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Evaluation of a betavoltaic energy converter supporting scalable modular structure
Distinct from conventional energy‐harvesting (EH) technologies, such as the use of photovoltaic, piezoelectric, and thermoelectric effects, betavoltaic energy conversion can consistently generate uniform electric power, independent of environmental variations, and provide a constant output of high D...
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| Published in: | ETRI journal 2019, 41(2), , pp.254-261 |
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| Main Authors: | , , , , , , , |
| Format: | Article |
| Language: | English |
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| cited_by | cdi_FETCH-LOGICAL-c4290-18ab65f7674ffa29e70bfd18de48f8ecc337657e211254a7ab76acbb76b5d70c3 |
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| cites | cdi_FETCH-LOGICAL-c4290-18ab65f7674ffa29e70bfd18de48f8ecc337657e211254a7ab76acbb76b5d70c3 |
| container_end_page | 261 |
| container_issue | 2 |
| container_start_page | 254 |
| container_title | ETRI journal |
| container_volume | 41 |
| creator | Kang, Taewook Kim, Jinjoo Park, Seongmo Son, Kwangjae Park, Kyunghwan Lee, Jaejin Kang, Sungweon Choi, Byoung‐Gun |
| description | Distinct from conventional energy‐harvesting (EH) technologies, such as the use of photovoltaic, piezoelectric, and thermoelectric effects, betavoltaic energy conversion can consistently generate uniform electric power, independent of environmental variations, and provide a constant output of high DC voltage, even under conditions of ultra‐low‐power EH. It can also dramatically reduce the energy loss incurred in the processes of voltage boosting and regulation. This study realized betavoltaic cells comprised of p‐i‐n junctions based on silicon carbide, fabricated through a customized semiconductor recipe, and a Ni foil plated with a Ni‐63 radioisotope. The betavoltaic energy converter (BEC) includes an array of 16 parallel‐connected betavoltaic cells. Experimental results demonstrate that the series and parallel connections of two BECs result in an open‐circuit voltage Voc of 3.06 V with a short‐circuit current Isc of 48.5 nA, and a Voc of 1.50 V with an Isc of 92.6 nA, respectively. The capacitor charging efficiency in terms of the current generated from the two series‐connected BECs was measured to be approximately 90.7%. |
| doi_str_mv | 10.4218/etrij.2018-0022 |
| format | article |
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It can also dramatically reduce the energy loss incurred in the processes of voltage boosting and regulation. This study realized betavoltaic cells comprised of p‐i‐n junctions based on silicon carbide, fabricated through a customized semiconductor recipe, and a Ni foil plated with a Ni‐63 radioisotope. The betavoltaic energy converter (BEC) includes an array of 16 parallel‐connected betavoltaic cells. Experimental results demonstrate that the series and parallel connections of two BECs result in an open‐circuit voltage Voc of 3.06 V with a short‐circuit current Isc of 48.5 nA, and a Voc of 1.50 V with an Isc of 92.6 nA, respectively. 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It can also dramatically reduce the energy loss incurred in the processes of voltage boosting and regulation. This study realized betavoltaic cells comprised of p‐i‐n junctions based on silicon carbide, fabricated through a customized semiconductor recipe, and a Ni foil plated with a Ni‐63 radioisotope. The betavoltaic energy converter (BEC) includes an array of 16 parallel‐connected betavoltaic cells. Experimental results demonstrate that the series and parallel connections of two BECs result in an open‐circuit voltage Voc of 3.06 V with a short‐circuit current Isc of 48.5 nA, and a Voc of 1.50 V with an Isc of 92.6 nA, respectively. 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It can also dramatically reduce the energy loss incurred in the processes of voltage boosting and regulation. This study realized betavoltaic cells comprised of p‐i‐n junctions based on silicon carbide, fabricated through a customized semiconductor recipe, and a Ni foil plated with a Ni‐63 radioisotope. The betavoltaic energy converter (BEC) includes an array of 16 parallel‐connected betavoltaic cells. Experimental results demonstrate that the series and parallel connections of two BECs result in an open‐circuit voltage Voc of 3.06 V with a short‐circuit current Isc of 48.5 nA, and a Voc of 1.50 V with an Isc of 92.6 nA, respectively. The capacitor charging efficiency in terms of the current generated from the two series‐connected BECs was measured to be approximately 90.7%.</abstract><pub>Electronics and Telecommunications Research Institute (ETRI)</pub><doi>10.4218/etrij.2018-0022</doi><tpages>8</tpages><orcidid>https://orcid.org/0000-0001-9147-3898</orcidid><oa>free_for_read</oa></addata></record> |
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| ispartof | ETRI Journal, 2019, 41(2), , pp.254-261 |
| issn | 1225-6463 2233-7326 |
| language | eng |
| recordid | cdi_nrf_kci_oai_kci_go_kr_ARTI_4856931 |
| source | Alma/SFX Local Collection |
| subjects | beta ray betavoltaic cell betavoltaic device betavoltaic energy conversion energy harvesting 전자/정보통신공학 |
| title | Evaluation of a betavoltaic energy converter supporting scalable modular structure |
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