燃料电池文献综述和参考文献(2)

(3)燃料供给困难。尤其是使用氢气作为电池的燃料，由于氢气的储存和运输不方便，于此对应的氢燃料供给站还需要大力建设，很大程度上阻碍了电池的使用。目前的储氢方法可以实现的储氢容量不高，从很大程度上制约了燃料电池高能量密度的实现。如果改用煤气或者其他非氢气气体燃料，还需要对燃料进行重整，加大了投入成本。[4]
参考文献
[1]孙丽美,曹殿学,王贵领等.纳米Pd上H2O2的电催化还原反应[J].物理化学学报.2008,24(2):323-327
[2] 赵钦，孙丽美*，周淑娟等．氧化锡锑负载纳米Pd 催化H2O2电还原反应的催化性能[J]. 贵金属.2013,34(1):13-14
[3]韦雯雯．质子膜燃料电池的热力学优化研究及应用[D]．东华大学．2013
[4]倪学敏．直接硼氢化物燃料电池催化剂的研究[D]．武汉理工大学．2010
[5]刘建国，衣宗廉，魏昭彬．直接甲醇燃料电池的原理、进展和主要技术问题[J]．电源技术，2001，25(5)：363．366
[6]PONCE DE LEON C, WALCH F C, PU!TCHER D, ct a1. Direct borohydride fuel cells[J]. J Power Sources. 2006,155(2):172-181
[7]JUNG H W.A comparison of sodium borohydride as a fuel for proton exchange membrane fuel cells and for direct borohydride fuel cell[J]. J Power Sources. 2006,l 55(2)：329—339．
[8] 魏建良,王先友,易四勇等. 直接硼氢化物燃料电池[J]. 化学进展.2008,20(9):1427～1432
[7] 毛示旻,刘建国,邹志刚等. 直接硼氢化钠／双氧水燃料电池研究[J].电源技术. 2008,32(12):827～831
[8]CHOUDHURY N A, RAMAN R K, SAMPATH S, et a1. An alkaline direct borohydride fuel cell with hydrogen peroxide as oxidant[J]. Journal of Power Sources. 2005, 143(1/2): 1-8
[9]刘学．以石墨烯为载体的直接硼氢化钠燃料电池阳极催化剂研究[D]．湘潭大学．2010
[10]RAMAN R K，CHOUDHURY N A , SHUKLA A K. A high output voltage direct borohydride fuel cell[J]. Electrochemical and Solid State Letters. 2004, 7(12): A 488-A 491
[11]LUO N, MILEY G H, KIM K-J, et a1. NaBHdH202 fuel cells for air independent power systems[J]_Journal of Power Sources. 2008, 185(2): 685—690
[12]CAO D, SUN L, WANG G, et a1. Kinetics of hydrogen peroxide electroreduction on Pd nanoparticles in acidic medium[J]. Journal of Electroanalytical Chemistry. 2008, 621(1): 31—37
[13]WU H, WANG C, LIU Z, et a1. Influence of operation conditions on direct NaBH4/H202 fuel cell performance[J]. International Journal of Hydrogen Energy. 2010, 35(7): 2648-2651
[14] RAMAN R K, SHUKLA A K. Electro-reduction of hydrogen per-oxide on iron tetramethoxy phenyl porphyrin an d lead sulfate electrodes with application in direct borohydride fuel cells[J]. Journal of Applied Electrochemistry. 2005, 35: 1 157-1161
[15] LIU H, ZHANG L, ZHANG J, et a1. Electrocatalytic reduction of O2 and H202 by adsorbed cobalt tetramethoxyphenyl porphyrin and its application for fuel cell cathodes[J]. Journal of Power Sources. 2006, 161(2): 743-752
[16] DIAS V L N, FERNANDES E N, DA SILVA L M S, et a1. Electrochemical reduction of oxygen and hydrogen peroxide catalyzed by a surface copper(II)-2,4,6-tris(2-piridil)-1,3,5-triazine complex adsorbed on a graphite electrode[J]. Journal of Power Sources. 2005, 142(1/2): 10-17
[17] 李一栋,殷金玲. H2O2基燃料电池阴极催化剂的研究进展[J].化学工程师. 2011,189(6):42～44
[18]SELVARANI G, PRASHANT S K, SAHU A K, et a1. A direct borohydride fuel cell employing Prussian Blue as mediated electron-transfer hydrogen peroxide reduction catalyst[J]. Journal of Power Sources. 2008, 178(1): 86-91
[19] Aricò A S, Srinivasan S, Antonucci V. DMFCs: From Fundamental Aspects to Technology Development [J].Fuel Cells. 2001, 1(2): 133-161
[20] Ralph T R, Hogarth M P. The cathode challenges[J]. Platinum Metals Review. 2002,46 (1): 3-14
[21] Ysmael V,Gabriel A N,Mario M Y,et al. Active area and particle size of Pt particles synthesized from (NH4)2PtCl6 on a carbon support. Catalysis Today. 2005，107-108(970)：826-830 燃料电池文献综述和参考文献(2):http://www.751com.cn/wenxian/lunwen_26341.html