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      KCI등재 SCOPUS SCIE

      Study of degradation in bulk lifetime of n-type silicon wafer due to oxidation of boron-rich layer

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      https://www.riss.kr/link?id=A103562672

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      다국어 초록 (Multilingual Abstract)

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      한국어
      Various boron (B) diffusion techniques are being investigated to fabricate n-type Si solar cells. Thermal oxidation is often used to remove boron-rich layer (BRL) formed as a byproduct of B diffusion because BRL interferes with surface passivation of boron emitter. However, oxidizing the BRL can cause significant degradation in bulk lifetime. In this paper, high resolution electron microscopy (HREM) was performed to detect the presence of BRL after B diffusion and its removal after subsequent oxidation. In addition, bulk lifetime of n-type Si with BRL was measured after various oxidation conditions to systematically investigate the mechanism of oxidation-induced lifetime degradation in n-type Si. Detailed analysis of the oxidized samples revealed that iron (Fe) is primary metal impurity responsible for the bulk lifetime degradation after oxidation. This happens because Fe is gettered in BRL after B diffusion and during the oxidation, when the BRL is consumed, Fe is released into the bulk to degrade lifetime.
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      Various boron (B) diffusion techniques are being investigated to fabricate n-type Si solar cells. Thermal oxidation is often used to remove boron-rich layer (BRL) formed as a byproduct of B diffusion because BRL interferes with surface passivation of ...

      Various boron (B) diffusion techniques are being investigated to fabricate n-type Si solar cells. Thermal oxidation is often used to remove boron-rich layer (BRL) formed as a byproduct of B diffusion because BRL interferes with surface passivation of boron emitter. However, oxidizing the BRL can cause significant degradation in bulk lifetime. In this paper, high resolution electron microscopy (HREM) was performed to detect the presence of BRL after B diffusion and its removal after subsequent oxidation. In addition, bulk lifetime of n-type Si with BRL was measured after various oxidation conditions to systematically investigate the mechanism of oxidation-induced lifetime degradation in n-type Si. Detailed analysis of the oxidized samples revealed that iron (Fe) is primary metal impurity responsible for the bulk lifetime degradation after oxidation. This happens because Fe is gettered in BRL after B diffusion and during the oxidation, when the BRL is consumed, Fe is released into the bulk to degrade lifetime.

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      참고문헌 (Reference)

      1 M. J. Kerr, "Very low bulk and surface recombination in oxidized silicon wafers" 17 : 35-, 2001

      2 P. Sieu Pheng, "Tradeoffs between impurity gettering, bulk degradation, and surface passivation of boron-rich layers on silicon solar cells" 3 : 261-266, 2013

      3 D. Macdonald, "Recombination in n- and p-type silicon emitters contaminated with iron" 952-955, 2006

      4 V. V€ah€anissi, "Physical mechanisms of boron diffusion gettering of iron in silicon" 4 : 136-138, 2010

      5 O. Paz, "POCl3 and boron gettering of LSI silicon devices:similarities and differences" 126 : 1754-1761, 1979

      6 A. A. Istratov, "Metal content of multicrystalline silicon for solar cells and its impact on minority carrier diffusion length" 94 : 6552-, 2003

      7 S. M. Myers, "Mechanisms of transition-metal gettering in silicon" 88 : 3795-3819, 2000

      8 D. Macdonald, "Iron detection in crystalline silicon by carrier lifetime measurements for arbitrary injection and doping" 95 : 1021-1028, 2004

      9 A. Istratov, "Iron and its complexes in silicon" 69 : 13-44, 1999

      10 Y. -W. Ok, "Ion-implanted and screen-printed large area 20% efficient n-type front junction Si solar cells" 123 : 92-96, 2014

      1 M. J. Kerr, "Very low bulk and surface recombination in oxidized silicon wafers" 17 : 35-, 2001

      2 P. Sieu Pheng, "Tradeoffs between impurity gettering, bulk degradation, and surface passivation of boron-rich layers on silicon solar cells" 3 : 261-266, 2013

      3 D. Macdonald, "Recombination in n- and p-type silicon emitters contaminated with iron" 952-955, 2006

      4 V. V€ah€anissi, "Physical mechanisms of boron diffusion gettering of iron in silicon" 4 : 136-138, 2010

      5 O. Paz, "POCl3 and boron gettering of LSI silicon devices:similarities and differences" 126 : 1754-1761, 1979

      6 A. A. Istratov, "Metal content of multicrystalline silicon for solar cells and its impact on minority carrier diffusion length" 94 : 6552-, 2003

      7 S. M. Myers, "Mechanisms of transition-metal gettering in silicon" 88 : 3795-3819, 2000

      8 D. Macdonald, "Iron detection in crystalline silicon by carrier lifetime measurements for arbitrary injection and doping" 95 : 1021-1028, 2004

      9 A. Istratov, "Iron and its complexes in silicon" 69 : 13-44, 1999

      10 Y. -W. Ok, "Ion-implanted and screen-printed large area 20% efficient n-type front junction Si solar cells" 123 : 92-96, 2014

      11 K. Ryu, "High-efficiency n-type Si solar cells with novel inkjetprinted boron emitters" 33 : 2012

      12 K. Ryu, "High efficiency large area n-type front junction silicon solar cells with boron emitter formed by screen printing technology" 23 : 119-123, 2015

      13 S. Rein, "Electronic properties of interstitial iron and iron-boron pairs determined by means of advanced lifetime spectroscopy" 98 : 113711-, 2005

      14 H. M0saad, "Electronic passivation of silicon surfaces by halogens" 23 : 487-491, 1994

      15 S. P. Phang, "Direct comparison of boron, phosphorus, and aluminum gettering of iron in crystalline silicon" 109 : 073521-, 2011

      16 R. A. Sinton, "Contactless determination of currentevoltage characteristics and minority-carrier lifetimes in semiconductors from quasi-steadystate photoconductance data" 69 : 2510-, 1996

      17 M. A. Kessler, "Charge carrier lifetime degradation in Cz silicon through the formation of a boron-rich layer during BBr3 diffusion processes" 25 : 055001-, 2010

      18 P. Rothhardt, "Characterization of POCl-based codiffusion processes for bifacial n-type solar cells" 4 : 827-833, 2014

      19 B. Sopori, "Bulk defect generation during B-diffusion and oxidation of CZ wafers: mechanism for degrading solar cell performance" 0719-0723, 2014

      20 P. Negrini, "Boron predeposition in silicon using BBr3" 125 : 609-613, 1978

      21 A. Das, "Boron diffusion with boric acid for high efficiency silicon solar cells" 157 : 2010

      22 A. Das, "20% efficient screen-printed n-type solar cells using a spin-on source and thermal oxide/silicon nitride passivation" 1 : 146-152, 2011

      23 S. Barth, "19. 4 efficient bifacial solar cell with spin-on boron diffusion" 38 : 410-415, 2013

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      2023 평가예정 해외DB학술지평가 신청대상 (해외등재 학술지 평가)
      2020-01-01 평가 등재학술지 유지 (해외등재 학술지 평가) KCI등재
      2008-01-01 평가 등재학술지 선정 (등재후보2차) KCI등재
      2007-01-01 평가 등재후보 1차 PASS (등재후보1차) KCI등재후보
      2003-01-01 평가 등재후보학술지 선정 (신규평가) KCI등재후보
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      기준연도 WOS-KCI 통합IF(2년) KCIF(2년) KCIF(3년)
      2016 1.8 0.18 1.17
      KCIF(4년) KCIF(5년) 중심성지수(3년) 즉시성지수
      0.92 0.77 0.297 0.1
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