Depletion Layer Width Research Articles

Heterostructure Device Based on Graphene Oxide/TiO2/n-Si for Optoelectronic Applications

We produced a graphene oxide with good conductivity by a novel method that saves cost and time as illustrated in the structure Au/GO/TiO2/Si/Al. The GO was synthesized by burning polyvinyl alcohol at 300 °C on the TiO2/n-Si surface producing a conductive graphene oxide that is considered a new advantage of this technique. The Au/GO/TiO2/n-Si/Al structure is manufactured using the spin coating process. The XRD and SEM identified the samples’ structure and surface topography. In a frequency range from 10 kHz to 20 MHz, the electrical and dielectric parameters of the synthetic Schottky diodes were obtained from capacitance/conductance-voltage. The diagram of real and imaginary parts of the impedance (Z′, Z″), col-col, and their variation with temperatures, voltage, and frequency were also discussed. A comparison of electrical parameters such as ideality factor (n), series resistance (Rs), barrier height (Φb) based on traditional, Cheung, and Norde methods was investigated. The oxide layer thickness values (dox), the density distribution (Nss), the maximum admittance (Ym), the maximum electric field (Em), the depletion layer width (Wd), and ΔΦb (eV) were investigated using the C2 − V relationship. As the frequency increases, the Φb(C−V) increases, while the concentration of donor atoms (ND) decreases. The surface states (Nss) voltage-dependent profile was calculated and evaluated.

Performance evaluation of a new 30 μm thick GaAs x-ray detector grown by MBE

A circular mesa (400 μm diameter) GaAs p+-i-n+ photodiode with a 30 μm thick i layer was characterized for its performance as a detector in photon counting x-ray spectroscopy at 20 °C. The detector was fabricated from material grown by molecular beam epitaxy (MBE). An earlier MBE-grown detector fabricated using a different fabrication process and material from a different area of the same epiwafer was shown to suffer from: relatively high leakage current at high temperatures; a high effective carrier concentration that limited its depletion layer width; and material imperfections (butterfly defects) [Lioliou et al 2019 Nucl. Instrum. Methods Phys. Res. A 946 162670]. However, the new detector has better performance (lower leakage current and effective carrier concentration within the i layer). Using the new detector and low noise readout electronics, an energy resolution of 750 eV ± 20 eV Full Width at Half Maximum (FWHM) at 5.9 keV was achieved at 20 °C, equal to that reported for high quality GaAs detectors made from high quality material grown by metalorganic vapour phase epitaxy [Lioliou et al 2017 J. Appl. Phys. 122 244506]. The results highlight the substantially different performances of detectors made from the same epiwafer when the wafer qualities are not uniform and the effects of different fabrication processes.

Electrical characterization of Au/n-Si (MS) diode with and without graphene-polyvinylpyrrolidone (Gr-PVP) interface layer

In this research, for determining the effects of the (Gr-PVP) interfacial layer, two types of diodes (Au/n-Si and Au/(Gr-PVP)/n-Si) were performed on the same n-Si wafer with the same ohmic and rectifier contacts. Graphene-doped PVP nanocomposite film was grown on the n-Si wafer by a spin-coating method. Therefore, the basic electrical parameters of them were extracted from the I–V and Z-V-f characteristics and compared in detail. The higher values of n and lower values of BH obtained from Cheung’s functions compared to TE theory were ascribed to their voltage-dependent. The frequency-dependent diffusion potential (VD), doping-donor atoms (ND), depletion layer width (WD), surface potential (Ψs), Rs, and BH values of the MPS diode were also extracted from the impedance characteristics in the frequency range of 10–103 kHz.

A sandwich-structured surface plasmon ultraviolet photodetector based on ZnO thin film

In this article, novel sandwich-structured surface plasmon ultraviolet (UV) photodetectors based on ZnO thin films with engineered rear metal electrode were fabricated by radio-frequency magnetron sputtering. An exhaustive study about the impact of a dissimilar metallic layer (Au and Pt) on the structural, optical, and electrical properties of the device was carried out. The carrier collection property of the sandwich structure devices has the advantages of horizontal and vertical joint collection. In theory, adding a new metal semiconductor layer introduces a contact area and increases the resistance. An ultra-low dark noise current of less than 2.0 × 10–7 A and a responsivity exceeding 1.6 A/W were achieved with the prepared ZnO-based UV-PDs in the rear metallic electrode mode. The devices based on the ZnO/Pt/ZnO and MgZnO/Pt/MgZnO sandwich structures show high responsivity and fast response. This study provides a depletion layer width method for the fabrication of high-response UV photodetectors for surface plasmon-based materials by integrating metal semiconductor nanostructures. A homogeneous two-layer UV photodetector is constructed, which changes the traditional single-layer device structure and overcomes drawbacks of the single device structure.

Modification of barrier height and depletion layer width of methyl red (MR) dye-based organic device in the presence of single-walled carbon nanotubes (SWCNT)

In this paper, barrier height ( $$\phi_{{\text{b}}}$$ ) and depletion layer width (Wd) of ITO-coated glass/Methyl Red (MR) dye/Aluminum (Al)-based organic device have been studied, and effect of single-walled carbon nanotubes (SWCNT) on both of these parameters has been observed. ITO-coated glass as front electrode and Aluminum as back electrode are used to form the device by using spin coating technique. $$\phi_{{\text{b}}}$$ is calculated by analyzing both I–V and C–V characteristics. In the presence of SWCNT, $$\phi_{{\text{b }}}$$ is reduced from 0.870 ± 0.05 eV to 0.754 ± 0.05 eV in I–V characteristics and from 0.850 ± 0.12 eV to 0.784 ± 0.12 eV in C–V characteristics. $$\phi_{{\text{b }}}$$ is also estimated by Norde method, which shows the presence of SWCNT lowers the value of $$\phi_{{\text{b }}}$$ from 0.852 eV to 0.738 eV. Wd has been calculated from C–V characteristics. With SWCNT, value of Wd reduces from (8.74 ± 0.02) × 10−6 cm to (7.85 ± 0.02) × 10−6 cm. Threshold voltage also decreases from 2.52 V to 1.99 V in the presence of SWCNT. Addition of SWCNT within device ameliorates charge injection by lessening $$\phi_{{\text{b}}}$$ and Wd of the device.

Underlayer Selection to Improve the Performance of Polycrystalline Ge Thin Film Transistors

1. Introduction To improve the performance of Ge-thin film transistors (TFTs), it is essential not only to enhance the crystallinity of poly-Ge but also comprehensively study the relationship between its electrical properties and TFT characteristics. We recently advanced conventional solid-phase crystallization (SPC) method, significantly enlarged the grain size of poly-Ge and recorded the highest Hall effect hole mobility (μ Hall) of 620 cm2/Vs [1,2]. We fabricate poly-Ge TFTs using SPC-Ge and discuss the relationship between the film properties and TFT characteristics [3]. In the present study, we discuss the Ge thickness effects on the poly-Ge TFTs. To further improve the TFT performance, we enhanced the Ge crystallinity at thin film region (< 100 nm) by inserting Al2O3 underlayer. 2. Experimental Procedure The a-Ge layers were deposited on SiO2 glass substrates by vacuum deposition while heating at 125 °C. The initial film thickness of the a-Ge layer (t i) ranged from 25 to 200 nm. The samples were also prepared in which the insulating underlayer (Al2O3, GeO2) was sputtered at 10-50 nm for Ge with t i = 50-300 nm. The samples were then loaded into a conventional tube furnace in an N2 atmosphere annealed at 450 °C for 5 h to induce SPC.We fabricated accumulation-mode metal source/drain (S/D) p-channel TFTs using SPC-Ge. Figure 1 shows the process and structure. Pt and TiN were sequentially formed as a metal S/D and a capping layer, respectively. We used Al/SiO2/Al2O3/SiO2/GeO2 for the gate stack. The channel width and length (W/L) were 55 and 10 μm, respectively. All process including SPC were conducted below 450 °C. 3. Results and Discussion Figures 2(a)‒2(e) show the grain size dramatically varies with t i. All samples showed p-type conduction because the defects in Ge provides shallow acceptor levels that generate holes at room temperature. Therefore, larger grain sizes provide lower hole concentration p, as shown in Figs. 2(f) and 2(g). Figure 2(g) also shows that μ Hall peaks at t i = 200 nm, whereas the grain size peaks at t i = 100 nm. This behavior is likely attributed to the carrier scattering near the Ge/SiO2 interface [2].Figure 2(h) shows that on-current I on increases with increasing t i, which reflects μ Hall. Off-current I off is determined by the relationship between t i and the maximum depletion layer width (d max), which can be estimated from p. From the relationship between d max and t i, we found that the lower t i provides the higher occupation of the depletion layer in the whole SPC-Ge layer, which decreases I off. Reflecting I on, I off, and the on/off current ratio I on/I off reaches the maximum at t i = 50 nm. Figure 2(i) shows that field-effect mobility (μ FE) is consistent with the trend of μ Hall, while μ FE is much lower than μ Hall. This is likely because not only carrier scattering at the MOS interface, but also large I off causes underestimation of transconductance and μ FE.We thinned the t i = 100 nm sample to 55 nm using chemical-mechanical polishing. The film keeps low p enough to get full-depleted, and was processed into TFT as before. Figures 3(a) and 3(b) show the typical p-channel transistor operation, high I on/I off (102) and μ FE (170 cm2/Vs) because of both the high I on due to the high μ Hall and low I off. Therefore, to improve the TFT performance, a Ge layer compatible with high μ Hall and a thin film is desirable.Because the nucleation in a thin film occurs at the substrate interface, we modulated the interface by preparing Al2O3 and GeO2 underlayers. Figures 4(a)‒4(f) show the grain size is almost doubled by inserting underlayers for both t i = 50 nm and 300 nm, while the t i = 50 nm Ge layer with GeO2 did not crystallize completely due to the slow growth rate. Compared to the samples without underalyers, Fig. 4(g) shows the underlayers reduce p reflecting the large grain size. Figures 4(h) shows the GeO2 underlayer provides high μ Hall for t i = 300 nm, while low μ Hall for t i < 300 nm. This behavior is likely due to the carrier scattering near the Ge/GeO2 interface. Conversely, the Al2O3 underlayer provides high μ Hall for t i < 300 nm. In particular, the t i = 50 nm Ge layer exhibits relatively low p and high μ Hall. These results suggest that the Al2O3 underlayer has the potential to further improve the performance of poly-Ge TFTs.

Enhancing the Diode Characteristics of Pulsed Laser–Deposited n‐MgxZn1−xO/p‐Si Heterojunction: Role of Oxygen Ambient Pressure

Herein, diode characteristics of n‐MgxZn1−xO/p‐Si heterojunctions grown by pulsed laser deposition at different oxygen ambient pressures are investigated. It is found that the heterojunctions grown at lower oxygen growth pressure of 1.0 × 10−2 mbar and below do not show rectifying diode‐like behavior, whereas those grown at higher oxygen pressures at and above 2.5 × 10−2 mbar exhibit perfect diode‐like rectifying characteristics. The diode characteristics are found to improve significantly with increasing oxygen ambient pressure during the growth of MgxZn1−xO film. The current–voltage measurements show that the n‐MgxZn1−xO/p‐Si heterojunction diode grown at a higher oxygen ambient pressure of ≈1.0 × 10−1 mbar has the lowest reverse saturation current of ≈19 nA and highest rectification ratio of ≈1.4 × 104. The capacitance–voltage measurements reveal that the depletion layer width of heterojunction diodes increases manifold with increasing oxygen ambient pressure during the growth of MgxZn1−xO, which is understood in terms of decrease in carrier concentrations in the MgxZn1−xO thin films grown at higher oxygen ambient pressures. The n‐MgxZn1−xO/p‐Si heterojunction diodes, grown at high oxygen ambient pressures, with low reverse saturation current, high rectification ratio, and large depletion width may have potential application in wide‐bandgap nanoelectronic devices and UV enhanced photodetectors.

Size effects of tin oxide quantum dot gas sensors: from partial depletion to volume depletion

The grain size effect is one of the fundamental characteristics of semiconductor gas sensors. However, it has not been fully understood due to the absence of studies on the volume-depleted grains. In this work, the gas-sensitive SnO2 quantum dots (QDs) from partial depletion to volume depletion are prepared to discuss the size effects. A facile aqueous-based method is used to prepare the size-controllable SnO2 QDs of 2.0–12.6 nm. The resistance shows a monotonically negative size effect while the response reaches the optimization when the grain radius is comparable to the depletion layer width. It is suggested that the design of highly sensitive gas sensors should consider the equal importance of the control of grain size and depletion layer width. The computational results illustrate size-dependent energy level of donors and number of quasi-free electrons, which are responsible for the negative size effect of resistivity in the volume-depleted SnO2 crystallites. This work provides a comprehensive understanding of grain size effects from partial depletion to volume depletion in semiconductor gas sensors.

A Compare Study on Electrical Properties of MS Diodes with and Without CoFe2O4-PVP Interlayer

Cobalt ferrite (CoFe2O4) nanostructures in powder form were synthesized by an ultrasound assisted method. The crystalline structure of it was determined by XRD method. The prepared powder was mixed with an aqueous polyvinylpyrrolidone (PVP) solution to utilize as an interfacial thin film. The prepared CoFe2O4-PVP solution was deposited on the n-Si wafer utilizing electrospinning method. Electrical characteristics of the Au/n-Si (MS) and Au/(CoFe2O4-PVP)/n-Si (MPS) diodes were investigated using current and admittance (Y = G + iωC) measurements. Electrical parameters like ideality factor (n), barrier height (ΦB), and series resistance (Rs) of them were extracted from I–V measurements. The Ln(IF)-(VF) plots were drawn to determine the current conduction mechanisms (CCMs). Besides, the other diode parameters including diffusion potential, concentration of donor atoms, depletion layer width, barrier height and Fermi-energy were extracted from C−2–V characteristic. As a result, the electrical parameters of these diodes were compared with each other, and the obtained results confirm that the polymer interlayer between M and S is more affective on electrical performance of the diode.

Phase-shifting electron holography for accurate measurement of potential distributions in organic and inorganic semiconductors.

Phase-shifting electron holography (PS-EH) is an interference transmission electron microscopy technique that accurately visualizes potential distributions in functional materials, such as semiconductors. In this paper, we briefly introduce the features of the PS-EH that overcome some of the issues facing the conventional EH based on Fourier transformation. Then, we present a high-precision PS-EH technique with multiple electron biprisms and a sample preparation technique using a cryo-focused-ion-beam, which are important techniques for the accurate phase measurement of semiconductors. We present several applications of PS-EH to demonstrate the potential in organic and inorganic semiconductors and then discuss the differences by comparing them with previous reports on the conventional EH. We show that in situ biasing PS-EH was able to observe not only electric potential distribution but also electric field and charge density at a GaAs p-n junction and clarify how local band structures, depletion layer widths and space charges changed depending on the biasing conditions. Moreover, the PS-EH clearly visualized the local potential distributions of two-dimensional electron gas layers formed at AlGaN/GaN interfaces with different Al compositions. We also report the results of our PS-EH application for organic electroluminescence multilayers and point out the significant potential changes in the layers. The proposed PS-EH enables more precise phase measurement compared to the conventional EH, and our findings introduced in this paper will contribute to the future research and development of high-performance semiconductor materials and devices.

Effects of Manganese on Highly Donor-Doped Barium Titanate Ceramics with Resistivity of Positive Temperature Coefficient

Highly donor-doped ceramics with composition of Ba0.984Y0.016TiO3 were prepared for thermistors with positive temperature coefficient of resistivity (PTCR) via a route of solid reaction, reducing sintering and aerial oxidation. The effects of Mn additive were investigated on the ceramic characteristics of composition, morphology and electrical properties. The Mn incorporation affected little on ceramic composition but resulted in an obvious change in ceramic morphology, which illustrated the average grain size of 1.16, 1.65 and 1.01 μm for Mn addition amount of 0, 0.0005 and 0.0010, respectively. The grain growth, together with the Mn additive, influenced the electrical properties of room temperature resistivity, PTCR jump, donor and acceptor densities as well as the depletion layer width.

A comparison study regarding Al/p-Si and Al/(carbon nanofiber–PVP)/p-Si diodes: current/impedance–voltage (I/Z–V) characteristics

Al/p-Si and Al/(carbon nanofiber–PVP)/p-Si diodes were produced using a p-type silicon wafer with 10 Ω cm resistivity to determine the polymer interlayer effects on device characteristics. To assess whether carbon nanofiber–PVP interlayer is beneficial for electrical performance, the current–voltage (I–V) and the impedance–voltage (Z–V) measurements were performed in wide range of voltage. Thus, electrical parameters such as series resistance, barrier height, and ideality factor were derived from the forward bias Ln (IF)–VF and Cheung’s functions, so that they are compared and voltage dependence of them is explored. Later, the values of intercept voltage, width of depletion layer, doping acceptor atom concentration, and barrier height were also extracted from C−2–V data at 1 MHz and then results were compared with each other. The surface states and their energy profile were also extracted from the IF–VF characteristics by considering barrier height (BH) and n is voltage dependent as well. Experimental results indicate that the carbon nanofiber–PVP interlayer decreases surface states (Nss), series resistance (Rs) and leakage current, whereas it increases rectifying ratio and shunt resistance. Hence, such polymeric interlayer material forms an interesting alternative to conventional oxide layer due to some advantages of polymers such as desirably low values of cost, weight, and energy consumption.

Electrical characteristics of Au/PVP/n-Si structures using admittance measurements between 1 and 500 kHz

In this study, Au/n-Si structures with PVP polymer interlayer were fabricated and characterized using capacitance/conductance–voltage–frequency (C/G–V–f) measurements. Obtained electrical parameters were found to be sensitive to frequency due to polymer interlayer, changes of traps/states (Dit/Nss) level, interfacial/dipole polarization. The dispersion in C and G in depletion region is due to Nss/polarization, while the dispersion in accumulation region is due to interlayer/series resistance (Rs). The voltage-dependent profiles of Nss and Rs were derived using the methods of low–high frequency capacitance/Hill-Coleman and Nicollian–Brews, respectively. The width of depletion layer (Wd) and barrier height (ΦB) values increase with increasing frequency almost linearly. On the other hand, Rs decreases with increasing frequency whereas the maximum electric field (Em) exhibits opposite behavior. The high frequency C/G–V plots were corrected to reveal the Rs effect on them. The experimental results indicate that the growth of PVP interlayer by spin coating at the Au/n-Si interface yields a preferable and suitable device compared to devices with conventional insulating interlayer due to some advantages of polymer interlayers such as low-cost/weight, flexibility, and easy grown processes.

Effect of La0.67Sr0.33 MnO3 Insertion Layer on the Ferroelectric and Resistive Switching Behaviors of PbZr0.52Ti0.48O3/Nb:SrTiO3 Heterostructures

Recently, ferroelectric resistive switching (RS) effect in the ferroelectric/semiconductor heterostructures has been widely studied and the RS performance has been greatly improved. However, the relationships between ferroelectric and RS behaviors as well as interface structure of ferroelectric/semiconductor heterostructures need to be further studied. Herein, a [Formula: see text][Formula: see text]MnO3 (LSMO) layer with the thickness of 7 nm is inserted into [Formula: see text][Formula: see text]O3/Nb:SrTiO3 (PZT/NSTO) heterostructures, and its effects on the ferroelectric and RS behaviors are investigated. The PZT/NSTO heterostructures show significantly asymmetric ferroelectric loops, and the RS ratio in which can reach to three orders of magnitude. However, by inserting the LSMO layer, the ferroelectric loops became relatively symmetric, but the RS effect almost disappeared. It can be considered that the LSMO layer affects the interfacial energy band structure of the PZT/NSTO heterostructures, which makes ferroelectric polarization lose its effect on the modulation of the depletion layer width. Therefore, the existence of the adjustable depletion layer is very important for the RS effect of ferroelectric/semiconductor heterostructures.

Random telegraph signals caused by a single dopant in a metal–oxide–semiconductor field effect transistor at low temperature

While the importance of atomic-scale features in silicon-based device for quantum application has been recognized and even the placement of a single atom is now feasible, the role of a dopant in the substrate has not attracted much attention in the context of quantum technology. In this paper, we report random telegraph signals (RTSs) originated from trapping and detrapping of an electron by a donor in the substrate of a p-type metal–oxide–semiconductor field-effect-transistor. RTSs, not seen when the substrate was grounded, were observed when a positive bias was applied to the substrate. The comprehensive study on the signals observed reveals that the nature of the RTSs is discrete threshold voltage variations due to the change in the depletion layer width depending on the charge state of a single dopant, neutral or positively charged.

Determination of frequency and voltage dependence of electrical properties of Al/(Er2O3/SiO2/n-Si)/Al MOS capacitor

In this study, we investigated the effects of applied voltage and frequencies on the electrical properties of Al/(Er2O3(150 nm)/SiO2(20 nm)/n-Si)/Al MOS capacitor. The e-beam deposited Er2O3/SiO2 films were annealed at 650 °C in N2 ambient and the crystal and phase identification of the films were confirmed by X-ray diffractometry. The capacitance–voltage (C–V) and the conductance–voltage (G/ω–V) measurements of the MOS capacitor were carried out for voltage frequencies from 50 kHz to 1 MHz at several steps. The parameters of doping concentration, diffusion potential, built-in potential, barrier height, Fermi energy level, the image force barrier lowering and the depletion layer width were calculated by C–V and G/ω–V data. While the depletion layer width decreased with increasing frequencies, the diffusion potential and the barrier height increased a little with small frequencies (200 kHz ≤ f) first, then decreased insignificantly. We also studied the frequency effects on the series resistance (Rs) and the interface state density (Dit) through the C–V and G/ω–V curves, and found noticeable decreases in Rs and Dit values with increasing frequency. The measured and calculated results reveal that both Rs and Dit frequency dependence have significant impacts on Er2O3/SiO2/n-Si MOS capacitor properties. These effects are basically because of the interfacial charge behavior of thin SiO2 layer contained in between n-Si and Er2O3.

Investigation of gamma-irradiation effects on electrical characteristics of Al/(ZnO–PVA)/p-Si Schottky diodes using capacitance and conductance measurements

In this study, Al/(ZnO–PVA)/p-Si (MPS type) Schottky diodes (SDs) were fabricated instead of metal–semiconductor (MS) type SDs with traditional insulator interfacial layer. Additionally, basic electrical parameters of these MPS-type SDs (such as doping acceptor atoms (NA), depletion layer width (WD), series resistance (Rs), barrier height (ΦB), and surface states/traps (Nss/Nit)) were found as a function of gamma-irradiation by using the capacitance/conductance–voltage (C/G–V) measurements. These measurements under 0–60 kGy radiation doses show that radiation-induced Nss are more effective in the depletion layer. On the other hand, voltage-dependent profiles of Rs and Nss were also obtained using Nicollian–Brews and Castagne–Vapaille methods, respectively. Additionally, the C/G–V characteristics were corrected before irradiation and after 60 kGy doses by considering the effects of Rs. These calculations show that Rs is more effective especially in the accumulation region and therefore, it must be considered in the calculations. All these results have indicated that MS-type SDs with (ZnO–PVA) polymer interfacial layer are very sensitive to gamma-irradiation. Hence, they can be successfully used as MPS-type detectors instead of MIS/MOS-type detectors. Hence, they can be successfully used as MPS-type detectors instead of MIS/MOS-type detectors, since polymer layers can be easily grown compared to insulator/oxide layers. Also, they are cheaper, lighter, more flexible, and require low energy consumption. In conclusion, it can be said that although all parameters were affected by gamma-irradiation, no significant defect/deterioration was observed in applied dose range which would hinder the operation of these MPS-type SDs.

Investigation of the electrical properties of diodes by crosschecking dependence on the presence of (nanocarbon-PVP) interface layer

The Al/p-Si (metal-semiconductor (MS)) and Al/nanocarbon-PVP/p-Si (metal-polymer-semiconductor) type Schottky barrier diodes (SBDs) were fabricated in same conditions to determine the existence of an increase in the performance of Al/p-Si diode and they were called as D1 and D2, respectively. For this purpose, the electrical properties of the diodes were investigated using the current–voltage and impedance–voltage measurements in wide bias voltage. The ideality factor, reverse-saturation current and zero-bias barrier height values were calculated from the linear part of the forward bias lnI–V plot as 6.23, 2.35 ✕ 10–8A, 0.68 eV for D1 and 2.86, 4.27 ✕ 10–9A, 0.73 eV for D2, respectively. It is seen from results that the value of rectifier rate for D2 is about 8 times higher than for D1. The values of barrier height, Fermi energy level, the number of doped acceptor atoms and depletion layer width were obtained. The values of series resistance and special density distribution of interface states’ values also considerably decrease using (nanocarbon Polyvinylpyrrolidone (PVP)) interlayer. All these results confirmed that the nanocarbon-PVP polymer interlayer leads to a seriously increase in the performance of the MS diodes and hence it can be successfully used as an insulator in view of low cost, grown by simple methods.

Interfacial Analysis of Anatase TiO2 in KOH Solution by Molecular Dynamics Simulations and Photoelectrochemical Experiments.

Hydrogen can be produced by photoelectrochemical (PEC) water splitting using a KOH solution as an electrolyte and TiO2 as a photoanode. In this work, we fabricated anatase TiO2 nanoring/nanotube arrays and TiO2 nanotube arrays using an anodic oxidation method, confirmed by field-emission scanning electron microscopy (FESEM) and X-ray diffractometry (XRD), and then conducted the photoelectrochemical experiments with 1 M KOH and Na2SO4 solutions. The bias voltage, small impedance, negative flat-band potential, large capacitance, and depletion layer width in the anatase TiO2–KOH system were observed, leading to the stable and large photocurrent density. To understand the effects of KOH on the interface properties of TiO2/H2O, the electric double layers of anatase TiO2(001), (100), (101)/KOH interfaces were further investigated by calculating the ion–surface interaction with molecular dynamics simulations. It is noted that the number density of potassium ions has the same trend as that of oxygen atoms due to the layering effect in liquids and the strongest ionic hydration of K+ on anatase (101) is observed by analyzing the radial distribution function and coordination number. In addition, the electrostatic characteristics along the TiO2/KOH interfaces were analyzed based on the Grahame double layer model. The potential drops in the outer Helmholtz layer of anatase (001), (100), and (101) surfaces are 1.08, 0.26, and 0.51 V, respectively. Compared with TiO2–H2O systems, the larger potential drops in the TiO2–KOH system explain the phenomenon that KOH solute contributes substantially to a chemical bias in PEC reactions. At the same time, we estimated the depletion layer widths of anatase TiO2(001), (100), and (101) surfaces as 37.48, 173.25, and 64.49 Å, respectively, which are of similar magnitude to the experimental results. Anatase TiO2(100) with the widest depletion layer is suggested in photocatalysis. These works provide a clear understanding of interfacial behavior of KOH on anatase TiO2 from a microscale, which can be used to explain the promotion effect of the KOH electrolyte and guide the design of TiO2 nanocrystals in the PEC system.

Improvement of surge current performances of ZnO varistor ceramics via C3N4-doping

ZnO-Bi2O3 based varistor ceramics doped with C3N4 were fabricated via solid state method. Experimental results show that C3N4 additive acts as an inhibitor in ZnO grain growth, and the average grain size decreases from 10.2–7.1 μm. The varistor breakdown voltage gradient increases from 222.3–282.3 V/mm, and the nonlinear coefficient increases from 51.9–58.2 with the increase of C3N4 content from 0 to 3.0 wt%. The C3N4-added samples exhibited smaller residual voltage ratio and better surge current withstanding capability. It is proposed that the C3N4-doping leads to substitution of nitrogen for oxygen in the grain boundary region, forming acceptor type defects. The acceptor type defects act as electron traps, increasing the barrier height from 1.31 to 1.50 eV and the depletion layer width from 54.9–61.8 nm, which increases the nonlinearity, and the surge current performances of the C3N4 doped ZnO varistor ceramics are improved.