.-P.; Zhang, X.; Song, Y.-T.; Shirkov, G.; Karamysheva, G.; Karamyshev, O.; Calabretta, L.; Caruso, A. Investigation of TiN Film on an RF Ceramic Window by Atomic Layer Deposition. J. Vac. Sci. Technol. A Vacuum, Surfaces, Film. 2020, 38, 052401 DOI: 10.1116/6.0000159
  There is no corresponding record for this reference.
55. 55
  Nguyen, T. P.; Lefrant, S. XPS Study of SiO Thin Films and SiO-Metal Interfaces. J. Phys.: Condens. Matter 1989, 1, 5197– 5204, DOI: 10.1088/0953-8984/1/31/019
  There is no corresponding record for this reference.
56. 56
  Desbiens, E.; Dolbec, R.; El Khakani, M. A. Reactive Pulsed Laser Deposition of High- k Silicon Dioxide and Silicon Oxynitride Thin Films for Gate-Dielectric Applications. J. Vac. Sci. Technol. A Vacuum, Surfaces, Film. 2002, 20, 1157– 1161, DOI: 10.1116/1.1467357
  There is no corresponding record for this reference.
57. 57
  Ketteler, G.; Yamamoto, S.; Bluhm, H.; Andersson, K.; Starr, D. E.; Ogletree, D. F.; Ogasawara, H.; Nilsson, A.; Salmeron, M. The Nature of Water Nucleation Sites on TiO2(110) Surfaces Revealed by Ambient Pressure X-Ray Photoelectron Spectroscopy. J. Phys. Chem. C 2007, 111, 8278– 8282, DOI: 10.1021/jp068606i
  There is no corresponding record for this reference.
58. 58
  Walle, L. E.; Borg, A.; Johansson, E. M. J.; Plogmaker, S.; Rensmo, H.; Uvdal, P.; Sandell, A. Mixed Dissociative and Molecular Water Adsorption on Anatase TiO 2(101). J. Phys. Chem. C 2011, 115, 9545– 9550, DOI: 10.1021/jp111335w
  There is no corresponding record for this reference.
59. 59
  Walle, L. E.; Borg, A.; Uvdal, P.; Sandell, A. Experimental Evidence for Mixed Dissociative and Molecular Adsorption of Water on a Rutile TiO2 (110) Surface without Oxygen Vacancies. Phys. Rev. B - Condens. Matter Mater. Phys. 2009, 80, 235436 DOI: 10.1103/PhysRevB.80.235436
  There is no corresponding record for this reference.
60. 60
  Esaka, F.; Furuya, K.; Shimada, H.; Imamura, M.; Matsubayashi, N.; Sato, H.; Nishijima, A.; Kawana, A.; Ichimura, H.; Kikuchi, T. Comparison of Surface Oxidation of Titanium Nitride and Chromium Nitride Films Studied by X-Ray Absorption and Photoelectron Spectroscopy. J. Vac. Sci. Technol. A Vacuum, Surfaces, Film. 1997, 15, 2521– 2528, DOI: 10.1116/1.580764
  There is no corresponding record for this reference.
61. 61
  Jaeger, D.; Patscheider, J. Single Crystalline Oxygen-Free Titanium Nitride by XPS. Surf. Sci. Spectra 2013, 20, 1, DOI: 10.1116/11.20121107
  There is no corresponding record for this reference.
62. 62
  Chan, M. H.; Lu, F. H. X-Ray Photoelectron Spectroscopy Analyses of Titanium Oxynitride Films Prepared by Magnetron Sputtering Using Air/Ar Mixtures. Thin Solid Films 2009, 517, 5006– 5009, DOI: 10.1016/j.tsf.2009.03.100
  There is no corresponding record for this reference.
63. 63
  Robinson, K. S.; Sherwood, P. M. A. X-Ray Photoelectron Spectroscopic Studies of the Surface of Sputter Ion Plated Films. Surf. Interface Anal. 1984, 6, 261– 266, DOI: 10.1002/sia.740060603
  There is no corresponding record for this reference.
64. 64
  Cherono, S.; Chris-Okoro, I.; Liu, M.; Kim, R. S.; Nalawade, S.; Akande, W.; Maria-Diana, M.; Mahl, J.; Hale, C.; Yano, J.; Aravamudhan, S.; Crumlin, E.; Craciun, V.; Kumar, D. Transformation of TiN to TiNO Films via In-Situ Temperature-Dependent Oxygen Diffusion Process and Their Electrochemical Behavior. Metals (Basel). 2025, 15, 497, DOI: 10.3390/met15050497
  There is no corresponding record for this reference.
65. 65
  Kuznetsov, M. V.; Zhuravlev, J. F.; Zhilyaev, V. A.; Gubanov, V. A. XPS Study of the Nitrides, Oxides and Oxynitrides of Titanium. J. Electron Spectrosc. Relat. Phenom. 1992, 58, 1, DOI: 10.1016/0368-2048(92)80001-O
  There is no corresponding record for this reference.
66. 66
  Kabachkov, E.; Kurkin, E.; Vershinin, N.; Balikhin, I.; Berestenko, V.; Michtchenko, A.; Shulga, Y. Synthesis and Properties of Pt/TiN Catalyst for Low-Temperature Air Purification from Carbon Monoxide. J. Adv. Mater. Technol. 2021, 6, 131– 143, DOI: 10.17277/jamt.2021.02.pp.131-143
  There is no corresponding record for this reference.
67. 67
  George, S. M. Atomic Layer Deposition: An Overview. Chem. Rev. 2010, 110, 111– 131, DOI: 10.1021/cr900056b
  There is no corresponding record for this reference.
68. 68
  Corneille, J. S.; Chen, P. J.; Truong, C. M.; Oh, W. S.; Goodman, D. W. Surface Spectroscopic Studies of the Deposition of TiN Thin Films from Tetrakis-(Dimethylamido)-Titanium and Ammonia. J. Vac. Sci. Technol. A Vacuum, Surfaces, Film. 1995, 13, 1116– 1120, DOI: 10.1116/1.579596
  There is no corresponding record for this reference.
69. 69
  Xiong, H.; Wu, L.; Liu, Y.; Gao, T.; Li, K.; Long, Y.; Zhang, R.; Zhang, L.; Qiao, Z. A.; Huo, Q.; Ge, X.; Song, S.; Zhang, H. Controllable Synthesis of Mesoporous TiO2 Polymorphs with Tunable Crystal Structure for Enhanced Photocatalytic H2 Production. Adv. Energy Mater. 2019, 9, 1901634 DOI: 10.1002/aenm.201901634
  There is no corresponding record for this reference.
70. 70
  Peng, F.; Cai, L.; Huang, L.; Yu, H.; Wang, H. Preparation of Nitrogen-Doped Titanium Dioxide with Visible-Light Photocatalytic Activity Using a Facile Hydrothermal Method. J. Phys. Chem. Solids 2008, 69, 1657– 1664, DOI: 10.1016/j.jpcs.2007.12.003
  There is no corresponding record for this reference.
71. 71
  Zhang, H.; Wang, B.; Brown, B. Atomic Layer Deposition of Titanium Oxide and Nitride on Vertically Aligned Carbon Nanotubes for Energy Dense 3D Microsupercapacitors. Appl. Surf. Sci. 2020, 521, 146349 DOI: 10.1016/j.apsusc.2020.146349
  There is no corresponding record for this reference.
72. 72
  Mpofu, P.; Niiranen, P.; Alm, O.; Lauridsen, J.; Larsson, T.; Pedersen, H. Atomic Layer Deposition of AlxTi1-XN via Co-Evaporation of Metal Precursors. J. Vac. Sci. Technol. A 2025, 43, 032405 DOI: 10.1116/6.0004420
  There is no corresponding record for this reference.
73. 73
  Jintsugawa, O.; Sakuraba, M.; Matsuura, T.; Murota, J. Thermal Nitridation of Ultrathin SiO2 on Si by NH3. Surf. Interface Anal. 2002, 34, 456– 459, DOI: 10.1002/sia.1337
  There is no corresponding record for this reference.
74. 74
  Graf, N.; Yegen, E.; Gross, T.; Lippitz, A.; Weigel, W.; Krakert, S.; Terfort, A.; Unger, W. E. S. XPS and NEXAFS Studies of Aliphatic and Aromatic Amine Species on Functionalized Surfaces. Surf. Sci. 2009, 603, 2849– 2860, DOI: 10.1016/j.susc.2009.07.029
  There is no corresponding record for this reference.
75. 75
  Dietrich, P. M.; Graf, N.; Gross, T.; Lippitz, A.; Krakert, S.; Schüpbach, B.; Terfort, A.; Unger, W. E. S. Amine Species on Self-Assembled Monolayers of ω-Aminothiolates on Gold as Identified by XPS and NEXAFS Spectroscopy. Surf. Interface Anal. 2010, 42, 1184– 1187, DOI: 10.1002/sia.3224
  There is no corresponding record for this reference.
76. 76
  Solís, R. R.; Gómez-Avilés, A.; Belver, C.; Rodriguez, J. J.; Bedia, J. Microwave-Assisted Synthesis of NH2-MIL-125(Ti) for the Solar Photocatalytic Degradation of Aqueous Emerging Pollutants in Batch and Continuous Tests. J. Environ. Chem. Eng. 2021, 9, 106230 DOI: 10.1016/j.jece.2021.106230
  There is no corresponding record for this reference.
77. 77
  Endle, J. P.; Sun, Y.; White, J. M.; Ekerdt, J. G. X-Ray Photoelectron Spectroscopy Study of TiN Films Produced with Tetrakis(Dimethylamido)Titanium and Selected N-Containing Precursors on SiO2. J. Vac. Sci. Technol. A 1998, 16, 1262– 1267, DOI: 10.1116/1.581271
  There is no corresponding record for this reference.
78. 78
  Quesada-Cabrera, R.; Sotelo-Vazquez, C.; Darr, J. A.; Parkin, I. P. Critical Influence of Surface Nitrogen Species on the Activity of N-Doped TiO2 Thin-Films during Photodegradation of Stearic Acid under UV Light Irradiation. Appl. Catal. B Environ. 2014, 160–161, 582– 588, DOI: 10.1016/j.apcatb.2014.06.010
  There is no corresponding record for this reference.
79. 79
  Asghar, M.; Yousaf, M.; Huwaimel, B.; Iqbal, T.; Ahmed, I.; Qureshi, M. T.; Abrar, M.; Shafiq, M.; Almohammedi, A.; Hameed, R. A.; AlElaimi, M.; Maryam, M.; Afsheen, S. Synthesis of Biocompatible Coating on Ni-Cr Alloy by Cathodic Cage Plasma Processing Technique as Anti-Pathogenic Bacteria for Medicinal Applications. Phys. Scr. 2023, 98, 055920 DOI: 10.1088/1402-4896/acc908
  There is no corresponding record for this reference.
80. 80
  Braic, L.; Vasilantonakis, N.; Mihai, A.; Villar Garcia, I. J.; Fearn, S.; Zou, B.; Alford, N. M. N.; Doiron, B.; Oulton, R. F.; Maier, S. A.; Zayats, A. V.; Petrov, P. K. Titanium Oxynitride Thin Films with Tunable Double Epsilon-Near-Zero Behavior for Nanophotonic Applications. ACS Appl. Mater. Interfaces 2017, 9, 29857– 29862, DOI: 10.1021/acsami.7b07660
  There is no corresponding record for this reference.
81. 81
  Li, K.; Li, S.; Li, N.; Dixon, D. A.; Klein, T. M. Tetrakis(Dimethylamido)Hafnium Adsorption and Reaction on Hydrogen Terminated Si(100) Surfaces. J. Phys. Chem. C 2010, 114, 14061– 14075, DOI: 10.1021/jp101363r
  There is no corresponding record for this reference.
82. 82
  Ruhl, G.; Rehmet, R.; Knfžvá, M.; Vepřek, S. In Situ XPS Studies of the Deposition of Thin Films from Tetrakis(Dimethylamido)Titanium Organometallic Precursor for Diffusion Barriers. MRS Online Proc. Libr. 1993, 309, 461– 466, DOI: 10.1557/PROC-309-461
  There is no corresponding record for this reference.
83. 83
  NIST NIST Standard Reference Database Number 20. https://dx.doi.org/10.18434/T4T88K (accessed Apr 7, 2025).
  There is no corresponding record for this reference.
84. 84
  Longrie, D.; Deduytsche, D.; Haemers, J.; Smet, P. F.; Driesen, K.; Detavernier, C. Thermal and Plasma-Enhanced Atomic Layer Deposition of TiN Using TDMAT and NH3 on Particles Agitated in a Rotary Reactor. ACS Appl. Mater. Interfaces 2014, 6, 7316– 7324, DOI: 10.1021/am5007222
  There is no corresponding record for this reference.
85. 85
  Elam, J. W.; Schuisky, M.; Ferguson, J. D.; George, S. M. Surface Chemistry and Film Growth during TiN Atomic Layer Deposition Using TDMAT and NH3. Thin Solid Films 2003, 436, 145– 156, DOI: 10.1016/S0040-6090(03)00533-9
  There is no corresponding record for this reference.
86. 86
  Biesinger, M. C.; Lau, L. W. M.; Gerson, A. R.; Smart, R. S. C. Resolving Surface Chemical States in XPS Analysis of First Row Transition Metals, Oxides and Hydroxides: Sc, Ti, V, Cu and Zn. Appl. Surf. Sci. 2010, 257, 887– 898, DOI: 10.1016/j.apsusc.2010.07.086
  There is no corresponding record for this reference.
87. 87
  Methaapanon, R.; Bent, S. F. Comparative Study of Titanium Dioxide Atomic Layer Deposition on Silicon Dioxide and Hydrogen-Terminated Silicon. J. Phys. Chem. C 2010, 114, 10498– 10504, DOI: 10.1021/jp1013303
  There is no corresponding record for this reference.
88. 88
  Weiller, B. H. Chemical Vapor Deposition of TiN from Tetrakis(Dimethylamido)Titanium and Ammonia: Kinetics and Mechanistic Studies of the Gas-Phase Chemistry. J. Am. Chem. Soc. 1996, 118, 4975– 4983, DOI: 10.1021/ja953468o
  There is no corresponding record for this reference.
89. 89
  Hughes, K. J.; Engstrom, J. R. Nucleation Delay in Atomic Layer Deposition on a Thin Organic Layer and the Role of Reaction Thermochemistry. J. Vac. Sci. Technol. A Vacuum, Surfaces, Film. 2012, 30, 01A102 DOI: 10.1116/1.3625564
  There is no corresponding record for this reference.
90. 90
  Mpofu, P.; Hafdi, H.; Lauridsen, J.; Alm, O.; Larsson, T.; Pedersen, H. A Mass Spectrometrical Surface Chemistry Study of Aluminum Nitride ALD from Tris-Dimethylamido Aluminum and Ammonia. Mater. Adv. 2024, 5, 9259– 9269, DOI: 10.1039/D4MA00922C
  There is no corresponding record for this reference.
91. 91
  Lee, W. J.; Yun, E. Y.; Lee, H. B. R.; Hong, S. W.; Kwon, S. H. Dataset for TiN Thin Films Prepared by Plasma-Enhanced Atomic Layer Deposition Using Tetrakis(Dimethylamino)Titanium (TDMAT) and Titanium Tetrachloride (TiCl4) Precursor. Data Br. 2020, 31, 105777 DOI: 10.1016/j.dib.2020.105777
  There is no corresponding record for this reference.
92. 92
  Yun, J.; Park, M.; Rhee, S. Comparison of Tetrakis(Dimethylamido)Titanium and Tetrakis(Diethylamido)Titanium as Precursors for Metallorganic Chemical Vapor Deposition of Titanium Nitride. J. Electrochem. Soc. 1999, 146, 1804– 1808, DOI: 10.1149/1.1391847
  There is no corresponding record for this reference.
93. 93
  Sen, K.; Banu, T.; Debnath, T.; Ghosh, D.; Das, A. K. Towards a Comprehensive Understanding of the Chemical Vapor Deposition of Titanium Nitride Using Ti(NMe2)4: A Density Functional Theory Approach. Dalt. Trans. 2014, 43, 8877– 8887, DOI: 10.1039/c4dt00690a
  There is no corresponding record for this reference.
94. 94
  Dubois, L. H.; Zegarski, B. R.; Girolami, G. S. Infrared Studies of the Surface and Gas Phase Reactions Leading to the Growth of Titanium Nitride Thin Films from Tetrakis(Dimethylamido)Titanium and Ammonia. J. Electrochem. Soc. 1992, 139, 3603– 3609, DOI: 10.1149/1.2087327
  There is no corresponding record for this reference.
95. 95
  Mpofu, P.; Hafdi, H.; Niiranen, P.; Lauridsen, J.; Alm, O.; Larsson, T.; Pedersen, H. Surface Chemistry in Atomic Layer Deposition of AlN Thin Films from Al(CH3)3 and NH3 Studied by Mass Spectrometry. J. Mater. Chem. C 2024, 12, 12818– 12824, DOI: 10.1039/D4TC01867B
  There is no corresponding record for this reference.
Supporting Information
Supporting Information
The Supporting Information is available free of charge at https://pubs.acs.org/doi/10.1021/acs.chemmater.5c02974.
- Additional details from the APXPS measurements (PDF)
- cm5c02974_si_001.pdf (738.39 kb)
Terms & Conditions

Most electronic Supporting Information files are available without a subscription to ACS Web Editions. Such files may be downloaded by article for research use (if there is a public use license linked to the relevant article, that license may permit other uses). Permission may be obtained from ACS for other uses through requests via the RightsLink permission system: http://pubs.acs.org/page/copyright/permissions.html.

Surface Chemistry in the Initial Stages of Titanium Nitride Atomic Layer Deposition Using Operando Ambient Pressure X-ray Photoelectron SpectroscopyClick to copy article linkArticle link copied!

Chemistry of Materials

License Summary*

Abstract

License Summary*

License Summary*

License Summary*

1. Introduction

2. Methods

2.1. APXPS

2.2. Film Deposition

2.3. Data Analysis

2.4. Residual Gas Analysis

3. Results

First ALD Half-Cycle: TDMAT

Figure 1

Second ALD Half-Cycle: NH3

Figure 2

Figure 3

Three Additional ALD Cycles: 3 × (TDMAT + NH3)

Figure 4

Figure 5

O 1s

Ti 2p

N 1s

C 1s

Mass Spectrometry

Figure 6

4. Discussion

Reaction Mechanisms

Figure 7

5. Conclusions

Supporting Information

Terms & Conditions

Author Information

Acknowledgments

References

Cited By

Chemistry of Materials

License Summary*

Article Views

Altmetric

Citations

Recommended Articles

Abstract

Figure 1

Figure 2

Figure 3

Figure 4

Figure 5

Figure 6

Figure 7

References

Supporting Information

Supporting Information

Terms & Conditions

Surface Chemistry in the Initial Stages of Titanium Nitride Atomic Layer Deposition Using Operando Ambient Pressure X-ray Photoelectron Spectroscopy
Click to copy article linkArticle link copied!

Second ALD Half-Cycle: NH₃

Three Additional ALD Cycles: 3 × (TDMAT + NH₃)