Indium Tin Oxide Glass Substrate Research Articles

Reflectance-tunable terahertz polarization reflector using indium tin oxide

Indium tin oxide (ITO) is a transparent conductive material that is widely used in optical display applications and terahertz (THz) devices. This paper proposes an ITO-based THz polarization reflector. The proposed reflector is based on the wire-grid ITO pattern and glass substrate, with tunable THz reflectance, high optical transparency, and excellent stability. The performance of the proposed reflector is demonstrated and validated through experiments using a CW THz system and a UV–Vis spectrometer. The experimental results are in good agreement with the numerical simulation. The proposed reflector has a tunable THz reflectance from 0.5 to 0.97 in the THz frequency range (0.22–0.5 THz) and a high optical transmittance of approximately 60% in the wavelength range 450–800 nm. The proposed device successfully optimizes the radiation path in THz and optical hybrid systems to significantly improve the system performance. The work presented in this paper provides a new method for designing THz devices based on transparent conductive materials.

Reflective blue phase liquid crystal display with triangular dielectric layer

ABSTRACT We propose a reflective blue-phase liquid-crystal display (LCD) with triangular dielectric layers and a diffuse reflector electrode. The triangular dielectric layers with a high dielectric coefficient on the top and bottom indium tin oxide glass substrates are equivalent to the conductive plates, forming a corrugated electrode structure. This type of reflective blue-phase LCD based on planar electrode and diffuse mirror electrode can offer relatively high reflectance (~74.5%) and low operation voltage (9.2 Vrms) compared to most other devices due to its fairly strong and uniform horizontal electric field component along the whole blue-phase liquid crystal bulk. This design has the advantages of fast response time, easy manufacturing process, a high resolution and full-colour capability. It is a promising future high-quality reflective full-colour microdisplay.

Electrochromic Properties of Electrospun Fibers Based on Bis‐Thiomethylcyclohexanone Derivatives

AbstractIn this work, the electrochromic (EC) application of the hybrid fibers based on bis‐thiomethylcyclohexanone derivatives is evaluated. For this purpose, two new bis‐thiomethylcyclohexanone derivatives, 2,6‐bis(phenyl(phenylthio)methyl)cyclohexanone (PPTMC) and 2,6‐bis((2,6‐dichlorophenyl)(phenylthio)methyl)cyclohexanone (CPPTMC), were synthesized by thio‐Michael addition and characterized by spectroscopic methods and X‐ray diffraction. The hybrid fibers based on bis‐thiomethylcyclohexanone and poly(methyl methacrylate) (PMMA) were successfully prepared with electrospinning. The surface morphology and elemental compositions of these hybrid fibers were investigated by scanning electron microscopy (SEM) and energy dispersive X‐ray spectroscopy (EDS). The electrochemical, optical and electrochromic behaviors of indium tin oxide (ITO) glass substrates coated with those fibers were evaluated using spectrophotometry techniques. Moreover, the electrochromic devices (ECDs) based on PPTMC‐PMMA and CPPTMC‐PMMA hybrid fibers showed reversible color change from the transparent state to light brown by switching from +3.0 to −3.0 V. The calculated coloration efficiency of the hybrid fibers based on PPTMC‐PMMA was found to be 207.27 cm2/C whereas a higher coloration efficiency was obtained for the hybrid fibers based on CPPTMC‐PMMA (273.31 cm2/C). Our results show that hybrid fibers based on PPTMC‐PMMA and CPPTMC‐PMMA are potential materials for optical and electrochromic applications.

Analysis of Indium and Tin in Different Scrap Liquid Crystal Display Glass by Heavy Metal Digestion Method

Disposing of liquid crystal display (LCD) waste has significant effects on the environment, human and animal health, and metal resources by extension if inappropriately treated. In this study, we have developed a process for the separation of indium–tin oxide (ITO) glass from the LCD panel and evaluated the best digestion process for the analysis of In and Sn from ITO glass. The digestion process of scrap LCD in this work involves the separation of the polarizing film from ITO glass by environmentally friendly cold thermal shock method with liquid nitrogen, the removal of liquid crystals between the ITO glass substrates by ultrasonic cleaning, and the analysis of In and Sn from ITO glass by acid digestion method with a suitable reagent. Various brands of scrap LCDs were treated with six different digestion methods to determine In and Sn concentrations. The result of this study indicates that aqua-regia digestion procedure was the best method for the analysis of In and Sn. The concentrations of In and Sn in various brands of LCDs were in the range of 233–332 mg/kg and 43–421.5 mg/kg, respectively. Further, the analysis of In and Sn metals at different locations of the same scrap LCD was also carried out and it was observed that the concentrations of these metals (In—0.0278–0.0369% and Sn—0.0033–0.0078%) were significantly similar, with slight variations in their percentages.

Additive-Free Electrophoretic Deposition of Graphene Quantum Dots Thin Films.

The electrophoretic deposition (EPD) of graphene-based materials on transparent substrates is highly potential for many applications. Several factors can determine the yield of the EPD process, such as applied voltage, deposition time and particularly the presence of dispersion additives (stabilisers) in the suspension solution. This study presents an additive-free EPD of graphene quantum dot (GQD) thin films on an indium tin oxide (ITO) glass substrate and studies the deposition mechanism with the variation of the applied voltage (10-50 V) and deposition time (5-25 min). It is found that due to the small size (≈3.9 nm) and high content of deprotonated carboxylic groups, the GQDs form a stable dispersion (zeta-potential of about -35 mV) without using additives. The GQD thin films can be deposited onto ITO with optimal surface morphology at 30 V in 5 min (surface roughness of approximately (3.1±1.3) nm). In addition, as-fabricated GQD thin films also possess some interesting physico-optical properties, such as a double-peak photoluminescence at about λ=417 and 439 nm, with approximately 98 % visible transmittance. This low-cost and eco-friendly GQD thin film is a promising material for various applications, for example, transparent conductors, supercapacitors and heat conductive films in smart windows.

Titanium oxide hollow structure layer for dye sensitized solar cell by liquid phase deposition

In this study, polystyrene (PS) microspheres templates having different coating densities were prepared by drop casting PS microspheres with the diameter of 800 nm on indium tin oxide (ITO) glass substrate. TiO2 film was deposited on the PS microsphere template via liquid phase deposition (LPD) using a solution of ammonium hexafluoro-titanate [(NH4)2TiF6] and boric acid (H3BO3). A LPD-TiO2 hollow layer was prepared by removing PS microspheres via high-temperature sintering; this hollow layer acts as a barrier between the ITO and electrolyte interface in the working electrode structure of a dye-sensitized solar cell (DSSC). Because hollow layer has a large specific surface area, it increases dye adsorption and acts as a barrier layer to inhibit direct contact between ITO and electrolyte interface. Thus, the charge recombination rate between ITO and electrolyte interface is reduced and the electron transmission efficiency between the ITO and the working electrode is improved. Hollow layer (0.1 wt% PS, 50 nm) in the DSSC exhibited the optimum short-circuit current density (Jsc) of 12.75 mA/cm2, open-circuit voltage (Voc) of 0.71 V, fill factor of 62.19%, and photoelectric conversion efficiency (η) of 5.67%.

Thin Film of Perovskite (Mixed-Cation of Lead Bromide FA1−xMAxPbBr) Obtained by One-Step Method

Perovskite materials for solar cell applications were prepared by a one-step method. In the following work, the spin coating technique was used for organic–inorganic hybrid perovskite formamidinium lead tribromide (FAPbBr3), methylammonium lead tribromide (MAPbBr3) and formamidinium methylammonium lead tribromide (FA1−xMAxPbBr3).Thin films of mixed FA1−xMAxPbBr3 (x = 0–1) perovskites deposited on indium tin oxide glass substrates were obtained by mixing FAPbBr3 and MAPbBr3 in different proportions. Structural x-ray diffraction (XRD), morphological (Scanning Electron Microscopy (SEM) and energy dispersive x-ray spectroscopy (EDX) and optical (uv–visible spectroscopy (UV–Vis) proprieties were investigated for all synthesized perovskites as a function of the MA/FA ratio. The (XRD) analysis shows the formation of a cubic-phase perovskite with space group Pm-3 m in the composition range 0 ≤ x ≤ 1. High absorbance levels were obtained in the infrared region 500-900 nm for mixed perovskites FAMAPbBr3. The estimated energy band-gap from the absorbance spectral measurements for FAMAPbBr3 thin films was in the range of 2.2 eV for FAPbBr3 and 2.3 eV for MAPbBr3, respectively. The photoluminescence emission of mixed FA/MA perovskite thin films was located in intermediate values between 580 nm and 555 nm.

Electrochemical Hydrogen Gas Sensing Employing Palladium Oxide/Reduced Graphene Oxide (PdO-rGO) Nanocomposites

This research work aims at proposing cheap, facile, sensitive, and selective assembly of three electrode electrochemical hydrogen (H2) gas sensor which operates on room temperature in ambient conditions. Palladium oxide-reduced graphene oxide (PdO-rGO) nanocomposite have been synthesized using insitu chemical sol-gel method and modified Hummer’s method. The phase, structure, particle size, and bonding information have been obtained using X-ray diffraction (XRD) analysis, transmission electron microscopy (TEM), Fourier Transform Infrared (FTIR) spectroscopy, and Ultraviolet-Visible (UV-Vis) absorption spectroscopy. Palladium oxide (PdO) nanoparticles of size ranging from 30 to 35 nm have been successfully attached with uniform 2D network of reduced graphene oxide (rGO) sheets which offers a large surface area for H2 adsorption. The thin film of nanocomposite have been fabricated on conducting Indium tin oxide (ITO) glass substrates using electrophoretic deposition (EPD) process and is employed as working electrode (WE) in indigenously developed three-electrode cell. Thin film surface morphology have been observed using Scanning Electron Microscopy (SEM) and it shows agglomerates of PdO nanoparticles with multiple randomly stacked rGO nanosheets uniformly spread across the surface of the film. The amperometric response of the assembled electrochemical sensor has been recorded for the detection of 10 to 80 percent concentration of hydrogen gas using potentiostat/galvanostat autolab. The sensitivity of the sensor is found out to be $0.462~ \mu \text{A}$ /% H2 concentration and sensing calibration curve shows a uniform linear response. The stability and selectivity of the sensor has been enhanced using H2 insensitive reference electrode (RE) and solid polymer electrolyte gas permeable membrane, respectively, which will aid new dimensions in designing robust H2 sensor at room temperature.

Review of various measurement methodologies of migration ion influence on LCD image quality and new measurement proposal beyond LCD materials

AbstractNowadays, thin‐film transistor liquid crystal displays (TFT‐LCDs) have realized high reliability of display characteristics by improving liquid crystal (LC) materials and cell fabrication processes. In order to improve display reliability, measurement methodologies are important to see the progress of improvement of materials and processes; thus, our group has proposed voltage holding ratio (VHR), ion impurity, residual direct current (DC) and elastic constants for LC cells, and the optical anisotropy of an alignment layer on indium tin oxide (ITO) glass substrate for LCD industry. In case of an ion impurity, we have succeeded in measuring the ion impurity amount in TFT‐LCD. Furthermore, we have recently proposed ion impurity measurement methodology for beyond LCD applications that are organic light emitting diode (OLED) and organic photovoltaics (OPV).In this review, I introduce each measurement methodology for LCDs and beyond LCDs in detail.

Investigation of mode interconversion for interfacial pattern formation through plasma–surface interaction

AbstractThe appropriate understanding of the plasma–surface interaction is crucial in optimizing the atmospheric pressure plasma jet (APPJ) to suit a particular application. In this study, we mainly focus on the behavior of mode interconversion for interfacial patterns regarding APPJ interacting with a indium tin oxide (ITO) glass substrate. By regulating the pulse voltage, annular interfacial pattern formation on ITO surface displays two types of modes, that is, the diffuse pattern and the streamer pattern. Furthermore, these two modes are not independent and are transformed into each other by introducing additive N2 and O2. The reason is mainly attributed to the difference of the N2+(B)/O(3p) ratio and local electric field distribution. This information on the operation mode and interconversion between them provides deep insights into the nature of the physicochemistry during plasma–surface interaction processes.

Analysis of Defects and Surface Roughness on the Hydrogenated Amorphous Silicon (a-Si:H) Intrinsic Thin Film for Solar Cells

Effect of defect - through observation of energy absorption Urbach, on deposition rate, energy band gap, and surface roughness of intrinsic thin film are investigated using Radio Frequency Plasma Enhance Chemical Vapor Deposition (RF-PECVD). Films are grown on ITO (Indium Tin Oxide) glass substrate. Analysis of energy band gap is conducted to determine changes in the structure of a thin film of a-Si:H. Energy band gap is important to determine the portion of the spectrum of sunlight that is absorbed solar cells. From the characterization using UV-Vis spectrometer and the Tauc’s plot method, the width of the resulting energy band gap is greater if the hydrogen dilution is increased. It can be shown that the increase of the hydrogen dilution, will increase the energy band gap, and the surface roughness of thin layers. Instead, the improvement of the hydrogen dilution decrease the rate of deposition and Urbach energy. It is estimated that with greater hydrogen dilution, an intrinsic thin film of a-Si:H is more conductive for more reduction in residual of band tail defects or dangling bond defects.

ZnO nanorod arrays modified with Bi2S3 nanoparticles as cathode for efficient polymer solar cells

Abstract The surface modification of zinc oxide nanorod arrays (ZnO NRAs) is an effective way to improve electrical coupling between ZnO NRAs and organic active layer, and can decrease the surface defects of ZnO NRAs. In this work, ZnO NRAs grown on indium tin oxide (ITO) glass substrates are decorated with bismuth trisulphide (Bi2S3) nanoparticles using successive ionic layer adsorption and reaction (SILAR) at room temperature. The resulted ZnO/Bi2S3 core-shell NRAs are characterized by using different measurement techniques. SEM and TEM images confirm the homogeneous coverage of Bi2S3 nanoparticles on the surface of ZnO NRAs. XPS and PL spectra demonstrate that surface defects of ZnO NRAs modified with 0.2 mM Bi2S3 nanoparticles are effectively reduced. XRD spectra show the modification of the ZnO NRAs surface with Bi2S3 can enhances the crystallinity of the active layer and ZnO NRAs, which will improve the absorption of sunlight, and help for the charge transfer in solar cells. Finally, hybrid solar cells with the structure of ITO/ZnO/Bi2S3/P3HT:PC71BM (or PTB7:PC71BM)/MoO3/Ag are for the first time fabricated. The solar cells based on the ZnO/0.2 mM Bi2S3 core-shell NRAs with P3HT:PC71BM as active layer exhibit the nice performance with Jsc, Voc, FF and η values equal to 9.51 ± 0.09 mA/cm2, 0.61 ± 0.01 V, 61.6 ± 0.6%, and 3.57 ± 0.05%, respectively. Besides, the PCE of the device based on the ZnO/0.2 mM Bi2S3 core-shell NRAs with PTB7:PC71BM is improved to 6.35% from 4.88% of the reference device without Bi2S3 coated. Increase of electrical coupling between ZnO NRAs and organic active layer and decline of the surface defects of ZnO NRAs lead to the performance improvement of devices with ZnO/Bi2S3 core-shell NRAs, which implies that ZnO/Bi2S3 core-shell NRAs made by SILAR method are promising electron transport materials in solar cells.

Turbulence Imaging Simulation Based on Electrically Tunable Polymer Dispersed Liquid Crystals Cell

In this study, the scattering properties of polymer dispersed liquid crystals (PDLC) and its optical features for use in turbulence image simulation are presented. A PDLC cell composed of a liquid crystal/monomer mixture with two indium tin oxide glass substrates, 55 wt.% E7 and 45 wt.% NOA65, is proposed. And this mixture had a thickness of 10 µm. With respect to its scattering properties, it was hypothesized that the proposed PDLC cell could be utilized as an electrically tunable turbulence imaging simulator. The measured results, two dimensional images of the transmission light, under voltages from 0 Vrms to 10 Vrms showed that the PDLC film could effectively simulate turbulence situation of a point light source under atmosphere turbulence condition to a certain extent. This PDLC film had a great potential for application in turbulence imaging simulation.

Ideal microlens array based on polystyrene microspheres for light extraction in organic light-emitting diodes

Abstract Ideal microlens array (IMLA) based on polystyrene (PS) microspheres with small diameters has been introduced to the surface of indium tin-oxide (ITO) glass substrates to enhance the out-coupling efficiency of organic light-emitting diode (OLED) devices. IMLA was fabricated by a replica molding process using annealed closely packed PS spheres as the template. IMLA is used to extract the waveguide mode which is limited in glass substrate. Experiment results show that the best performance of OLED devices is achieved when the diameter of IMLA is about 6 μm. The enhancement of current efficiency, power efficiency and EQE of green-emitting OLED devices with IMLA with a diameter of 6 μm is 56.4%, 63.5% and 58.8%, respectively, relative to devices without any light out-coupling structures in the forward direction. In addition, we also demonstrate that the IMLA with a diameter of 6 μm can also be applied for the extraction of red, blue and white light. Furthermore, the use of IMLA is not detrimental to the electrical and optical performance of the OLED devices.

Design and synthesis of host materials based on spirofluorene and s-triazine moieties and the applications in organic light-emitting devices

Organic light-emitting devices (OLEDs) attract intensive attentions from both fundamental and applied researchers due to their unique properties of flexibility, light-weight, color-tunability, high electroluminescent efficiency, and ease of device fabrication. The design of the emitting layer (EML) of OLEDs plays a dominant role in ruling the electroluminescent performances. Typically, the EML is composed of a host and an organic emitter. As the emerging emitters for OLEDs, thermally activated delayed fluorescence (TADF) materials are capable of utilizing 100% of the electrically generated excitons. However, the device performances are also limited by charge injection from the electrodes, charge balance in the EML, and the outcoupling schemes. In this contribution, we designed four host materials for the TADF emitter, which were synthesized based on spirofluorene and s-triazine moieties. The physical and chemical properties were characterized via thermogravimetric analysis, differential scanning calorimetry, UV-vis absorption, fluorescence, phosphorescence, cyclic voltammetry measurements. It is found that the four host materials exhibited excellent thermal stability and the peaks of the UV-vis absorption located between 280 and 355 nm, which led to freedom of self-absorption. From the low temperature phosphorescent spectra (77 K), we can determine that the peak wavelengths are 505, 519, 522, 525 nm respectively for DTSF-2-DP-TRZ, SF-2-DTDP-TRZ, SF-4-DTDP-TRZ, and SF-4-TDP-TRZ, which make them ideal as a host for green TADF emitters. To evaluate their performances in the electroluminescence, these host materials were blended with the green TADF emitter, i.e., 2,4,5,6-tetrakis(carbazole-9-yl)-1,3-dicyanobenzene (4CzIPN) with nearly 100% photoluminescence quantum yield, as the emitting layers processed by spin-coating. The used glass substrate was covered with pre-patterned indium tin oxide (ITO). After routine cleaning procedures, the ITO glass substrate was treated with UV-ozone for 20 min. And then the conducting polymer poly(styrene sulfonic acid)-doped poly(3,4-ethylenedioxythiophene) (PEDOT:PSS) was spin-coated onto the substrate, following with thermal anneal in the glove box. Later, the EML was spin-coated onto PEDOT:PSS from chlorobenzene solution. To improve the charge balance and thus high radiative recombination, we deposited the additional hole blocking layer, electron transporting layer, and electron injection layer onto the EML via vacuum process. By comparing the electroluminescent performances of the devices with the four hosts, we figure out the structure-property relationship. It is well known that the host materials played roles in ruling the exciton utilization. The electroluminescent spectra of the devices are similar with a slight deviation of the peak wavelengths, i.e., 516, 516, 502, and 506 nm respectively for the case using DTSF-2-DP-TRZ, SF-4-TDP-TRZ, SF-2-DTDP-TRZ, and SF-4-DTDP-TRZ as the hosts, which could be ascribed to the different polarity of the host-guest environment and the slightly incomplete of host-guest energy transfer. In our investigation, we found that the host DTSF-2-DP-TRZ exhibited high glass transition temperature, well-match energy levels, and bipolar charge injection. Therefore, the device with DTSF-2-DP-TRZ rendered a maximum brightness of 6600 cd/m2, a maximum current efficiency of 51.3 cd/A, and a maximum external quantum efficiency of 16.6%, which are superior to those of the devices with the other hosts. This work provides a guidance for exploring host materials for efficient OLEDs with TADF as the emitter. Further works on material and device optimization would lead to better electroluminescent performances to meet the requirements of mass production.

Three-Dimensional Structures of Nanoporous NiO/ZnO Nanoarray Films for Enhanced Electrochromic Performance.

An electrochromic device with the as-obtained nanoporous NiO /ZnO nanoarray as a working electrode was constructed and assembled. The nanoporous NiO/ZnO nanoarray film with a three-dimensional structure was prepared on indium tin oxide (ITO) glass substrate through a two-step route that combined chemical bath deposition method with a hydrothermal method. The nanoporous NiO/ZnO nanoarray electrode reveals a noticeable improvement in electrochromism compared with that of nanoporous NiO alone, including higher optical modulation (81 %), higher coloration efficiency (78.5 cm2 C-1 ), faster response times (2.6 and 9.7 s for coloring and bleaching, respectively), and favorable durability performance. Such enhancements are mainly attributed to the three-dimensional structures of nanoporous NiO coated on ZnO nanoarray, namely, 1) the uniform hexagonal ZnO nanoarray loads more nanoporous NiO, 2) nanoporous NiO cross-linked with ZnO nanorods provides a loose interspace morphology, 3) stronger adhesion between ZnO nanorods and ITO covered with ZnO seed, 4) core-shell and cross-linked structures promote electrolyte infiltration, and 5) appropriate band gaps improve charge transfer.

Experiments on the effects of varying subcooled conditions on the dynamics of single vapor bubble and heat transfer rates in nucleate pool boiling regime

Dependence of bubble dynamic parameters and the associated heat transfer mechanisms on varying levels of sub-cooled conditions has been experimentally studied. Isolated nucleate pool boiling experiments have been performed to generate a single vapor bubble on an ITO (Indium Tin Oxide) glass substrate for three degrees of sub-cooling (ΔTsub-cooled = 2 °C, 5 °C and 0 °C). Field measurements have been made using gradient-based rainbow schlieren deflectometry. Various sub-phenomena associated with a bubble cycle, for instance, bubble inception and its growth, bubble oscillation and its departure from the heated substrate, have been visualized in real time for the range of bulk conditions employed. The recorded rainbow schlieren images have been analyzed to determine the transient variations of bubble dynamic parameters such as equivalent bubble diameter, bubble base diameter and aspect ratio. Effects of sub-cooled level on bubble oscillations have been estimated based on the dynamic variations in the hue values in the vicinity of the oscillating bubble. Spectral analysis of the hue variations showed an increasing trend in the oscillation frequency with sub-cooling conditions (foscillation = 52.8 Hz and 47.2 Hz for ΔTsubcool = 5 °C and 2 °C respectively). Based on the whole-field temperature distribution retrieved through the quantitative analysis of the schlieren images, individual contributions of the various heat transfer mechanisms (natural convection, bubble growth and superheat layer) towards the overall heat transfer rates have been determined. Results revealed that the contribution of natural convection heat transfer increases from 54% under saturation conditions to up to 99% for ΔTsub-cooling = 5 °C.

Low-Cost and Flexible Anti-Reflection Films Constructed From Nano Multi-Layers of TiO2 and SiO2 for Perovskite Solar Cells

We theoretically investigate the anti-reflection (AR) films based on nano multi-layers (NML) of TiO <sub xmlns:mml="http://www.w3.org/1998/Math/MathML" xmlns:xlink="http://www.w3.org/1999/xlink">2</sub> and SiO <sub xmlns:mml="http://www.w3.org/1998/Math/MathML" xmlns:xlink="http://www.w3.org/1999/xlink">2</sub> . This kind of NML dielectric structures have the advantages of low-cost and flexible. Six kinds of transparent conductive substrate (TCS) have been studied here, which are ITO (indium tin oxide) glass, FTO (fluorine-doped tin oxide) glass, ITO PEN (polyethylene naphthalate), FTO PEN, ITO PET (polyethylene terephthalate), and FTO PET, respectively. The AR effect is about 2.3825% for FTO glass substrate, about 3.4232% for ITO glass substrate, about 5.2703% for FTO PEN substrate, about 5.0914% for ITO PEN, about 3.8584% for FTO PET, and about 4.2371% for ITO PET. In practice, this kind of AR films can be widely applicable to enhance the external quantum efficiency (EQE) of the solar cells, and then improve the power conversion efficiency (PCE). Finally, the improved PCE of perovskite solar cells based on our NML AR films is theoretically obtained.

Antifouling Surfaces Based on Fluorine-Containing Asymmetric Polymer Brushes: Effect of Chain Length of Fluorinated Side Chain.

The influence of chain length of a fluorinated side chain of an asymmetric polymer brush with poly(ethylene glycol) (PEG) side chains on the antifouling property was systematically investigated so as to obtain more knowledge for deepening our understanding of the structure-(antifouling)-property relationship of asymmetric polymer brush. A series of asymmetric polymer brushes, consisting of hydrophobic poly(pentafluoropropyl methacrylate) (PPTFMA) side chains with the number of repeat units of pentafluoropropyl methacrylate (PTFMA) ranging from 8 to 42 and hydrophilic PEG side chains, was first synthesized by sequential reversible addition-fragmentation chain transfer (RAFT) polymerization and atom transfer radical polymerization (ATRP). Subsequently, thin films were prepared by spin-casting the solution of these brushes onto indium tin oxide (ITO) and SiO2 substrates. Water contact angle analysis showed that the hydrophobicity of the film surface increased with the length of PPTFMA side chain. The atomic force microscopy (AFM) measurement demonstrated that these films had a roughness of <3 and <10 nm onto ITO glass and SiO2 substrates, respectively. The antifouling behaviors of these films in bovine serum albumin (BSA) solution were evaluated by quartz crystal microbalance (QCM), which showed that the asymmetric brush surfaces had considerable antifouling performance with less protein adsorption in comparison with the bare surface. In addition, the films made from polymer brushes with shorter PPTFMA side chains exhibited better antifouling and fouling-release behaviors.

Microwave Spectroscopic Detection of Human Hsp70 Protein on Annealed Gold Nanostructures on ITO Glass Strips.

Conductive indium-tin oxide (ITO) and non-conductive glass substrates were successfully modified with embedded gold nanoparticles (AuNPs) formed by controlled thermal annealing at 550 °C for 8 h in a preselected oven. The authors characterized the formation of AuNPs using two microscopic techniques: scanning electron microscopy (SEM) and atomic force microscopy (AFM). The analytical performances of the nanostructured-glasses were compared regarding biosensing of Hsp70, an ATP-driven molecular chaperone. In this work, the human heat-shock protein (Hsp70), was chosen as a model biomarker of body stress disorders for microwave spectroscopic investigations. It was found that microwave screening at 4 GHz allowed for the first time the detection of 12 ng/µL/cm2 of Hsp70.