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Lu Tian et al[10] synthesized the molecular precursor (TMEDA)Ni(SC{O}C6H5)2.
(C) (A) (B) (D) (E) (F) Figure. 1 SEM images of nickel sulfide nanostructures from: A) Tang[7], B) Lang[8], C) Liu[9] , D) Tian[10], E) Yang[12] and F) Zhang[13] paper PengFei Yang et al[12] synthesized Nanorods of NiS successfully prepared by a solvothermal synthetic route using S and Ni powders as reagents in ethylenediamine solvent at the temperature of 200◦C (Figure 1e).
The Magnetic Properties of NiS nanocubes were studied by Lu Tian et al[10].
Tian, L.
Yang, B.

Degradation of P-nitrophenol Affected by Synergy of Indirect and Direct Electrooxidation TIAN Mei1,2,a, YANG Lijuan1,b, WANG Jing2,c, LI Zan1,d and CHEN Shen1,e 1Physical Chemistry Lab, Harbin University, Harbin, P.R.China 2College of Chemical Engineering and Materials Science, Heilongjiang University, Harbin, P.R.China ashl913@vip.sina.com, bylj9400@sina.com, ciljuse@126.com, dlizan80@126.com, eshally1995@yahoo.com.cn Keywords: p-nitrophenol, degradation, synergy, indirect and direct electrooxidation Abstract.
In Chinese [5] Weihong Huang, Dan Yang, Jiebing Ruan, et al..
[8] Mei Tian, Lijuan Yang, Ruihai Cui, et al..

For the large-scale singular systems, Chen Chao-tian, Liu Yong-qing[6] first investigated the stability of large-scale singular dynamical systems, and gave its interconnecting parameters regions of stability.
[3] Chen Chao-tian.
[6] Chen Chao-tian, Liu Yong-qing.
[8] Chen Chao-Tian, Liu Yong-Qing; Lyapunov stability analysis of linear singular dynamical systems, ICIPS '97. 1997 IEEE International Conference on Intelligent Processing Systems, Vol.1, 1997,635 – 639
[9] Yang Dong-mei, Zhang Qing-ling, Singular systems, Science Press, Beijing, 2004

Yang, Solar Energy, Vol. 84: p. 2195-2201 (2010)
Tian, S.
Yang, Dyes and Pigments, Vol. 96: p. 609-613 (2013)
Yang, et al., Surface Science, Vol. 605: p. 1281-1286 (2011)
Tian, et al., Materials Letters, Vol. 62: p. 77-80 (2008)

Xuyue Yang, The University of Electro-communications, Japan Members Prof.Rungang.WANG Chinese Mechanical Engineering Society China Mr.A.L.Yan Materials Society of CMES China Prof Ming LI National Natural Science Foundation of China China Prof.Xiaohong.WANG Harbin Institute of Technology China Prof Pan ZENG Tsinghua University China Prof Shipu CHEN Shanghai Jiaotong University China Prof.D.Steglich GKSS Germany Prof.S.B.Kang KIMM Korea Prof.Zheren YANG National Taiwan University Taiwan Dr A.A.Shirzadi University of Cambridge UK Prof.W.G.Xu TWI UK Prof.W.C.Chen Dynamic System Inc.
Yang Prof.
Harbin Institute of Technology Xiubo Tian Prof.
Avenida Universidad, Mexico Jer-Ren Yang Prof.
Baohui Tian Dr.

Tian and Y.
Yang: Trans.
Yang, S.
Tian: Materials Science Forum Vol. 686 (2011), p. 125 [11] M.B.
Yang, J.

Table 2 Basic information of TBS TBS name GSM equipment model The no. of frequency carrier Power of transmission equipment(W) area（m2） Materials of wall Area of window(m2) EER Ba Gua 2206 18 350 29 240mm brick wall 1.3 2.81 Chen Tian 2206 10 300 16 370mm brick wall 0.7 2.77 Under the circumstances that R is bigger than the corresponding lower limits, we have simulated two base stations with different (EC, R), and the results are shown in Fig.3 and Fig.4.
Fig.3 Simulation results in Ba Gua Fig.4 Simulation results in Chen Tian Figure 5 compare the energy consumptions under different frequency carrier intelligent shutoff strategies.
NONE Fig.5 Daily power consumption of Ba Gua(left) and Chen Tian(right) TBS Conclusion By building model systematically and comprehensively on frequency carrier intelligent shutoff technology of wireless device and heat exchange process in TBS, with the constraints of system state equations and the goal of minimizing total TBS energy consumption, we compare main strategies of frequency carrier intelligent shutoff technology, and following conclusions are drawn from our simulations.
[4] Rujing Guo, Xin Yang and Jianfei Hu.

Characteristics of Biodegradable Implantable Drug Delivery System with Micro-porous Structure Yang Gao 1,a, Xiaopeng Wang 1,b Tianning Chen 1,c 1 School of Mechanical Engineering,Xi'an Jiaotong University,Xi'an 710049,China a gyang1029@163.com, b xpwang@mail.xjtu.edu.cn, c tnchen@mail.xjtu.edu.cn Keywords: Micro-porous structure, PLGA, Drug release model, Simulation Abstract.
Richards Grayson (2005) achieved the target of drug release at different stage through pakaging with various PLGA [3], Tianning Chen(2006) found that the change of carrier structure could control the rate of drug release [4].
Biomaterials(S0142-9612), 26 (2005), p. 2137-2145 [4] Liangshan Qian, Tianning Chen: Design of New Controlled Drug release Micro-Carriers Based on MEMS of Its Drug Release Traits [J].
Proceeding of the 7th ICFDM (2006), p. 341-344 [5] Yang R, Chen T-N and Chen H-L: Microfabrication of biodegradable (PLGA) honeycomb structures and potential application in implantable drug delivery [J].

Yang: Trans.
Tian and Y.
Yang: Trans.
Yang, S.Q.
Tian: Materials Science Forum Vol. 686 (2011), p. 125 [12] J.X.

The Simulation of Strong Electromagnetic Field Experimental Environment around On-line Monitoring System for UHV Transmission Tower Shunren Hu1, a, Xiaofang Yang 1,b ,Liang Gu1,c , Li She1,d 1Electronic Information and Automation Academy, Chongqing University of Technology, China ahsr71@163.com, bsunflowerfang@hotmail.com, csheli@cqut.edu.cn, dguliang@cqut.edu.cn Keywords: UHV transmission tower; Monitoring system; Intense electromagnetic interference; Experimental environment; Simulation Abstract.
References [1] Yang Zhong-jiang.
[4] Yang Ru-gui.
[6] Tian Yang-meng., harm and mechanism of lightning electromagnetic pulse protection.
[7] Tian Ming-hong etc.