第一性原理计算N掺杂对InNbO4电子结构的影响

宽带隙（3.83 eV）半导体光催化材料InNbO4在紫外光作用下具有分解水和降解有机物的性能。最近实验发现了N掺杂InNbO4具有可见光下分解水制氢的活性。为了从理论上解释这一实验现象，本文采用基于密度泛函理论的第一性原理计算了N掺杂对InNbO4的能带结构、态密度和光学性质的影响。分析能带结构可得，N掺杂后在InNbO4的价带（O 2p）上方形成N 2p局域能级，导致电子跃迁所需的能量减小。吸收光谱表明，N掺杂后InNbO4的光吸收边出现了红移，实现了可见光吸收。     

N-S共掺杂金红石相TiO2电子结构与光学性质的第一性原理研究

采用基于第一性原理的平面波超软赝势方法研究N和S单掺杂以及N和S共掺杂金红石相TiO2的能带结构,态密度和光学性质.结果表明:N掺杂导致禁带宽度减小为1.43 eV,并且在价带上方形成了一条杂质能带;S掺杂导致费米能级上移靠近导带,直接带隙减小为0.32 eV;N和S共掺杂导致能带结构中出现了两条杂质能带,靠近导带的一条杂质能级距离导带底约0.35 eV,靠近价带的一条杂质能级距离价带顶约0.85 eV,杂质能级主要由N原子的2p轨道和S原子的3p轨道组成.N和S掺杂后不但使TiO2的吸收带产生红移,而且在可见光区具有较大的吸收系数,光催化活性增强.     

Fe-N共掺杂锐钛矿相TiO2电子性质与光学性质的第一性原理研究

近年来,Fe和N掺杂锐钛矿相TiO2半导体在实验中发现许多优异性能,本文采用基于密度泛函理论的平面波超软赝势方法研究了纯锐钛矿相TiO2、Fe和N单掺杂及Fe和N共掺杂TiO2的能带结构、电荷布居、态密度和光学性质.分析发现:Fe掺杂引起杂质能带位于禁带中央,杂质能带最高点与导带相距大约0.6 eV而最低点与价带相距大约0.2 eV;N掺杂引起的杂质能带位于价带顶部附近. Fe和N共掺杂后杂质能带由两部分组成,位于价带顶上方0.62 eV和导带底下方0.22 eV处,其中一层杂质能带主要由N原子的2p轨道和Fe原子的3d轨道杂化形成,而另一条杂质能带主要由Fe原子的3d轨道形成,由于杂质能级的出现,使锐钛矿TiO2的禁带宽度变小.对光学性质分析发现:Fe和N共掺杂会使锐钛矿TiO2光学吸收带边红移,可见光区的光吸收系数明显增大,在低能区出现了新的吸收峰,对应能量为1.82 eV,与实验结果相符.     

Mn-N共掺杂TiO_2电子结构和光学性质的第一性原理计算

本文采用第一性原理研究了Mn、N掺杂TiO_2和Mn-N共掺杂TiO_2的能带结构、态密度和Mn-N共掺TiO_2对体系介电函数与吸收谱的影响.研究结果表明,Mn掺杂TiO_2的能带结构的禁带内出现的杂质能级是由Mn的3d轨道贡献;N掺杂TiO_2在费米能级处的杂质能级则由O 2p,Ti 3d和N 2p轨道杂化形成;Mn-N共掺的TiO_2能带在费米能级处的杂质能级则由O 2p,Ti和Mn的3d以及N 2p轨道杂化形成;对于介电函数,在低能区间(2.5 e V),理想TiO_2无介电峰,Mn-N共掺体系则出现了两个介电峰,原因在于Mn 3d态和N 2p态使介电峰值向低能区移动;同时,与理想TiO_2的吸收谱相比,最大的变化是在可见光区出现了一个吸收峰,且在可见光区的响应的范围变宽.     

Mn-N共掺杂TiO2电子结构和光学性质的第一性原理计算

本文采用第一性原理研究了Mn、N掺杂TiO2和Mn-N共掺杂TiO2的能带结构、态密度和Mn-N共掺TiO2对体系介电函数与吸收谱的影响.研究结果表明,Mn掺杂TiO2的能带结构的禁带内出现的杂质能级是由Mn 的3d轨道贡献;N掺杂TiO2在费米能级处的杂质能级则由O 2p, Ti 3d和N 2p轨道杂化形成; Mn-N共掺的TiO2能带在费米能级处的杂质能级则由O 2p, Ti 和Mn的3d以及N 2p轨道杂化形成; 对于介电函数,在低能区间(<2.5 eV),理想TiO2无介电峰, Mn-N共掺体系则出现了两个介电峰,原因在于Mn 3d态和N 2p态使介电峰值向低能区移动;同时,与理想TiO2的吸收谱相比,最大的变化是在可见光区出现了一个吸收峰,且在可见光区的响应的范围变宽.     

过渡金属(Ni)掺杂ZnV2O4的第一性原理计算

采用基于密度泛函理论下的MS软件模拟了过渡金属Ni掺杂ZnV₂O₄前后的能带结构、态密度以及光学性质.结果表明：ZnV₂O₄具有间接的光学跃迁且能带间隙为0.355 eV,Ni掺杂后能带间隙增加为0.785 eV,且带隙类型不变,引入的Ni-3d轨道电子对ZnV₂O₄的价带和导带组成提供了较大贡献.光学性质结果表明ZnV₂O₄为一种低介电材料,在可见光区的吸收系数和折射率较低,主要表现为紫外吸收.掺杂Ni后,在可见光区的吸收特性和光电导率均增大,有效改善了ZnV₂O₄在可见光区的光电性能.     

Be,C双受主共掺杂实现P型AlN的第一性原理研究

基于密度泛函理论(Density Functional Theory)的第一性原理平面波超软赝势方法(USPP),首先对Be、C掺杂Al N的晶格结构进行优化,得到其稳定结构.然后对Be、C掺杂Al N的晶格参数、结合能、能带结构、电子态密度和电荷集居数进行了详细地计算和分析.计算结果表明:Be-2C共掺杂Al N的构型具有更稳定的结构,能使受主能级变宽、非局域化特征明显.因此,Be-2C共掺杂Al N有望成为一种更稳定高效的p型掺杂手段.     

Mn2+、N2-共掺杂Zn2GeO4晶体电子结构和光学性质的研究

采用基于密度泛函理论的平面波超软赝势方法对本征Zn2GeO4，Mn2+掺杂Zn2GeO4，Mn2+/N2-共掺杂Zn2GeO4超晶胞进行了几何结构优化，计算了掺杂前后体系的晶格常数、能带结构、态密度和光学性质。结果表明，Mn离子掺入后，Mn离子3d轨道与O离子2p轨道之间有强烈的轨道杂化效应，掺杂系统不稳定，而Mn/N离子共掺后，Mn离子和N离子之间的吸引作用克服了Mn离子之间的排斥作用，能够明显地提高掺杂浓度和体系的稳定性。光学性质计算结果表明，Mn离子与N离子共掺杂能改善Zn2GeO4电子在低能区的光学跃迁特性，增强电子在可见光区的光学跃迁；吸收谱计算结果显示，Mn离子与N离子掺入后体系对低频电磁波吸收增加。     

N掺杂锐钛矿TiO2电子结构的第一性原理研究

为了研究N掺杂对锐钛矿型TiO2电子结构的影响,进而揭示N掺杂导致锐钛矿型TiO2的禁带宽度变小的机理,对N掺杂TiO2进行了基于密度泛函理论的第一性原理研究.通过对能带、态密度及电子分布密度图的分析,发现在N掺杂后,N原子与Ti原子在导带区,发生了强烈的相互关联作用,致使Ti原子3d轨道上的电子向N原子2p轨道发生移动,使得导带降低了,从而使得TiO2导带的禁带宽度变小.理论预测可以发生红移现象,与实验结果对比分析,理论与实验基本相符.     

(Nb,N)共掺杂锐钛矿电子结构和光学性质的第一性原理研究

二氧化钛（TiO₂）作为一种性能优良的光催化剂已经受到越来越多的关注.本研究采用密度泛函理论的第一性原理和广义梯度近似+U方法,对锐钛矿结构TiO₂晶体三种可能的（Nb,N）共掺杂TiO₂的几何结构、形成能、能带结构、电子密度和光吸收系数进行了研究,并与单掺杂（Nb/N）体系进行了对比.对掺杂后体系的几何结构进行的计算表明杂质原子掺入后晶格发生了不同程度的畸变.此外,（Nb,N）共掺杂体系与纯TiO₂相比,其禁带宽度和吸收边较小.同时,与N掺杂TiO₂相比,N的2p态在共掺杂情形下变为完全占据,从而减少了电子空穴对的复合.而且共掺杂体系的形成能比N单掺杂体系低,因而更加稳定.因此,（Nb,N）共掺杂可以很好地提升锐钛矿型TiO₂在可见光波段的光催化性能.     

Experimental and computational study of visible light-induced photocatalytic ability of nitrogen ions-implanted TiO2 nanotubes

Nitrogen-doped TiO2 nanotubes(TNTs)were prepared by ion implantation and anodic oxidation.The prepared samples were applied in photocatalytic(PC)oxidation of methyl blue,rhodamine B,and bisphenol A under light irradiation.To explore the influence of doped ions on the band and electronic structure of TiO2,computer simulations were performed using the VASP code implementing spin-polarized density functional theory(DFT).Both substitutional and interstitial nitrogen atoms were considered.The experimental and computational results propose that the electronic structure of TiO2 was modified because of the emergence of impurity states in the band gap by introducing nitrogen into the lattice,leading to the absorption of visible light.The synergy effects of tubular structures and doped nitrogen ions were responsible for highly efficient and stable PC activities induced by visible and ultraviolet(UV)light.     

First-principles investigation of impurity concentration influence on bonding behavior,electronic structure and visible light absorption for Mn-doped BiOCl photocatalyst

We performed first-principles calculation to investigate the bonding behavior, electronic structure and visible light absorption of Mn_xBi_1−xOCl (x=0, 0.0625, 0.09375 and 0.125) using density functional theory (DFT) within a plane-wave ultrasoft pseudopotential scheme. The relaxed structural parameters are consistent with the experimental results. The bonding behavior, bond orders, Mulliken charges and bond populations as well as formation energies are obtained. The calculated band structures and density of states show that Mn incorporation results in some impurity energy levels of Mn 3d states in forbidden band as well as valence band and conduction band, and that Mn 3d states, for the modest Mn doping concentration, not only can act as the capture center of excited electrons under longer wavelength light irradiation, but also may trap the photo-excited holes, improving the transfer of photo-excited carriers to the reactive sites. Our calculated optical absorption spectra exhibit that the spectral absorption edge is obviously red-shifted and extends to the visible, red and infrared light region due to the incorporation of Mn. Our calculated absorption spectra are in excellent agreement with the experimental results of Mn-doped BiOCl photocatalyst.     

Photostability and visible-light-driven photoactivity enhancement of hierarchical ZnS nanoparticles: The role of embedment of stable defect sites on the catalyst surface with the assistant of ultrasonic waves

Zinc sulfide is a UV-active photocatalyst and it undergoes photocorrosion under light irradiation. In this work, the defect sites on ZnS nanoparticles (NPs) surfaces were induced with the help of powerful ultrasonic waves. The defect sites caused (1) suppression of photocorrosion in a large extent under UV light irradiation and (2) enhancement of visible light photo activity. The photocorrosion inhibition was induced by raising valence band (VB) position through the formation of interstitial zinc and sulfur vacancy states in the ZnS band structure and weakening of oxidative capacity of hole. The enhancement of visible light photocatalytic activity may be related to the generation of more defect energy states in the ZnS band gap. Under visible light irradiation, the electron was excited from the ZnS VB to the interstitial sulfur and zinc vacancy states before injecting into the conduction band of ZnS. Therefore, we modified the band gap of ZnS so that it acts as a visible light active photocatalyst. ZnS NPs were prepared using two different classical and ultrasound methods. The prepared ZnS using ultrasound method, exhibited more outstanding photocatalytic activity for degrading reactive black 5 (RB5) under UV and sunlight irradiation in comparison with the classical method. Details of the degradation mechanism under UV light were investigated. This work provides new insights to understanding the photocorrosion stability and visible light activity of bare ZnS photocatalyst.     

替位和间隙原子N对ZnO电子结构和光学性质的影响

本文采用密度泛函理论，深入研究了N作为替位和间隙原子对ZnO电子结构和光学性质的影响，结果表明：由于N在八面体间隙位置的形成能小所以更倾向于占据八面体间隙位置；N掺杂ZnO会形成p型半导体；N在间隙位置能够明显的缩小带隙宽度，可以有效的促进ZnO对光的吸收；在可见光区，处于间隙位置的N具有良好的光学吸收谱并且产生明显的红移，这与带隙的变化规律一致。     

Influence of high-energy X-ray irradiation on the optical properties of tetraphenylporphyrin thin films

Tetraphenylporphyrin (TPP) thermally evaporated films were irradiated by different doses (0.5–2.5 kGy) of X-ray with energy 6 MeV. The optical properties for TPP were investigated using spectrophotometric measurements of the transmittance and reflectance at normal incidence of light in the wavelength range from 200 to 1100 nm. The absorption spectra recorded in the UV-VIS region of spectra showed different absorption bands, namely four Q-bands in the visible region of the spectrum and a more intense band termed as the Soret band in the near-UV region of the spectrum. Two other bands labeled N and M appear in the UV region. The Soret band showed Davydov splitting. Increasing X-ray irradiation dose influences the optical properties of TPP films. All absorption bands show a continuous blue shift in position and a decrease in intensity with increasing X-ray dose. At 2.5 kGy the B, N, and M bands disappeared. The reduction in the absorbency was calculated as a function of X-ray dose. The energy gap was determined and the type of optical transition was found to be an indirect allowed transition.     

UV–visible,infrared absorption spectra of undoped and TiO2-doped lead phosphate glasses and the effect of gamma irradiation

Undoped and TiO₂-doped lead phosphate glasses were prepared. Ultraviolet (UV)–visible and Fourier transform-infrared (IR) absorption spectra of the prepared samples were measured before and after being subjected to doses of 30 and 60 kGy of gamma irradiation. The parent undoped lead phosphate glass reveals charge transfer UV absorption bands which are attributed to the presence of unavoidable iron impurities contaminated within the raw materials used for the preparation of the glasses and the sharing of divalent lead (Pb²⁺) ions. Experimental spectral data indicate that the doped titanium ions are involved in such glasses in two valences, namely the trivalent and tetravalent states. The predominant trivalent titanium (Ti³⁺) ions are characterized by its purple color and exhibiting two visible absorption bands at about 500–550 and 700–720 nm. The lesser tetravalent titanium (Ti⁴⁺) ions belong to the d⁰ configuration and generally exhibit only an UV absorption band. Spectral data show that gamma irradiation causes noticeable changes in the undoped and TiO₂-doped samples in the UV range while the effects are limited in the visible range. The observed changes in the UV region are attributed to photochemical reactions while TiO₂-doped samples show retardation or shielding toward continuous gamma irradiation together with the sharing of heavy Pb²⁺ ions. IR absorption spectra reveal the vibrations of several phosphate groups including the metaphosphate chains as the main structural building units together with the possible Pb?O vibrations.     

Model studies of the structure and optical properties of the TiO2(110) surface with an adsorbed Ag atom

ABSTRACT

The present studies of the atomic Ag adsorbate on the substrate TiO₂(110) explore the importance of dispersion (or van der Waals) energies for determining the structure of the adsorbed Ag atom, using density functional theory (DFT) supplemented by a dispersion energy treatment, within the PBE-D3 treatment. It is also of interest to explore electronic excitation by light absorption. Electronic density of states (EDOS) are obtained without and with Ag adsorbed on the TiO₂(110), to find the extent of change on the density of valence, conduction and intraband states. This is done using the hybrid HSE06 functional, which is known to provide good values for the energy band gap of the substrate. A computationally efficient PBE?+?BG procedure for these structures, which corrects the PBE band gap, is implemented to generate accurate EDOSs and light absorption intensities versus photon energies. This is followed by a reduced density matrix treatment of the dissipative dynamics of light absorption, generating state-to-state oscillator strengths and photoabsorbances for the pure and nanostructured TiO₂(110) surfaces. Adsorption of Ag leads to a noticeable increase in light absorption at visible wavelengths, and very large increases in the UV region of the spectrum.     

Abnormal phenomenon of source-drain current of AlGaN/GaN heterostructure device under UV/visible light irradiation

We report an abnormal phenomenon that the source-drain current (I_D) of AlGaN/GaN heterostructure devices decreases under visible light irradiation. When the incident light wavelength is 390 nm, the photon energy is less than the band gaps of GaN and AlGaN whereas it can causes an increase of I_D. Based on the UV light irradiation, a decrease of I_D can still be observed when turning on the visible light. We speculate that this abnormal phenomenon is related to the surface barrier height, the unionized donor-like surface states below the surface Fermi level and the ionized donor-like surface states above the surface Fermi level. For visible light, its photon energy is less than the surface barrier height of the AlGaN layer. The electrons bound in the donor-like surface states below the Fermi level are excited and trapped by the ionized donor-like surface states between the Fermi level and the conduction band of AlGaN. The electrons trapped in ionized donor-like surface states show a long relaxation time, and the newly ionized donor-like surface states below the surface Fermi level are filled with electrons from the two-dimensional electron gas (2DEG) channel at AlGaN/GaN interface, which causes the decrease of I_D. For the UV light, when its photon energy is larger than the surface barrier height of the AlGaN layer, electrons in the donor-like surface states below the Fermi level are excited to the conduction band and then drift into the 2DEG channel quickly, which cause the increase of I_D.