Showing papers by "Ho Won Jang published in 2014"

A New Water Oxidation Catalyst: Lithium Manganese Pyrophosphate with Tunable Mn Valency

Abstract: The development of a water oxidation catalyst has been a demanding challenge for the realization of overall water-splitting systems. Although intensive studies have explored the role of Mn element in water oxidation catalysis, it has been difficult to understand whether the catalytic capability originates mainly from either the Mn arrangement or the Mn valency. In this study, to decouple these two factors and to investigate the role of Mn valency on catalysis, we selected a new pyrophosphate-based Mn compound (Li2MnP2O7), which has not been utilized for water oxidation catalysis to date, as a model system. Due to the monophasic behavior of Li2MnP2O7 with delithiation, the Mn valency of Li2-xMnP2O7 (x = 0.3, 0.5, 1) can be controlled with negligible change in the crystal framework (e.g., volume change ∼1%). Moreover, inductively coupled plasma mass spectrometry, X-ray photoelectron spectroscopy, ex-situ X-ray absorption near-edge structure, galvanostatic charging–discharging, and cyclic voltammetry analysi...

Highly sensitive and selective H2 and NO2 gas sensors based on surface-decorated WO3 nanoigloos

Abstract: WO3 nanoigloos decorated with Ag-, Pd-, and Au nanoparticles are fabricated by soft-template method and self-agglomeration of metal films. The responses of WO3 nanoigloos decorated with metal nanoparticles to various gases such as NO2, CH3COCH3, C2H5OH, and H2 are much higher than those of bare WO3 nanoigloos. According to the surface decoration, WO3 nanoigloos show significantly different behaviors in the response enhancement, revealing that Pd-decorated WO3 nanoigloos exhibit the highest response to H2 together with fast response time to H2, C2H5OH, and CH3COCH3 (below 10 s), Au-decorated WO3 nanoigloos exhibit the highest response to NO2. The catalytic effect of Ag is relatively weaker than Pd and Au nanoparticles, however, it exhibit the fastest response time to NO2. These are attributed to not only the varied catalytic activities of the metal nanoparticles, but also the different work function energies of them. Our results show that highly sensitive and selective WO3 nanoigloos decorated with metal nanoparticles can be an effective platform to fabricate an electronic nose for the further application of semiconducting metal oxide gas sensors.

Vertically ordered hematite nanotube array as an ultrasensitive and rapid response acetone sensor.

Abstract: Vertically ordered nanotube array is a desirable configuration to improve gas sensing properties of the hematite which is the most abundant and cheapest metal oxide semiconductor on earth but has low and sluggish chemiresistive responses. We have synthesized a vertically aligned, highly ordered hematite nanotube array directly on a patterned SiO2/Si substrate and then it used as a gas sensor without additional processing. The nanotube array sensor shows unprecedentedly ultrahigh and selective responses to acetone with detection limits down to a few parts per billion and response time shorter than 3 s.

The use of UV/ozone-treated MoS2 nanosheets for extended air stability in organic photovoltaic cells

Abstract: MoS2 nanosheets obtained through a simple sonication exfoliation method are employed as a hole-extraction layer (HEL) to improve the efficiency and air stability of organic photovoltaic cells (OPVs). The reduction in the wavenumber difference, appearance of a UV-vis peak, and atomic force microscopy images indicate that MoS2 nanosheets are formed through the sonication method. The OPVs with MoS2 layers show a degraded performance with a power conversion efficiency (PCE) of 1.08%, which is lower than that of OPVs without HEL (1.84%). After performing the UV/ozone (UVO) treatment of the MoS2 surface for 15 min, the PCE value increases to 2.44%. Synchrotron radiation photoelectron spectroscopy data show that the work function of MoS2 increases from 4.6 to 4.9 eV upon UVO treatment, suggesting that the increase in the PCE value is caused by the bandgap alignment. Upon inserting poly(3,4-ethylenedioxythiophene):poly(styrene sulfonate) (PEDOT:PSS) between MoS2 and the active layer, the PCE value of the OPV increases to 2.81%, which is comparable with that of the device employing only PEDOT:PSS. Furthermore, the stability of the OPVs is improved significantly when MoS2/PEDOT:PSS layers are used as the HEL. Therefore, it is considered that the use of UVO-treated MoS2 may improve the stability of OPV cells without degrading the device performance.

Superhydrophobic and antireflective nanograss-coated glass for high performance solar cells

Abstract: We present a facile method for producing superhydrophobic nanograss-coated (SNGC) glass surfaces that possess both reduced reflectivity and self-cleaning properties at the air/glass interface. The refractive index of a CaF2 nanograss (NG) layer on a glass substrate, deposited by glancing angle vapor deposition, is 1.04 at 500 nm, which is the second-lowest value ever reported so far. The fluorinated NG layer gives rise to a high water contact angle (>150°) and very efficient cleaning out of dust with water drops. Using the dual functionalities of the SNGC glass, we demonstrate superhydrophobic and antireflective organic photovoltaic cells with excellent power conversion efficiency.

Influence of gas ambient on charge writing at the LaAlO3/ SrTiO3 heterointerface

Abstract: We investigated the influences of charge writing on the surface work function (W) and sheet resistance (R) of the LaAlO3/SrTiO3 (LAO/STO) heterointerface in several gas environments: H2(2%)/N2(98%), air, N2, and O2. The decrease in W and R due to charge writing was much larger in air (ΔW = −0.45 eV and ΔR = −40 kΩ/S) than in O2 (ΔW = −0.21 eV and ΔR = −19 kΩ/S). The reduced R could be maintained more than 100 h in H2/N2. Such distinct behaviors were quantitatively discussed, based on the proposed charge-writing mechanisms. Such analyses showed how several processes, such as carrier transfer via surface adsorbates, surface redox, electronic state modification, and electrochemical surface reactions, contributed to charge writing in each gas.

Low power consumption type gas sensor and method for manufacturing the same

Abstract: The present disclosure provides a gas sensor including: a substrate; an electrode formed on the substrate; and a gas-sensing layer formed on the electrode, wherein the gas-sensing layer is a self-heating nanocolumnar structure having nanocolumns formed on the electrode and inclined with respect to the electrode with an angle of 60-89° and gas diffusion pores formed between the nanocolumns. The gas sensor according to the present disclosure requires no additional heater since it self-heats owing to the nanocolumnar structure and exhibits superior gas sensitivity even when no heat is applied from outside. Also, it can be mounted on mobile devices such as mobile phones because it consumes less power.

Flexible transparent chemical sensors based on graphene oxide and method for preparing the same

Abstract: The present invention relates to a flexible transparent chemical sensor using graphene oxide which has low power consumption, a high sensitivity to ppm levels of gas, and flexible and transparent properties and operates at room temperature; and a method for preparing the same. According to the present invention, the flexible transparent chemical sensor comprises a substrate, a sensing electrode formed on the substrate, and a sensor active layer formed on the sensing electrode. Moreover, the sensor active layer consists of graphene oxide.

Method of gas sensor nano array including metal oxide nano wire pattern

Abstract: The present invention relates to a method of fabricating a gas sensor nanoarray including a metal oxide nanowire pattern The method of fabricating a gas sensor nanoarray includes forming a plurality of electrode pairs having a source electrode and a drain electrode on a substrate; forming an aligned metal oxide precursor/organic complex nanowire pattern on the source electrode and the drain electrode; and forming a nanowire pattern having a metal oxide by heating the metal oxide precursor/organic complex nanowire pattern According to the present invention, a gas sensor having improved electric charge mobility can be provided, a position and a direction of the metal oxide nanowire can be accurately modified, fabricating a large-area and high-performance nanowire gas sensor array is possible, and when forming the nanowire through an electro-hydrodynamic nanowire printer, nanowire forming speed is highly fast so the nanowire gas sensor can be fabricated faster than conventional methods

Chemiresistive Sensor Array Based on Semiconducting Metal Oxides for Environmental Monitoring

Abstract: We present gas sensing performance based on 22 sensor array with four different elements (TiO2, SnO2, WO3 and In2O3 thin films) fabricated by rf sputter. Each thin film was deposited onto the selected SiO2/Si substrate with Pt interdigitated electrodes (IDEs) of 5 m spacing which were fabricated on a SiO2/Si substrate using photolithography and dry etching. For 5 ppm NO2 and 50 ppm CO, each thin film sensor has a different response to offers the distinguishable response pattern for different gas molecules. Compared with the conventional micro-fabrication technology, 22 sensor array with such remarkable response pattern will be open a new foundation for monolithic integration of high-performance chemoresistive sensors with simplicity in fabrication, low cost, high reliablity, and multi- functional smart sensors for environmental monitoring.

Influence of gas ambient on charge writing at the LaAlO3/SrTiO3 heterointerface

Abstract: We investigated the influences charge writing on the surface work function and resistance of the LaAlO3/SrTiO3 (LAO/STO) heterointerface in several gas environments (air, O2, N2, and H2/N2). Charge writing decreased the surface work function and resistance of the LAO/STO sample quite a lot in air but slightly in O2.The interface carrier density was extracted from the measured sheet resistance and compared with that obtained from the proposed charge-writing mechanisms, such as carrier transfer via surface adsorbates and surface redox. Such quantitative analyses suggested that additional processes (e.g., electronic state modification and electrochemical surface reaction) were required to explain charge writing on the LAO/STO interface.