2017年我国光伏技术发展报告(2)Report on 2017 China PV technology development(part 2)
摘要(Abstract):
<正>在高效多晶的技术创新上,保利协鑫的镓共掺杂技术得到应用(市场上产品为S4),其主要效果是有效地减少了由于硼氧对引发的转换效率衰减,其光致衰减(light-induced degradation)是普通掺硼高效多晶电池的1/10,是PERC高效多晶电池的一种有潜力的多晶硅片。由于镓分凝系数小,造成多晶硅锭纵向电阻率变化较大,使得硅片得率和良率受到影响,成本升高。因此,保利协鑫与浙江大学硅材料国家重点实验室合作
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参考文献(References):
- [6]倪鹏.层流层对掺镓铸造多晶硅锭电阻率分布的影响[A].第十六届中国光伏学术大会[C].天津,2016.
- [7]黄春来,等.定向凝固法制备镓掺杂准单晶[A].第十六届中国光伏学术大会[C].天津,2016.
- [8]Cao F,Chen K X,Zhang J J,et al.Next-generation multicrystalline silicon Solar cells:Diamond-wire Sawing,nano-texture and High efficiency[J].Solar Energy Materials&Solar Cells,2015,141:132.
- [9]International Technology Roadmap for Photovoltaic(ITRPV)[EB/OL].http://www.itrpv.net/Reports/Downloads/,2017-05-01.
- [10]Chen Y F,Shen H,Altermatt P P.Analysis of recombination losses in screen-printed aluminum-alloyed back surface fields of silicon solar cells by numerical device simulation[J].Solar Energy Materials&Solar Cells,2014,120:356-362.
- [11]Schmidt J,Merkle A,Hoex B,et al.Atomic-layer-deposited aluminum oxide for the surface passivation of high-efficiency silicon solar cells[A].the 33rd IEEE Photovoltaic Specialists Conference[C].USA,2008.
- [12]Rentsch J.Industrial deposition of PECVD AlOx for rear passivation of PERC-type mc-Si solar cells[A].25th EU PV solar energy conference[C].Valencia,Spain,2010.
- [13]D Song,Xiong J,Hu Z,et al.Progress in n-type Si solar cell and module technology for high efficiency and low cost[A].38th IEEE Photovoltaic Specialist Conference[C].Austin,2012.
- [14]Benick J,Hoex B,Dingemans G,et al.High-efficiency n-type silicon solar cells with front side boron emitter[A].24th European Photovoltaic Solar Energy Conference[C].Hamburg,Germany,2009.
- [15]Cornagliotti E,Russell R,Tous L,et al.Bifacial n-PERT cells(Bi-PERT)with plated contacts for multi-wire interconnection[A].32nd European Photovoltaic Solar Energy Conference and Exhibition[C].Munich,2016.
- [16]Glunz S W,Feldmann F,Richter A,et al.the irresistible charm of a simple current flow pattern-25%with a solar cell featuring a full-area back contact[A].31st European photovoltaic solar energy conference and exhibition[C].Hamburg,2015.
- [17]Urue?a A,Aleman M,Cornagliotti E,et al.Beyond 22%large area n-type silicon solar cells with front laser doping and a rear emitter[A].31th European Photovoltaic Solar Energy Conference[C].Brussels,Belgium,2015.
- [18]光伏测试网.航天机电N型Pert双面双玻组件再创功率新高[EB/OL].http://www.testpv.com/portal.php?mod=view&aid=12184,2015-11-03.
- [19]Masuko K,Shigematsu M,Hashiguchi T,et al.Achievement of more than 25%conversion efficiency with crystalline silicon heterojunction solar cell[J].IEEE Journal of Photovoltaics,2014,4(6):1433-1435.
- [20]Emery K A,Green M A,Hishikawa Y.Solar cell efficiency tables(Version 45)[J].Progress in Photovoltaics,2015,23:1-9.
- [21]Seif J P,Gopal Krishnamani,Bénédicte Demaurex,et al.Amorphous/Crystalline Silicon Interface Passivation:AmbientTemperature Dependence and Implications for Solar Cell Performance[J].IEEE Journal of photovoltaics,2015,5(3):718-724.
- [22]Schwartz R J,Lammert M D.Silicon solar cells for high concentration applications[A].International Electron Devices Meeting[C].Washington,DC,1975.
- [23]Lammert M D,Schwartz R J.The interdigitated back contact solar cell:a silicon solar cell for use in concentrated sunlight[J].IEEE Transactions on Electron Devices,1977,24(4):337-42.
- [24]Smith D D,Cousins P,Westerberg S,et al.Towards the Practical Limits of Silicon Solar Cells[J].IEEE Journal of Photovoltaics,2014,4(6):1465-1469.
- [25]Green M A,Keith Emery,Yoshihiro Hishikawa,et al.Solar Cell Efficiency Tables(Version 47)[J].Progress in Photovoltaics:Research&Applications,2016,24:3-11.
- [26]Reichel C,Granek F,Hermle M,et al.Back-contacted backjunction n-type silicon solar cells featuring an insulating thin film for decoupling charge carrier collection and metallization geometry[J].Progress in Photovoltaics:Research&Applications,2013,21(5):1063-1076.
- [27]Peibst R,Harder N,Merkle A,et al.High-efficiency RISEIBC solar cells:influence of rear-side passivation on pn-junction meander recombination[A].28th European Photovoltaic Solar Energy Conference[C].Paris,France,2013.
- [28]Sullivan B O,Debucquoy M,Singh S,et al.Process Simplification for High Efficiency,Small area IBC silicon solar cells[A].28th European Photovoltaic Solar Energy Conference[C].Paris,France,2013.
- [29]Nakamura J,Katayama H,Koide N,et al.Development of Hetero-Junction Back Contact Si Solar Cells[A].40th IEEEPVSC[C].Denver,2014.
- [30]Masuko K,Shigematsu M,Hashiguchi T,et al.Achievement of more than 25%conversion efficiency with crystalline silicon heterojunction solar cell[A].40th IEEE PVSC[C].Denver,2014.
- [31]中国光伏测试网.日本Kaneka公司HBC电池效率达到创纪录的26.33%[EB/OL].http://www.testpv.com/portal.php?mod=view&aid=15021,2016-09-19.
- [32]PV-tech.[EB/OL].http://www.pv-tech.cn/news/HAREON_SOALR_REPORTS_SIGNIFICANT_TECHNOLOGY_ADVANCEMENT_AT_IEEE_PVSC,2017-05-01.
- [33]Franklin E,Fong K,Mcintosh K,et al.Design,fabrication and characterisation of a 24.4%efficient interdigitated back contact solar cell[A].29th European Photovoltaic Solar Energy Conference[C].Amsterdam,The Netherlands,2014.
- [34]Zhang X L,Yang Y,Liu W,et al.Development of high efficiency interdigitated back contact silicon solar cells and modules with industrial processing technologies[A].41st IEEEPVSC[C].Kyoto,Japan,2014.
- [35]Xu G C,Yang Y,Zhang X L,et al.6 inch IBC cells with efficiency of 23.5%fabricated with low-cost industrial technologies[A].43th IEEE PVSC[C].Portland,2016.
- [36]中国光伏行业协会.探究组件效率提升之道[J].光伏产业观察,2015,(10).
- [37]Green M A,Emery K,Hishikawa Y,et al.Solar cell efficiency tables(version 45)[J].Progress in Photovoltaics:Research&Applications,2015,23(1):1-9.