Ab Initio Study of the Atomic Level Structure of the Rutile TiO2(110)–Titanium Nitride (TiN) Interface

Moreno, José Julio Gutiérrez; Nolan, Michael

doi:10.1021/acsami.7b08840

Cited by 29 publications

(27 citation statements)

References 66 publications

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“…Figure 6a showed the PDOS of selected atoms in the HfN-TiO2 system, where TiO2 and HfN slabs are kept far apart to ensure there is no interaction between them. As expected, the plot showed TiO2 to be a wide bandgap n-type semiconductor whose valence and conduction bands are mostly composed of O-2p and Ti-3d states [51]. These figures also showed the electronic properties of HfN to be metallic with overlapped valence and conduction bands that are mostly composed of Hf d-states, which is consistent with earlier findings [8].…”

Section: Quantum Computation Resultssupporting

confidence: 90%

TiO2-HfN Radial Nano-Heterojunction: A Hot Carrier Photoanode for Sunlight-Driven Water-Splitting

et al. 2021

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The lack of active, stable, earth-abundant, and visible-light absorbing materials to replace plasmonic noble metals is a critical obstacle for researchers in developing highly efficient and cost-effective photocatalytic systems. Herein, a core–shell nanotube catalyst was fabricated consisting of atomic layer deposited HfN shell and anodic TiO2 support layer with full-visible regime photoactivity for photoelectrochemical water splitting. The HfN active layer has two unique characteristics: (1) A large bandgap between optical and acoustic phonon modes and (2) No electronic bandgap, which allows a large population of long life-time hot carriers, which are used to enhance the photoelectrochemical performance. The photocurrent density (≈2.5 mA·cm−2 at 1 V vs. Ag/AgCl) obtained in this study under AM 1.5G 1 Sun illumination is unprecedented, as it is superior to most existing plasmonic noble metal-decorated catalysts and surprisingly indicates a photocurrent response that extends to 730 nm. The result demonstrates the far-reaching application potential of replacing active HER/HOR noble metals such as Au, Ag, Pt, Pd, etc. with low-cost plasmonic ceramics.

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Section: Quantum Computation Resultssupporting

confidence: 90%

TiO2-HfN Radial Nano-Heterojunction: A Hot Carrier Photoanode for Sunlight-Driven Water-Splitting

et al. 2021

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“…This correction is applied to account for the potential reduction of Ti atoms that can form in the TiO 2 -TiN interface. The U value was chosen in consistency with our previous works on TiO 2 -TiN interfaces 40,54 and surface modified TiO 2 . 63 We use Bader charge analysis 64 to assess the localization of reduced Ti cations.…”

Section: Computational Detailsmentioning

confidence: 99%

“…The features observed in the structure of 2-layer thick TiO 2 -TiN interfaces are consistent with our previous model with a thicker oxide layer. 40…”

Section: Structure Of Ultra-thin Tio 2 On Tin Substratementioning

confidence: 99%

“…In our previous study, we found that the introduction of several O vacancies becomes more favourable, leading to the stability of highly nonstoichiometric systems. 40 Based on these results, in addition to the single vacancy system in the 2-layer thick TiO 2 model, we also consider the formation of highly non-stoichiometric interfaces, in which all of the bridging O are removed from the interface region. Figure 4 depicts the structure of 2-layer thick interface models with 6 interfacial oxygen vacancies, which results in an interface with the oxide composition of TiO 1.75 -TiN.…”

Section: Defects In Tio 2 -Tin Interface Modelsmentioning

confidence: 99%

“…37 From experiments, it is observed that TiN deposited by CVD on Si (100) forms a uniform film with stoichiometric composition and predominance of (200) out-of-plane orientation at deposition temperatures in the range of 400-700 º C. 38 The epitaxial growth of TiO 2 on TiN leads to the formation of rutile TiO 2 (110) with the presence of an interfacial oxynitride (TiN x O y ) transition layer. 39 In a previous publication, 40 we used Hubbard corrected density functional theory (DFT+U) to study the structure and electronic properties of rutile TiO 2 (110)-TiN (100) interfaces. We have found that in the rutile (110)-TiN interface system defects such as Ti vacancies in TiN, O vacancies in TiO 2 or interdiffusion of O and N atoms within the interface may be present.…”

Section: Introductionmentioning

confidence: 99%

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Structure, Stability and Water Adsorption on Ultra-Thin TiO2 Supported on TiN

Moreno

Fronzi²,

Lovera³

et al. 2019

Preprint

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Interfacial metal-oxide systems with ultrathin oxide layers are of high interest for their use in catalysis. In this study, we present a density functional theory (DFT) investigation of the structure of ultrathin rutile layers (one and two TiO2 layers) supported on TiN and the stability of water on these interfacial structures. The rutile layers are stabilized on the TiN surface through the formation of interfacial Ti–O bonds. Charge transfer from the TiN substrate leads to the formation of reduced Ti3+ cations in TiO2. The structure of the one-layer oxide slab is strongly distorted at the interface, while the thicker TiO2 layer preserves the rutile structure. The energy cost for the formation of a single O vacancy in the one-layer oxide slab is only 0.5 eV with respect to the ideal interface. For the two-layer oxide slab, the introduction of several vacancies in an already non-stoichiometric system becomes progressively more favourable, which indicates the stability of the highly non-stoichiometric interfaces. Isolated water molecules dissociate when adsorbed at the TiO2 layers. At higher coverages the preference is for molecular water adsorption. Our ab initio thermodynamics calculations show the fully water covered stoichiometric models as the most stable structure at typical ambient conditions. Interfacial models with multiple vacancies are most stable at low (reducing) oxygen chemical potential values. A water monolayer adsorbs dissociatively on the highly distorted 2-layer TiO1.75-TiN interface, where the Ti3+ states lying above the top of the valence band contribute to a significant reduction of the energy gap compared to the stoichiometric TiO2-TiN model. Our results provide a guide for the design of novel interfacial systems containing ultrathin TiO2 with potential application as photocatalytic water splitting devices.

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A Versatile Strategy for Achieving Fast‐Charging Batteries via Interfacial Engineering: Pseudocapacitive Potassium Storage without Nanostructuring

Kim

Jung

Lim

et al. 2022

Small

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over the past two decades. [1] In particular, intensive research on the rocking-chair type insertion/extraction behavior of alkali ions into electrodes has expanded the rechargeable battery market from portable electronic devices to electric vehicles (EVs). [2] However, this significant shift in the battery paradigm to high-energy-density applications has resulted in challenges related to charging time. [3] For example, several hours are inevitably required to charge EVs completely using the current battery technology, far the behind practical goal that EVs charge to 80% of state of charge (ΔSOC) within only 10-15 min. [4] Therefore, the fast-charging capability of rechargeable batteries has become an essential requirement in modern society to adopt EVs and future energy systems. [5] Generally, the fast-charging properties of batteries depend on the transport kinetics of alkali ions in electrodes; hence, a short diffusion time of alkali ions in solid-state active material is highly required. [6] The diffusion time (τ) of alkali ions in electrodes is related to the diffusion length (L) and diffusivity (D), as follows: τ = L 2 × D −1 . [7] As the diffusion time is dependent on the values of L and D, approaches to shorten the diffusion length and to increase the diffusivity of alkali ions have been mainly investigated in the design of fast-charging batteries. [8] Recently,The rapid transport of alkali ions in electrodes is a long-time dream for fast-charging batteries. Though electrode nanostructuring has increased the rate-capability, its practical use is limited because of the low tap density and severe irreversible reactions. Therefore, development of a strategy to design fast-charging micron-sized electrodes without nanostructuring is of significant importance. Herein, a simple and versatile strategy to accelerate the alkali ion diffusion behavior in micron-sized electrode is reported. It is demonstrated that the diffusion rate of K + ions is significantly improved at the hetero-interface between orthorhombic Nb 2 O 5 (001) and monoclinic MoO 2 (110) planes. Lattice distortion at the hetero-interface generates an inner space large enough for the facile transport of K + ions, and electron localization near oxygen-vacant sites further enhances the ion diffusion behavior. As a result, the interfacial-engineered micron-sized anode material achieves an outstanding rate capability in potassium-ion batteries (KIBs), even higher than nanostructured orthorhombic Nb 2 O 5 which is famous for fast-charging electrodes. This is the first study to develop an intercalation pseudocapacitive micron-sized anode without nanostructuring for fast-charging and high volumetric energy density KIBs. More interestingly, this strategy is not limited to K + ion, but also applicable to Li + ion, implying the versatility of interfacial engineering for alkali ion batteries.

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Ab Initio Study of the Atomic Level Structure of the Rutile TiO₂(110)–Titanium Nitride (TiN) Interface

Cited by 29 publications

References 66 publications

TiO2-HfN Radial Nano-Heterojunction: A Hot Carrier Photoanode for Sunlight-Driven Water-Splitting

TiO2-HfN Radial Nano-Heterojunction: A Hot Carrier Photoanode for Sunlight-Driven Water-Splitting

Structure, Stability and Water Adsorption on Ultra-Thin TiO2 Supported on TiN

A Versatile Strategy for Achieving Fast‐Charging Batteries via Interfacial Engineering: Pseudocapacitive Potassium Storage without Nanostructuring

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