• Title/Summary/Keyword: Silicon heterojunction

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The Influence of the Wafer Resistivity for Dopant-Free Silicon Heterojunction Solar Cell (실리콘 웨이퍼 비저항에 따른 Dopant-Free Silicon Heterojunction 태양전지 특성 연구)

  • Kim, Sung Hae;Lee, Jung-Ho
    • Journal of Surface Science and Engineering
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    • v.51 no.3
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    • pp.185-190
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    • 2018
  • Dopant-free silicon heterojunction solar cells using Transition Metal Oxide(TMO) such as Molybdenum Oxide($MoO_X$) and Vanadium Oxide($V_2O_X$) have been focused on to increase the work function of TMO in order to maximize the work function difference between TMO and n-Si for a high-efficiency solar cell. One another way to increase the work function difference is to control the silicon wafer resistivity. In this paper, dopant-free silicon heterojunction solar cells were fabricated using the wafer with the various resistivity and analyzed to understand the effect of n-Si work function. As a result, it is shown that the high passivation and junction quality when $V_2O_X$ deposited on the wafer with low work function compared to the high work function wafer, inducing the increase of higher collection probability, especially at long wavelength region. the solar cell efficiency of 15.28% was measured in low work function wafer, which is 34% higher value than the high work function solar cells.

Phophorus External Gettering for High Quality Wafer of Silicon Heterojunction Solar Cells

  • Park, Hyo-Min;Tak, Seong-Ju;Kim, Chan-Seok;Park, Seong-Eun;Kim, Yeong-Do;Kim, Dong-Hwan
    • Proceedings of the Materials Research Society of Korea Conference
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    • 2011.05a
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    • pp.43.2-43.2
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    • 2011
  • Minority Carrier recombination should be suppressed for high efficiency solar cells. However, impurities in the silicon bulk region deteriorate the minority carrier lifetimes, causes conversion efficiency drop. In this study, we introduced phosphorus external gettering for silicon heterojunction solar cell substrates. Gettering was undergone at 750, 800, 850 and $900^{\circ}C$ in furnace for 30 minutes. Bulk lifetimes and calculated diffusion length were improved. We applied phosphorus gettering to silicon heterojunction solar cells. Gettered group and ungettered group were used as substrate of silicon heterojunction solar cells. After fabrication, characteristics of solar cells were analyzed. The results were observed to see the enhancement of substrate quality which directly connects with solar cell properties.

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Application of Novel BSF Metal and Laser Annealing to Silicon Heterojunction Solar Cell

  • Bong, Seong-Jae;Kim, Seon-Bo;An, Si-Hyeon;Park, Hyeong-Sik;Lee, Jun-Sin
    • Proceedings of the Korean Vacuum Society Conference
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    • 2014.02a
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    • pp.491.2-491.2
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    • 2014
  • Generally, silicon heterojunction solar cell has intrinsic and n-type of hydrogenated amorphous silicon (a-Si:H) as passivation layer and BSF layer. In this study, antimony, novel material, deposited on back side of the heterojunction solar cell as passivation and BSF layer to substitute the a-Si:H and the characteristics of the solar cell such electrical properties and optical properties were analyzed. And SIMS analysis was carried out to obtain the depth profile of the BSF layer which was deposited by laser annealing process.

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TCO Workfunction Engineering with Oxygen Reactive Sputtering Method for Silicon Heterojunction Sola Cell Application

  • Bong, Seong-Jae;Kim, Seon-Bo;An, Si-Hyeon;Park, Hyeong-Sik;Lee, Jun-Sin
    • Proceedings of the Korean Vacuum Society Conference
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    • 2014.02a
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    • pp.492-492
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    • 2014
  • On account of the good conductivity and optical properties, TCO is generally used in silicon heterojunction solar cell since the emitter material, hydrogenated amorphous silicon (a-Si:H), of the solar cell has low conductivity compare to the emitter of crystalline silicon solar cell. However, the work function mismatch between TCO layer and emitter leads to band-offset and interfere the injection of photo-generated carriers. In this study, work function engineering of TCO by oxygen reactive sputtering method was carried out to identify the trend of band-offset change. The open circuit voltage and short circuit current are noticeably changed by work function that effected from variation of oxygen ratio.

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Impact of Hydrogen-Doped Indium Oxide Films on the Performance of Silicon Heterojunction Solar Cells (수소 도핑된 인듐 산화막에 따른 실리콘 이종 접합 태양전지 성능에 미치는 영향)

  • Hyeong Gi Park;Jaehyeong Lee;Junsin Yi
    • Journal of the Korean Institute of Electrical and Electronic Material Engineers
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    • v.37 no.6
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    • pp.582-589
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    • 2024
  • We investigated the potential of IO:H thin films and hydrogen doping to improve current density and fill factor for enhancing the performance of silicon heterojunction solar cells. We revealed that a transmittance of 86.7% and work function of 5.4 eV could be achieved by injecting 3 sccm of hydrogen gas. The lattice constant of 1.037 nm at the AB site indicates an anion antibonding tendency, and the work function increases as the Fermi level shifts to the valence band. Based on these findings, we fabricated a silicon heterojunction solar cell and achieved an efficiency of 18.53%, while computer simulation confirmed a conversion efficiency of 24.65%, an open-circuit voltage of 724 mV, and a fill factor of 82.72% at a current density of 41.15 mA/cm2.

Effect of Interface Reaction between ZnO:Al and Amorphous Silicon on Silicon Heterojunction Solar Cells (실리콘 이종 접합 태양 전지 특성에 대한 ZnO:Al과 비정질 실리콘 계면 반응의 영향)

  • Kang, Min-Gu;Tark, Sung-Ju;Lee, Jong-Han;Kim, Chan-Seok;Jung, Dae-Young;Lee, Jung-Chul;Yoon, Kyung-Hoon;Kim, Dong-Hwan
    • Korean Journal of Materials Research
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    • v.21 no.2
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    • pp.120-124
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    • 2011
  • Silicon heterojunction solar cells have been studied by many research groups. In this work, silicon heterojunction solar cells having a simple structure of Ag/ZnO:Al/n type a-Si:H/p type c-Si/Al were fabricated. Samples were fabricated to investigate the effect of transparent conductive oxide growth conditions on the interface between ZnO:Al layer and a-Si:H layer. One sample was deposited by ZnO:Al at low working pressure. The other sample was deposited by ZnO:Al at alternating high working pressure and low working pressure. Electrical properties and chemical properties were investigated by light I-V characteristics and AES method, respectively. The light I-V characteristics showed better efficiency on sample deposited by ZnO:Al by alternating high working pressure and low working pressure. Atomic concentrations and relative oxidation states of Si, O, and Zn were analyzed by AES method. For poor efficiency samples, Si was diffused into ZnO:Al layer and O was diffused at the interface of ZnO:Al and Si. Differentiated O KLL spectra, Zn LMM spectra, and Si KLL spectra were used for interface reaction and oxidation state. According to AES spectra, sample deposited by high working pressure was effective at reducing the interface reaction and the Si diffusion. Consequently, the efficiency was improved by suppressing the SiOx formation at the interface.

Research and Development Trend of Carrier Selective Energy Contact Solar Cells (전하선택형 태양전지의 연구개발 동향)

  • Cho, Eun-Chel;Cho, Young Hyun;Yi, Junsin
    • Current Photovoltaic Research
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    • v.6 no.2
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    • pp.43-48
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    • 2018
  • The traditional silicon heterojunction solar cells consist of intrinsic amorphous silicon to prevent recombination of the silicon surface and doped amorphous silicon to transport the photo-generated electrons and holes to the electrode. Back contact solar cells with silicon heterojunction exhibit very high open-circuit voltages, but the complexity of the process due to form the emitter and base at the backside must be addressed. In order to solve this problem, the structure, manufacturing method, and new materials enabling the carrier selective contact (CSC) solar cell capable of achieving high efficiency without using a complicated structure have recently been actively developed. CSC solar cells minimize carrier recombination on metal contacts and effectively transfer charge. The CSC structure allows very low levels of recombination current (eg, Jo < 9fA/cm2), thereby achieves high open-circuit voltage and high efficiency. This paper summarizes the core technology of CSC solar cell, which has been spotlighted as the next generation technology, and is aiming to speed up the research and development in this field.

Surface passivation study of a-Si:H/c-Si heterojunction solar cells using VHF-CVD (VHF-CVD를 이용한 a-Si:H/c-Si 이종접합태양전지 표면 패시배이션 연구)

  • Song, JunYong;Jeong, Daeyoung;Kim, Kyoung Min;Park, Joo Hyung;Song, Jinsoo;Kim, Donghwan;Lee, JeongChul
    • 한국신재생에너지학회:학술대회논문집
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    • 2011.05a
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    • pp.128.1-128.1
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    • 2011
  • In amorphous silicon and crystalline silicon(a-Si:H/c-Si) heterojuction solar cells, intrinsic hydrogenated amorphous silicon(a-Si:H) films play an important role to passivate the crystalline silicon wafer surfaces. We have studied the correlation between the surface passivation quality and nature of the Si-H bonding at the a-Si:H/c-Si interface. The samples were obtained by VHF-CVD under different deposition conditions. The passivation quality and analysis of all structures studied was performed by means of quasi steady state photoconductance(QSSPC) methods and fourier transform infrared spectrometer(FTIR) measurements respectively.

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Effect on the Thermal Treatment for Improving Efficiency in Silicon Heterojunction Solar Cells (이종접합 실리콘 태양전지의 효율 개선을 위한 열처리의 효과)

  • Hyeong Gi Park;Junsin Yi
    • Journal of the Korean Institute of Electrical and Electronic Material Engineers
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    • v.37 no.4
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    • pp.439-444
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    • 2024
  • This study investigates the post-thermal treatment effects on the efficiency of silicon heterojunction solar cells, specifically examining the influence of annealing on p-type microcrystalline silicon oxide and ITO thin films. By assessing changes in carrier concentration, mobility, resistivity, transmittance, and optical bandgap, we identified conditions that optimize these properties. Results reveal that appropriate annealing significantly enhances the fill factor and current density, leading to a notable improvement in overall solar cell efficiency. This research advances our understanding of thermal processing in silicon-based photovoltaics and provides valuable insights into the optimization of production techniques to maximize the performance of solar cells.