국립중앙도서관 "우편 복사 서비스"로 연결 됩니다.
The rapid growth in the transparent electronics industry has increased the need for transparent photovoltaic cells (TPCs) and transparent self‐powered devices. To make TPCs and transparent self‐powered devices more efficient, a detailed understand...
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RISS 인기검색어
https://www.riss.kr/link?id=O111649359
- 저자
- 발행기관
- 학술지명
- 권호사항
-
발행연도
2021년
-
작성언어
-
-
Print ISSN
1062-7995
-
Online ISSN
1099-159X
-
등재정보
SCI;SCIE;SCOPUS
-
자료형태
학술저널
-
수록면
943-952 [※수록면이 p5 이하이면, Review, Columns, Editor's Note, Abstract 등일 경우가 있습니다.]
- 소장기관
-
구독기관
- 전북대학교 중앙도서관
- 성균관대학교 중앙학술정보관
- 부산대학교 중앙도서관
- 전남대학교 중앙도서관
- 제주대학교 중앙도서관
- 중앙대학교 서울캠퍼스 중앙도서관
- 인천대학교 학산도서관
- 숙명여자대학교 중앙도서관
- 서강대학교 로욜라중앙도서관
- 계명대학교 동산도서관
- 충남대학교 중앙도서관
- 한양대학교 백남학술정보관
- 이화여자대학교 중앙도서관
- 고려대학교 도서관
-
0
상세조회 -
0
다운로드
부가정보
다국어 초록 (Multilingual Abstract)
The rapid growth in the transparent electronics industry has increased the need for transparent photovoltaic cells (TPCs) and transparent self‐powered devices. To make TPCs and transparent self‐powered devices more efficient, a detailed understanding of device structure is needed. In this study, TiO2/NiO heterojunction‐based TPCs were fabricated with different TiO2 layer thicknesses, and the effect of TiO2 layer thickness on the photovoltage and photocurrent was evaluated. All the fabricated TiO2/NiO heterojunction‐based devices had a high optical transparency (>50%) in the visible–near‐infrared (vis–NIR) region. The fabricated devices were illuminated with different power sources of different wavelengths. If the TiO2 layer was too thick or too thin, the TPC performance deteriorated. By growing the optimal 100‐nm‐thick TiO2 layer, a simultaneous tunability between high optical transparency and high photovoltaic performance was achieved. A TiO2/NiO heterojunction‐based device with an optimal 100‐nm‐thick TiO2 layer had the highest optical transparency (>60%) in the vis–NIR region, with the highest photovoltage of 685.00 ± 68.06 mV and the highest photocurrent of 4.42 ± 1.35 mA under the illumination of a light source with a power density of 70 mW/cm2 at a wavelength of 365 nm. The fabricated TPCs had a high sensitivity to ultraviolet (UV) signals and demonstrated self‐powered behavior. This study clarified the role of TiO2 layer thickness optimization in improving the performance of TiO2/NiO heterojunction‐based TPCs.
Demonstration of an onsite running motor using two TiO2/NiO heterojunction‐based devices connected in parallel configuration to extract maximum photocurrent: Effect of thickness of the TiO2 absorber layer in TiO2/NiO heterojunction‐based transparent photovoltaic cell is studied. A tunability between optical transparency and performance of TiO2/NiO heterojunction‐based transparent photovoltaic is established. A successful operation of an onsite running motor is demonstrated exhibiting the simplest extraction and direct use of photogenerated power from the device.
Demonstration of an onsite running motor using two TiO2/NiO heterojunction‐based devices connected in parallel configuration to extract maximum photocurrent: Effect of thickness of the TiO2 absorber layer in TiO2/NiO heterojunction‐based transparent photovoltaic cell is studied. A tunability between optical transparency and performance of TiO2/NiO heterojunction‐based transparent photovoltaic is established. A successful operation of an onsite running motor is demonstrated exhibiting the simplest extraction and direct use of photogenerated power from the device.
The rapid growth in the transparent electronics industry has increased the need for transparent photovoltaic cells (TPCs) and transparent self‐powered devices. To make TPCs and transparent self‐powered devices more efficient, a detailed understanding of device structure is needed. In this study, TiO2/NiO heterojunction‐based TPCs were fabricated with different TiO2 layer thicknesses, and the effect of TiO2 layer thickness on the photovoltage and photocurrent was evaluated. All the fabricated TiO2/NiO heterojunction‐based devices had a high optical transparency (>50%) in the visible–near‐infrared (vis–NIR) region. The fabricated devices were illuminated with different power sources of different wavelengths. If the TiO2 layer was too thick or too thin, the TPC performance deteriorated. By growing the optimal 100‐nm‐thick TiO2 layer, a simultaneous tunability between high optical transparency and high photovoltaic performance was achieved. A TiO2/NiO heterojunction‐based device with an optimal 100‐nm‐thick TiO2 layer had the highest optical transparency (>60%) in the vis–NIR region, with the highest photovoltage of 685.00 ± 68.06 mV and the highest photocurrent of 4.42 ± 1.35 mA under the illumination of a light source with a power density of 70 mW/cm2 at a wavelength of 365 nm. The fabricated TPCs had a high sensitivity to ultraviolet (UV) signals and demonstrated self‐powered behavior. This study clarified the role of TiO2 layer thickness optimization in improving the performance of TiO2/NiO heterojunction‐based TPCs.
Demonstration of an onsite running motor using two TiO2/NiO heterojunction‐based devices connected in parallel configuration to extract maximum photocurrent: Effect of thickness of the TiO2 absorber layer in TiO2/NiO heterojunction‐based transparent photovoltaic cell is studied. A tunability between optical transparency and performance of TiO2/NiO heterojunction‐based transparent photovoltaic is established. A successful operation of an onsite running motor is demonstrated exhibiting the simplest extraction and direct use of photogenerated power from the device.
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