25.9% 高效 ZnOxNy/Si 串联太阳能电池的器件模拟

IF 2.9 4区工程技术 Q1 MULTIDISCIPLINARY SCIENCES Advanced Theory and Simulations Pub Date : 2024-09-10 DOI:10.1002/adts.202400252

Ingvild Bergsbak, Ørnulf Nordseth, Kjetil K. Saxegaard, Vegard S. Olsen, Holger von Wenckstern, Kristin Bergum

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In addition to its high mobility, <math altimg=\"urn:x-wiley:25130390:media:adts202400252:adts202400252-math-0003\" display=\"inline\" location=\"graphic/adts202400252-math-0003.png\">\n<semantics>\n<mrow>\n<msub>\n<mi>ZnO</mi>\n<mi>x</mi>\n</msub>\n<msub>\n<mi mathvariant=\"normal\">N</mi>\n<mi>y</mi>\n</msub>\n</mrow>\n${\\rm ZnO}_x{\\rm N}_y$</annotation>\n</semantics></math> can attain sufficiently low carrier concentration to enable <math altimg=\"urn:x-wiley:25130390:media:adts202400252:adts202400252-math-0004\" display=\"inline\" location=\"graphic/adts202400252-math-0004.png\">\n<semantics>\n<mrow>\n<mi>p</mi>\n<mi>n</mi>\n</mrow>\n$pn$</annotation>\n</semantics></math>-junctions, and has a tunable bandgap around the 1.7 eV range. It is therefore suitable for pairing with a Si-based bottom cell. In addition to the <math altimg=\"urn:x-wiley:25130390:media:adts202400252:adts202400252-math-0005\" display=\"inline\" location=\"graphic/adts202400252-math-0005.png\">\n<semantics>\n<mrow>\n<msub>\n<mi>ZnO</mi>\n<mi>x</mi>\n</msub>\n<msub>\n<mi mathvariant=\"normal\">N</mi>\n<mi>y</mi>\n</msub>\n</mrow>\n${\\rm ZnO}_x{\\rm N}_y$</annotation>\n</semantics></math> layer, the tandem cell consists of a <math altimg=\"urn:x-wiley:25130390:media:adts202400252:adts202400252-math-0006\" display=\"inline\" location=\"graphic/adts202400252-math-0006.png\">\n<semantics>\n<mrow>\n<msub>\n<mi>Cu</mi>\n<mn>2</mn>\n</msub>\n<mi mathvariant=\"normal\">O</mi>\n</mrow>\n${\\rm Cu}_2{\\rm O}$</annotation>\n</semantics></math> emitter and a Si heterojunction bottom cell. A buffer layer is introduced between the emitter and absorber in the top cell to mediate a large valence band offset that resulted in a poor fill factor, <math altimg=\"urn:x-wiley:25130390:media:adts202400252:adts202400252-math-0007\" display=\"inline\" location=\"graphic/adts202400252-math-0007.png\">\n<semantics>\n<mrow>\n<mi>F</mi>\n<mi>F</mi>\n</mrow>\n$FF$</annotation>\n</semantics></math>. A <math altimg=\"urn:x-wiley:25130390:media:adts202400252:adts202400252-math-0008\" display=\"inline\" location=\"graphic/adts202400252-math-0008.png\">\n<semantics>\n<mrow>\n<msub>\n<mi>ZnO</mi>\n<mi>x</mi>\n</msub>\n<msub>\n<mi mathvariant=\"normal\">N</mi>\n<mi>y</mi>\n</msub>\n</mrow>\n${\\rm ZnO}_x{\\rm N}_y$</annotation>\n</semantics></math> buffer layer bandgap of 1.5 eV gave the highest power conversion efficiency (PCE). The objective is to estimate the optimal performance of <math altimg=\"urn:x-wiley:25130390:media:adts202400252:adts202400252-math-0009\" display=\"inline\" location=\"graphic/adts202400252-math-0009.png\">\n<semantics>\n<mrow>\n<msub>\n<mi>ZnO</mi>\n<mi>x</mi>\n</msub>\n<msub>\n<mi mathvariant=\"normal\">N</mi>\n<mi>y</mi>\n</msub>\n</mrow>\n${\\rm ZnO}_x{\\rm N}_y$</annotation>\n</semantics></math> in a tandem solar cell. The dependence of current–voltage (<math altimg=\"urn:x-wiley:25130390:media:adts202400252:adts202400252-math-0010\" display=\"inline\" location=\"graphic/adts202400252-math-0010.png\">\n<semantics>\n<mi>J</mi>\n$J$</annotation>\n</semantics></math>–<math altimg=\"urn:x-wiley:25130390:media:adts202400252:adts202400252-math-0011\" display=\"inline\" location=\"graphic/adts202400252-math-0011.png\">\n<semantics>\n<mi>V</mi>\n$V$</annotation>\n</semantics></math>) characteristics on thickness, mobility and carrier concentration in the <math altimg=\"urn:x-wiley:25130390:media:adts202400252:adts202400252-math-0012\" display=\"inline\" location=\"graphic/adts202400252-math-0012.png\">\n<semantics>\n<mrow>\n<msub>\n<mi>ZnO</mi>\n<mi>x</mi>\n</msub>\n<msub>\n<mi mathvariant=\"normal\">N</mi>\n<mi>y</mi>\n</msub>\n</mrow>\n${\\rm ZnO}_x{\\rm N}_y$</annotation>\n</semantics></math> layer is evaluated, and found to yield maximum performance with 0.35 <math altimg=\"urn:x-wiley:25130390:media:adts202400252:adts202400252-math-0013\" display=\"inline\" location=\"graphic/adts202400252-math-0013.png\">\n<semantics>\n<mrow>\n<mi>μ</mi>\n<mi mathvariant=\"normal\">m</mi>\n</mrow>\n$\\umu {\\rm m}$</annotation>\n</semantics></math>, 250 <math altimg=\"urn:x-wiley:25130390:media:adts202400252:adts202400252-math-0014\" display=\"inline\" location=\"graphic/adts202400252-math-0014.png\">\n<semantics>\n<msup>\n<mi>cm</mi>\n<mn>2</mn>\n</msup>\n${\\rm cm}^2$</annotation>\n</semantics></math> Vs–1 and <math altimg=\"urn:x-wiley:25130390:media:adts202400252:adts202400252-math-0015\" display=\"inline\" location=\"graphic/adts202400252-math-0015.png\">\n<semantics>\n<msup>\n<mn>10</mn>\n<mn>16</mn>\n</msup>\n$10^{16}$</annotation>\n</semantics></math> <math altimg=\"urn:x-wiley:25130390:media:adts202400252:adts202400252-math-0016\" display=\"inline\" location=\"graphic/adts202400252-math-0016.png\">\n<semantics>\n<msup>\n<mi>cm</mi>\n<mrow>\n<mo>−</mo>\n<mn>3</mn>\n</mrow>\n</msup>\n${\\rm cm}^{-3}$</annotation>\n</semantics></math>, respectively. Using these conditions, the <math altimg=\"urn:x-wiley:25130390:media:adts202400252:adts202400252-math-0017\" display=\"inline\" location=\"graphic/adts202400252-math-0017.png\">\n<semantics>\n<mi>J</mi>\n$J$</annotation>\n</semantics></math>–<math altimg=\"urn:x-wiley:25130390:media:adts202400252:adts202400252-math-0018\" display=\"inline\" location=\"graphic/adts202400252-math-0018.png\">\n<semantics>\n<mi>V</mi>\n$V$</annotation>\n</semantics></math> parameters of the device under AM1.5 illumination are short circuit current density, <math altimg=\"urn:x-wiley:25130390:media:adts202400252:adts202400252-math-0019\" display=\"inline\" location=\"graphic/adts202400252-math-0019.png\">\n<semantics>\n<mrow>\n<msub>\n<mi>J</mi>\n<mrow>\n<mi>S</mi>\n<mi>C</mi>\n</mrow>\n</msub>\n<mo>=</mo>\n<mn>17.76</mn>\n</mrow>\n$J_{SC}=17.76$</annotation>\n</semantics></math> mA <math altimg=\"urn:x-wiley:25130390:media:adts202400252:adts202400252-math-0020\" display=\"inline\" location=\"graphic/adts202400252-math-0020.png\">\n<semantics>\n<msup>\n<mi>cm</mi>\n<mrow>\n<mo>−</mo>\n<mn>2</mn>\n</mrow>\n</msup>\n${\\mathrm{cm}}^{-2}$</annotation>\n</semantics></math>, open circuit voltage, <math altimg=\"urn:x-wiley:25130390:media:adts202400252:adts202400252-math-0021\" display=\"inline\" location=\"graphic/adts202400252-math-0021.png\">\n<semantics>\n<mrow>\n<msub>\n<mi>V</mi>\n<mrow>\n<mi>O</mi>\n<mi>C</mi>\n</mrow>\n</msub>\n<mo>=</mo>\n<mn>1.74</mn>\n</mrow>\n$V_{OC}=1.74$</annotation>\n</semantics></math> V, <math altimg=\"urn:x-wiley:25130390:media:adts202400252:adts202400252-math-0022\" display=\"inline\" location=\"graphic/adts202400252-math-0022.png\">\n<semantics>\n<mrow>\n<mi>F</mi>\n<mi>F</mi>\n<mo>=</mo>\n<mn>83.8</mn>\n<mo>%</mo>\n</mrow>\n$FF=83.8\\%$</annotation>\n</semantics></math> and <math altimg=\"urn:x-wiley:25130390:media:adts202400252:adts202400252-math-0023\" display=\"inline\" location=\"graphic/adts202400252-math-0023.png\">\n<semantics>\n<mrow>\n<mi>PCE</mi>\n<mspace width=\"0.16em\"></mspace>\n<mo>=</mo>\n<mn>25.9</mn>\n<mo>%</mo>\n</mrow>\n${\\rm PCE}\\,=25.9\\%$</annotation>\n</semantics></math>. With this, it is reported on, to the best of the knowledge, the first device simulation based on <math altimg=\"urn:x-wiley:25130390:media:adts202400252:adts202400252-math-0024\" display=\"inline\" location=\"graphic/adts202400252-math-0024.png\">\n<semantics>\n<mrow>\n<msub>\n<mi>ZnO</mi>\n<mi>x</mi>\n</msub>\n<msub>\n<mi mathvariant=\"normal\">N</mi>\n<mi>y</mi>\n</msub>\n</mrow>\n${\\rm ZnO}_x{\\rm N}_y$</annotation>\n</semantics></math>.","PeriodicalId":7219,"journal":{"name":"Advanced Theory and Simulations","volume":"9 1","pages":""},"PeriodicalIF":2.9000,"publicationDate":"2024-09-10","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":"{\"title\":\"Device Simulation of 25.9% Efficient ZnOxNy/Si Tandem Solar Cell\",\"authors\":\"Ingvild Bergsbak, Ørnulf Nordseth, Kjetil K. Saxegaard, Vegard S. Olsen, Holger von Wenckstern, Kristin Bergum\",\"doi\":\"10.1002/adts.202400252\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"The novel, high electron mobility material <math altimg=\\\"urn:x-wiley:25130390:media:adts202400252:adts202400252-math-0002\\\" display=\\\"inline\\\" location=\\\"graphic/adts202400252-math-0002.png\\\">\\n<semantics>\\n<mrow>\\n<msub>\\n<mi>ZnO</mi>\\n<mi>x</mi>\\n</msub>\\n<msub>\\n<mi mathvariant=\\\"normal\\\">N</mi>\\n<mi>y</mi>\\n</msub>\\n</mrow>\\n${\\\\rm ZnO}_x{\\\\rm N}_y$</annotation>\\n</semantics></math> has been investigated theoretically as an absorber in a two-terminal tandem solar cell. In addition to its high mobility, <math altimg=\\\"urn:x-wiley:25130390:media:adts202400252:adts202400252-math-0003\\\" display=\\\"inline\\\" location=\\\"graphic/adts202400252-math-0003.png\\\">\\n<semantics>\\n<mrow>\\n<msub>\\n<mi>ZnO</mi>\\n<mi>x</mi>\\n</msub>\\n<msub>\\n<mi mathvariant=\\\"normal\\\">N</mi>\\n<mi>y</mi>\\n</msub>\\n</mrow>\\n${\\\\rm ZnO}_x{\\\\rm N}_y$</annotation>\\n</semantics></math> can attain sufficiently low carrier concentration to enable <math altimg=\\\"urn:x-wiley:25130390:media:adts202400252:adts202400252-math-0004\\\" display=\\\"inline\\\" location=\\\"graphic/adts202400252-math-0004.png\\\">\\n<semantics>\\n<mrow>\\n<mi>p</mi>\\n<mi>n</mi>\\n</mrow>\\n$pn$</annotation>\\n</semantics></math>-junctions, and has a tunable bandgap around the 1.7 eV range. It is therefore suitable for pairing with a Si-based bottom cell. In addition to the <math altimg=\\\"urn:x-wiley:25130390:media:adts202400252:adts202400252-math-0005\\\" display=\\\"inline\\\" location=\\\"graphic/adts202400252-math-0005.png\\\">\\n<semantics>\\n<mrow>\\n<msub>\\n<mi>ZnO</mi>\\n<mi>x</mi>\\n</msub>\\n<msub>\\n<mi mathvariant=\\\"normal\\\">N</mi>\\n<mi>y</mi>\\n</msub>\\n</mrow>\\n${\\\\rm ZnO}_x{\\\\rm N}_y$</annotation>\\n</semantics></math> layer, the tandem cell consists of a <math altimg=\\\"urn:x-wiley:25130390:media:adts202400252:adts202400252-math-0006\\\" display=\\\"inline\\\" location=\\\"graphic/adts202400252-math-0006.png\\\">\\n<semantics>\\n<mrow>\\n<msub>\\n<mi>Cu</mi>\\n<mn>2</mn>\\n</msub>\\n<mi mathvariant=\\\"normal\\\">O</mi>\\n</mrow>\\n${\\\\rm Cu}_2{\\\\rm O}$</annotation>\\n</semantics></math> emitter and a Si heterojunction bottom cell. A buffer layer is introduced between the emitter and absorber in the top cell to mediate a large valence band offset that resulted in a poor fill factor, <math altimg=\\\"urn:x-wiley:25130390:media:adts202400252:adts202400252-math-0007\\\" display=\\\"inline\\\" location=\\\"graphic/adts202400252-math-0007.png\\\">\\n<semantics>\\n<mrow>\\n<mi>F</mi>\\n<mi>F</mi>\\n</mrow>\\n$FF$</annotation>\\n</semantics></math>. A <math altimg=\\\"urn:x-wiley:25130390:media:adts202400252:adts202400252-math-0008\\\" display=\\\"inline\\\" location=\\\"graphic/adts202400252-math-0008.png\\\">\\n<semantics>\\n<mrow>\\n<msub>\\n<mi>ZnO</mi>\\n<mi>x</mi>\\n</msub>\\n<msub>\\n<mi mathvariant=\\\"normal\\\">N</mi>\\n<mi>y</mi>\\n</msub>\\n</mrow>\\n${\\\\rm ZnO}_x{\\\\rm N}_y$</annotation>\\n</semantics></math> buffer layer bandgap of 1.5 eV gave the highest power conversion efficiency (PCE). The objective is to estimate the optimal performance of <math altimg=\\\"urn:x-wiley:25130390:media:adts202400252:adts202400252-math-0009\\\" display=\\\"inline\\\" location=\\\"graphic/adts202400252-math-0009.png\\\">\\n<semantics>\\n<mrow>\\n<msub>\\n<mi>ZnO</mi>\\n<mi>x</mi>\\n</msub>\\n<msub>\\n<mi mathvariant=\\\"normal\\\">N</mi>\\n<mi>y</mi>\\n</msub>\\n</mrow>\\n${\\\\rm ZnO}_x{\\\\rm N}_y$</annotation>\\n</semantics></math> in a tandem solar cell. The dependence of current–voltage (<math altimg=\\\"urn:x-wiley:25130390:media:adts202400252:adts202400252-math-0010\\\" display=\\\"inline\\\" location=\\\"graphic/adts202400252-math-0010.png\\\">\\n<semantics>\\n<mi>J</mi>\\n$J$</annotation>\\n</semantics></math>–<math altimg=\\\"urn:x-wiley:25130390:media:adts202400252:adts202400252-math-0011\\\" display=\\\"inline\\\" location=\\\"graphic/adts202400252-math-0011.png\\\">\\n<semantics>\\n<mi>V</mi>\\n$V$</annotation>\\n</semantics></math>) characteristics on thickness, mobility and carrier concentration in the <math altimg=\\\"urn:x-wiley:25130390:media:adts202400252:adts202400252-math-0012\\\" display=\\\"inline\\\" location=\\\"graphic/adts202400252-math-0012.png\\\">\\n<semantics>\\n<mrow>\\n<msub>\\n<mi>ZnO</mi>\\n<mi>x</mi>\\n</msub>\\n<msub>\\n<mi mathvariant=\\\"normal\\\">N</mi>\\n<mi>y</mi>\\n</msub>\\n</mrow>\\n${\\\\rm ZnO}_x{\\\\rm N}_y$</annotation>\\n</semantics></math> layer is evaluated, and found to yield maximum performance with 0.35 <math altimg=\\\"urn:x-wiley:25130390:media:adts202400252:adts202400252-math-0013\\\" display=\\\"inline\\\" location=\\\"graphic/adts202400252-math-0013.png\\\">\\n<semantics>\\n<mrow>\\n<mi>μ</mi>\\n<mi mathvariant=\\\"normal\\\">m</mi>\\n</mrow>\\n$\\\\umu {\\\\rm m}$</annotation>\\n</semantics></math>, 250 <math altimg=\\\"urn:x-wiley:25130390:media:adts202400252:adts202400252-math-0014\\\" display=\\\"inline\\\" location=\\\"graphic/adts202400252-math-0014.png\\\">\\n<semantics>\\n<msup>\\n<mi>cm</mi>\\n<mn>2</mn>\\n</msup>\\n${\\\\rm cm}^2$</annotation>\\n</semantics></math> Vs–1 and <math altimg=\\\"urn:x-wiley:25130390:media:adts202400252:adts202400252-math-0015\\\" display=\\\"inline\\\" location=\\\"graphic/adts202400252-math-0015.png\\\">\\n<semantics>\\n<msup>\\n<mn>10</mn>\\n<mn>16</mn>\\n</msup>\\n$10^{16}$</annotation>\\n</semantics></math> <math altimg=\\\"urn:x-wiley:25130390:media:adts202400252:adts202400252-math-0016\\\" display=\\\"inline\\\" location=\\\"graphic/adts202400252-math-0016.png\\\">\\n<semantics>\\n<msup>\\n<mi>cm</mi>\\n<mrow>\\n<mo>−</mo>\\n<mn>3</mn>\\n</mrow>\\n</msup>\\n${\\\\rm cm}^{-3}$</annotation>\\n</semantics></math>, respectively. Using these conditions, the <math altimg=\\\"urn:x-wiley:25130390:media:adts202400252:adts202400252-math-0017\\\" display=\\\"inline\\\" location=\\\"graphic/adts202400252-math-0017.png\\\">\\n<semantics>\\n<mi>J</mi>\\n$J$</annotation>\\n</semantics></math>–<math altimg=\\\"urn:x-wiley:25130390:media:adts202400252:adts202400252-math-0018\\\" display=\\\"inline\\\" location=\\\"graphic/adts202400252-math-0018.png\\\">\\n<semantics>\\n<mi>V</mi>\\n$V$</annotation>\\n</semantics></math> parameters of the device under AM1.5 illumination are short circuit current density, <math altimg=\\\"urn:x-wiley:25130390:media:adts202400252:adts202400252-math-0019\\\" display=\\\"inline\\\" location=\\\"graphic/adts202400252-math-0019.png\\\">\\n<semantics>\\n<mrow>\\n<msub>\\n<mi>J</mi>\\n<mrow>\\n<mi>S</mi>\\n<mi>C</mi>\\n</mrow>\\n</msub>\\n<mo>=</mo>\\n<mn>17.76</mn>\\n</mrow>\\n$J_{SC}=17.76$</annotation>\\n</semantics></math> mA <math altimg=\\\"urn:x-wiley:25130390:media:adts202400252:adts202400252-math-0020\\\" display=\\\"inline\\\" location=\\\"graphic/adts202400252-math-0020.png\\\">\\n<semantics>\\n<msup>\\n<mi>cm</mi>\\n<mrow>\\n<mo>−</mo>\\n<mn>2</mn>\\n</mrow>\\n</msup>\\n${\\\\mathrm{cm}}^{-2}$</annotation>\\n</semantics></math>, open circuit voltage, <math altimg=\\\"urn:x-wiley:25130390:media:adts202400252:adts202400252-math-0021\\\" display=\\\"inline\\\" location=\\\"graphic/adts202400252-math-0021.png\\\">\\n<semantics>\\n<mrow>\\n<msub>\\n<mi>V</mi>\\n<mrow>\\n<mi>O</mi>\\n<mi>C</mi>\\n</mrow>\\n</msub>\\n<mo>=</mo>\\n<mn>1.74</mn>\\n</mrow>\\n$V_{OC}=1.74$</annotation>\\n</semantics></math> V, <math altimg=\\\"urn:x-wiley:25130390:media:adts202400252:adts202400252-math-0022\\\" display=\\\"inline\\\" location=\\\"graphic/adts202400252-math-0022.png\\\">\\n<semantics>\\n<mrow>\\n<mi>F</mi>\\n<mi>F</mi>\\n<mo>=</mo>\\n<mn>83.8</mn>\\n<mo>%</mo>\\n</mrow>\\n$FF=83.8\\\\%$</annotation>\\n</semantics></math> and <math altimg=\\\"urn:x-wiley:25130390:media:adts202400252:adts202400252-math-0023\\\" display=\\\"inline\\\" location=\\\"graphic/adts202400252-math-0023.png\\\">\\n<semantics>\\n<mrow>\\n<mi>PCE</mi>\\n<mspace width=\\\"0.16em\\\"></mspace>\\n<mo>=</mo>\\n<mn>25.9</mn>\\n<mo>%</mo>\\n</mrow>\\n${\\\\rm PCE}\\\\,=25.9\\\\%$</annotation>\\n</semantics></math>. With this, it is reported on, to the best of the knowledge, the first device simulation based on <math altimg=\\\"urn:x-wiley:25130390:media:adts202400252:adts202400252-math-0024\\\" display=\\\"inline\\\" location=\\\"graphic/adts202400252-math-0024.png\\\">\\n<semantics>\\n<mrow>\\n<msub>\\n<mi>ZnO</mi>\\n<mi>x</mi>\\n</msub>\\n<msub>\\n<mi mathvariant=\\\"normal\\\">N</mi>\\n<mi>y</mi>\\n</msub>\\n</mrow>\\n${\\\\rm ZnO}_x{\\\\rm N}_y$</annotation>\\n</semantics></math>.\",\"PeriodicalId\":7219,\"journal\":{\"name\":\"Advanced Theory and Simulations\",\"volume\":\"9 1\",\"pages\":\"\"},\"PeriodicalIF\":2.9000,\"publicationDate\":\"2024-09-10\",\"publicationTypes\":\"Journal Article\",\"fieldsOfStudy\":null,\"isOpenAccess\":false,\"openAccessPdf\":\"\",\"citationCount\":\"0\",\"resultStr\":null,\"platform\":\"Semanticscholar\",\"paperid\":null,\"PeriodicalName\":\"Advanced Theory and Simulations\",\"FirstCategoryId\":\"5\",\"ListUrlMain\":\"https://doi.org/10.1002/adts.202400252\",\"RegionNum\":4,\"RegionCategory\":\"工程技术\",\"ArticlePicture\":[],\"TitleCN\":null,\"AbstractTextCN\":null,\"PMCID\":null,\"EPubDate\":\"\",\"PubModel\":\"\",\"JCR\":\"Q1\",\"JCRName\":\"MULTIDISCIPLINARY SCIENCES\",\"Score\":null,\"Total\":0}","platform":"Semanticscholar","paperid":null,"PeriodicalName":"Advanced Theory and Simulations","FirstCategoryId":"5","ListUrlMain":"https://doi.org/10.1002/adts.202400252","RegionNum":4,"RegionCategory":"工程技术","ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"Q1","JCRName":"MULTIDISCIPLINARY SCIENCES","Score":null,"Total":0}

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摘要

我们从理论上研究了新型高电子迁移率材料 ZnOxNy$\{rm ZnO}_x\{rm N}_y$，将其用作双端串联太阳能电池的吸收剂。除了高迁移率之外，ZnOxNy${rm ZnO}_x{rm N}_y$ 还能达到足够低的载流子浓度，从而实现 pn$pn$ 结，并且在 1.7 eV 范围内具有可调带隙。因此，它适合与硅基底部电池配对使用。除了 ZnOxNy${\rm ZnO}_x{\rm N}_y$ 层之外，串联电池还包括一个 Cu2O${\rm Cu}_2{\rm O}$ 发射器和一个硅异质结底部电池。在顶部电池的发射器和吸收器之间引入了缓冲层，以调节导致填充因子 FF$FF$ 较低的较大价带偏移。缓冲层带隙为 1.5 eV 的 ZnOxNy${rm ZnO}_x{rm N}_y$ 具有最高的功率转换效率 (PCE)。研究的目的是估算 ZnOxNy${rm ZnO}_x{rm N}_y$ 在串联太阳能电池中的最佳性能。评估了电流-电压（J$J$-V$V$）特性对 ZnOxNy${rm ZnO}_x{rm N}_y$ 层的厚度、迁移率和载流子浓度的依赖性，发现在 0.35 μm$umu {rm m}$、250 cm2${rm cm}^2$ Vs-1 和 1016$10^{16}$ cm-3${rm cm}^{-3}$条件下分别能产生最大性能。在这些条件下，该器件在 AM1.5 照明下的 J$J$-V$V$ 参数为：短路电流密度 JSC=17.76$J_{SC}=17.76$ mA cm-2$\{mathrm{cm}}^{-2}$；开路电压 VOC=1.74$V_{OC}=1.74$ V；FF=83.8%$FF=83.8/%$；PCE=25.9%${rm PCE}\,=25.9/%$。据悉，这是第一个基于 ZnOxNy${rm ZnO}_x{rm N}_y$ 的器件模拟。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Device Simulation of 25.9% Efficient ZnOxNy/Si Tandem Solar Cell

The novel, high electron mobility material

{ZnO}_{x} N_{y} ${\rm ZnO}_x{\rm N}_y$

has been investigated theoretically as an absorber in a two-terminal tandem solar cell. In addition to its high mobility,

{ZnO}_{x} N_{y} ${\rm ZnO}_x{\rm N}_y$

can attain sufficiently low carrier concentration to enable

p n $pn$

-junctions, and has a tunable bandgap around the 1.7 eV range. It is therefore suitable for pairing with a Si-based bottom cell. In addition to the

{ZnO}_{x} N_{y} ${\rm ZnO}_x{\rm N}_y$

layer, the tandem cell consists of a

{Cu}_{2} O ${\rm Cu}_2{\rm O}$

emitter and a Si heterojunction bottom cell. A buffer layer is introduced between the emitter and absorber in the top cell to mediate a large valence band offset that resulted in a poor fill factor,

F F $FF$

. A

{ZnO}_{x} N_{y} ${\rm ZnO}_x{\rm N}_y$

buffer layer bandgap of 1.5 eV gave the highest power conversion efficiency (PCE). The objective is to estimate the optimal performance of

{ZnO}_{x} N_{y} ${\rm ZnO}_x{\rm N}_y$

in a tandem solar cell. The dependence of current–voltage (

J $J$

–

V $V$

) characteristics on thickness, mobility and carrier concentration in the

{ZnO}_{x} N_{y} ${\rm ZnO}_x{\rm N}_y$

layer is evaluated, and found to yield maximum performance with 0.35

μ m $\umu {\rm m}$

, 250

{cm}^{2} ${\rm cm}^2$

Vs^–1 and

10^{16} $10^{16}$

{cm}^{- 3} ${\rm cm}^{-3}$

, respectively. Using these conditions, the

J $J$

–

V $V$

parameters of the device under AM1.5 illumination are short circuit current density,

J_{S C} = 17.76 $J_{SC}=17.76$

{cm}^{- 2} ${\mathrm{cm}}^{-2}$

, open circuit voltage,

V_{O C} = 1.74 $V_{OC}=1.74$

F F = 83.8 % $FF=83.8\%$

and

PCE = 25.9 % ${\rm PCE}\,=25.9\%$

. With this, it is reported on, to the best of the knowledge, the first device simulation based on

{ZnO}_{x} N_{y} ${\rm ZnO}_x{\rm N}_y$

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来源期刊

Advanced Theory and Simulations Multidisciplinary-Multidisciplinary

CiteScore

5.50

自引率

3.00%

发文量

221

期刊介绍： Advanced Theory and Simulations is an interdisciplinary, international, English-language journal that publishes high-quality scientific results focusing on the development and application of theoretical methods, modeling and simulation approaches in all natural science and medicine areas, including: materials, chemistry, condensed matter physics engineering, energy life science, biology, medicine atmospheric/environmental science, climate science planetary science, astronomy, cosmology method development, numerical methods, statistics