Surfactant-treated graphene oxide in organic solvents and its application in photovoltaic cells

Yishan Wang,Shengyi Yang,Haowei Wang,Li Zhang,Haijuan Cheng,Bo He,Weile Li,Bingsuo Zou 한국물리학회 2017 Current Applied Physics Vol.17 No.3

In this paper, a simple and non-poisonous “surfactant treatment” method to prepare graphene oxide (GO) in organic solvents with good dispersibility was presented. As the surfactant molecules, didodecyldimethyla-mmonium bromide (DDAB) was attached onto the GO sheets via ionic interactions by mild sonication, the obtained GO:DDAB nanocomposites were then blended into copolymer Poly(3- hexylthiophene-2,5-diyl) (P3HT) [6,6]:-Phenyl C61 butyric acid methyl ester (PC61BM) as the active layer to fabricate bulk-heterojunction (BHJ) organic solar cells ITO/PEDOT:PSS/P3HT:PC61BM:(GO:DDAB)/ Ca/Al. The concentration of GO:DDAB in the active layer, a maximum power conversion efficiency (PCE) of 3.67% was obtained by blending 0.5 mg/mL GO:DDAB in the active layer, showing an efficiency increment of 13.35% as compared with that of the control device without doping GO:DDAB. The optimized OPVs with PTB7:PC71BM by adding GO:DDAB shows the PCE of 7.96%. Therefore, it paves a way to get high efficiency organic photovoltaic cells by directly blending surfactant-treated graphene oxide in organic solvent.

Identification and comparative analysis of the pearl oyster Pinctada fucata hemocytes microRNAs in response to Vibrio alginolyticus infection

Zhongliang Wang,Bei Wang,Gang Chen,Yishan Lu,Jichang Jian,Zaohe Wu 한국유전학회 2017 Genes & Genomics Vol.39 No.10

MicroRNAs (miRNAs) are a class of noncoding RNA molecules that function as negative regulators of gene expression and play important roles in a wide spectrum of biological processes, including in immune response. However, the physiological regulation function of Pinctada fucata miRNAs, specially their immunomodulation has not been explored yet. Here, two small RNA libraries from hemocytes of P. fucata with or without Vibrio alginolyticus infection were constructed and sequenced using the high-throughput Illumina deep sequencing technology. In total, 11,939,992 and 11,083,327 raw reads, corresponding to 10,993,546 and 9,988,179 clean reads, were respectively obtained in the control and infected libraries. A total of 276 miRNAs, including 225 known miRNAs and 51 putative novel miRNAs, were identified by bioinformatic analysis. By using pairwise comparison between two libraries, 93 miRNAs were found to be significantly differentially expressed, with 42 and 51 miRNAs exhibiting up-regulation and down-regulation, respectively. Thereinto, some known miRNAs were considered to be immune-related. Real-time PCR were implemented for 6 miRNAs co-expressed in the control and infected samples, and agreement was confirmed between the high-throughput sequencing and real-time PCR data. After miRNA targets were predicted, GO and KEGG pathway enrichment analysis were performed, and the results indicated that ten of the differentially expressed miRNAs were involved in immunerelated pathways, and might participate in the host immune response to V. alginolyticus. These results of identification and comparative analysis of miRNAs might deepen our understanding of host-pathogen interactions and immune defense mechanisms in P. fucata.

Degradation Phenomena of Wooden Pillars in the Main Hall of the Fengguo Monastery, Yixian, Liaoning, China - Scientific Investigation with XRD, IC, and FTIR Analysis -

Yishan Zhou,Toshiya Matsui,Cheng Liu,Fei Wang 한국문화재보존과학회 2020 보존과학회지 Vol.36 No.1

The Main Hall of the Fengguo monastery in Yixian county, Liaoning province, China, is the best preserved and largest wooden Buddhist structure, typical of the Liao dynasty style, in China. However, some degradation to the timber frame of the Main Hall has been noted, and this is causing concern in terms of the long-term preservation of the structure. In this study, wooden pillars showing the degradation phenomena of whitening, for areas in contact with the stone floor, and extensive surface damage at higher locations(mostly above 1 m) have been examined. Samples taken from wooden pillar surfaces were analyzed using X-ray powder diffraction, Fourier-transform infrared spectroscopy(FTIR), ion chromatography, and pH measurements. With respect to the whitening phenomenon, we found inorganic calcium precipitates and oxalate ions, along with higher pH values. These symptoms indicated that chemical changes were taking place in response to alkaline conditions, suggesting that alkaline mixtures with calcium content in the foundations may be responsible. Regarding the upper surface-damaged areas, no valid evidence for chemical degradation was found using FTIR analysis, while damaged areas exhibited the presence of more bat guano-related materials than which were apparent in undamaged areas. The occurrence of this surface-damaged phenomenon has therefore been attributed to physical damage caused by bat activity over long periods of time.

Influence Factor on Magnetization Property of Carbonyl Iron-based Magnetorheological Fluids

Daoming Wang,Bin Zi,Sen Qian,Jun Qian,Yishan Zeng 한국자기학회 2016 Journal of Magnetics Vol.21 No.4

Magnetization property is a critical factor for magnetorheological fluids (MRFs) to achieve the liquid-solid transition. The main focus of this study is on exploring the influence factors on magnetization properties of MRFs. In this paper, a theoretical analysis is performed to discuss the magnetization characteristics of MRFs firstly. Then, a method for the preparation of carbonyl iron-based MRFs is illustrated and five MRFs samples with various material parameters are prepared. It is succeeded by a series of experiments on testing the hysteresis loop and the magnetization curve of each sample and the influence factors are compared and analyzed. Experimental results indicate that there is basically no hysteresis phenomenon on MRFs which exhibits superparamagnetic behavior at room temperature. A surfactant coating on magnetic particles can slightly improve the MRFs magnetization. Additionally, the magnetic susceptibility and the saturation magnetization both increase with the particle concentration, whereas the influence of particle diameter is relatively very small. Moreover, as the temperature increases, the magnetization decreases and the declining rate accelerates gradually.

Molecular characterization and expression of ZAP-70 in Nile tilapia (Oreochromis niloticus) in response to Streptococcus agalactiae stimulus

Pin Nie,Yishan Lu,Zhen Gan,Bei Wang,Wei Zhou,Yanfei Zhang,JiChang Jian,Zaohe Wu 한국유전학회 2016 Genes & Genomics Vol.38 No.4

The 70 kDa zeta-chain associated protein kinase (ZAP-70) plays a critical role in effective signal transductions that are fundamental to T cell differentiation, proliferation and effector functions. In this paper, the ZAP- 70 gene of Nile tilapia, Oreochromis niloticus (designated as On-ZAP-70) was cloned and its expression pattern under the stimulation of Streptococcus agalactiae was investigated. Sequence analysis showed important structural characteristics required for TCRs signal transduction were detected in the deduced amino acid sequence of On-ZAP- 70, and the deduced genomic structure of On-ZAP-70 was similar to the known ZAP-70. In healthy tilapia, the On- ZAP-70 transcripts were mainly detected in the thymus, spleen, head kidney and gill. Moreover, there was a clear time-dependent expression pattern of On-ZAP-70 after immunization and the expression reached the highest level at 48 h in the spleen and head kidney, and at 72 h in the thymus, respectively. This is the first report on the expression of ZAP-70 induced by intracellular bacteria vaccination in teleosts. These findings indicated that On- ZAP-70 may play an important role in the immune response to intracellular bacteria in Nile tilapia.

Preparation of moso bamboo columnar activated carbon with high adsorption property via polyacrylamide@asphalt adhesives and steam activation

Liu Huan,Miao Yu,Tian Huayu,Chen Yishan,Wang Enfu,Huang Jingda,Zhang Wenbiao 한국탄소학회 2024 Carbon Letters Vol.34 No.3

Moso bamboo, as a kind of renewable functional material, exhibits outstanding development potential. It is promising to prepare activated carbon with good mechanical strength and high specific surface area using moso bamboo as raw material. In this work, we employed a hydraulic extruder to extrude the bamboo charcoal and the adhesive to obtain the moso bamboo activated carbon, and improved the specific surface area of the columnar activated carbon through high-temperature water vapor activation. Through the catalytic role of the water vapor activation process, the formation and expansion of the pores were promoted and the internal pores were greatly increased. The obtained columnar activated carbon shows excellent mechanical strength (93%) and high specific surface area (791.54 m2/g). Polyacrylamide@asphalt is one of the most effective adhesives in the high-temperature water vapor activation. The average pore size (22.99 nm) and pore volume (0.36 cm3/g) of the prepared columnar activated carbon showed a high mesoporous ratio (83%). Based on the excellent pore structure brought by the activation process, the adsorption capacity of iodine (1135.75 mg/g), methylene blue (230 mg/g) and carbon tetrachloride (64.03 mg/g) were greatly improved. The resultant moso bamboo columnar activated carbon with high specific surface area, excellent mechanical properties, and outstanding adsorption capacity possesses a wide range of industrial applications and environmental protection potential.

Tellurium-enhanced nonresonant third-order optical nonlinearity in a germanosilicate optical fiber.

Lin, Aoxiang,Liu, Xueming,Watekar, Pramod R,Zhao, Wei,Peng, Bo,Lu, Min,Wei, Wei,Sun, Chuandong,Wang, Yishan,Han, Won-Taek,Toulouse, Jean Optical Society of America 2009 Applied Optics Vol.48 No.26

<P>A tellurium-doped germanosilicate optical fiber was developed by modified chemical vapor deposition and solution doping techniques. Using the continuous-wave self-phase modulation method, the nonresonant nonlinear refractive index, n2, was measured to be 5.52 x 10(-20) m2/W, which is 2 to 3 times that of the undoped germanosilicate glass fiber. Polyhedron structures TeO3 and TeO4 with GeO4 and SiO4 are believed responsible for lower phonon energy, more nonbridging oxygens, and a larger hyperpolarization, leading to the observed higher nonresonant optical nonlinearity.</P>

Conductively coupled flexible silicon electronic systems for chronic neural electrophysiology

Li, Jinghua,Song, Enming,Chiang, Chia-Han,Yu, Ki Jun,Koo, Jahyun,Du, Haina,Zhong, Yishan,Hill, Mackenna,Wang, Charles,Zhang, Jize,Chen, Yisong,Tian, Limei,Zhong, Yiding,Fang, Guanhua,Viventi, Jonathan National Academy of Sciences 2018 PROCEEDINGS OF THE NATIONAL ACADEMY OF SCIENCES OF Vol.115 No.41

<P>Materials and structures that enable long-term, intimate coupling of flexible electronic devices to biological systems are critically important to the development of advanced biomedical implants for biological research and for clinical medicine. By comparison with simple interfaces based on arrays of passive electrodes, the active electronics in such systems provide powerful and sometimes essential levels of functionality; they also demand long-lived, perfect biofluid barriers to prevent corrosive degradation of the active materials and electrical damage to the adjacent tissues. Recent reports describe strategies that enable relevant capabilities in flexible electronic systems, but only for capacitively coupled interfaces. Here, we introduce schemes that exploit patterns of highly doped silicon nanomembranes chemically bonded to thin, thermally grown layers of SiO2 as leakage-free, chronically stable, conductively coupled interfaces. The results can naturally support high-performance, flexible silicon electronic systems capable of amplified sensing and active matrix multiplexing in biopotential recording and in stimulation via Faradaic charge injection. Systematic in vitro studies highlight key considerations in the materials science and the electrical designs for high-fidelity, chronic operation. The results provide a versatile route to biointegrated forms of flexible electronics that can incorporate the most advanced silicon device technologies with broad applications in electrical interfaces to the brain and to other organ systems.</P>