국립중앙도서관 "우편 복사 서비스"로 연결 됩니다.
Green plants and cyanobacteria possess the four manganese single calcium cluster necessary to oxidize water to O2. The photosynthetic process by which four flashes of light and two water molecules are transformed into O2 and a proton gradient is one ...
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RISS 인기검색어
https://www.riss.kr/link?id=T11763276
- 저자
-
발행사항
[S.l.]: Yale University 2008
-
학위수여대학
Yale University
-
수여연도
2008
-
작성언어
영어
- 주제어
-
학위
Ph.D.
-
페이지수
140 p.
-
지도교수/심사위원
Advisers: Gary W. Brudvig; Robert H. Crabtree.
-
0
상세조회 -
0
다운로드
소속기관이 구독 중이 아닌 경우 오후 4시부터 익일 오전 9시까지 원문보기가 가능합니다.
부가정보
다국어 초록 (Multilingual Abstract)
Green plants and cyanobacteria possess the four manganese single calcium cluster necessary to oxidize water to O2. The photosynthetic process by which four flashes of light and two water molecules are transformed into O2 and a proton gradient is one of the most interesting and challenging in nature. We, along with many others, work to better understand the first step in photosynthesis by mimicking it with small molecules.
We attempt to understand the mechanism for oxidizing water by single electron steps through the use of electrochemistry. This study has demonstrated the necessity of proton coupled electron transfer (PCET) in the mechanism of water oxidation as well as shown how the coordination of simple ligands can have a great effect upon the reduction potential of high valent intermediates. The electrochemical studies shown here will hopefully lead to the first catalytic oxidation of water with a manganese catalyst using one electron oxidants.
In this thesis, we also detail the development of TiO2 based photochemistry capable of oxidizing manganese complexes. Manganese model chemistry is very close to oxidizing water through discrete one electron steps, but to truly mimic the natural system, we must carry out oxidation with light. The new photochemical system shown in this thesis details the mechanism involved in oxidizing a manganese complex immobilized on a semiconductor surface using visible light.
We attempt to understand the mechanism for oxidizing water by single electron steps through the use of electrochemistry. This study has demonstrated the necessity of proton coupled electron transfer (PCET) in the mechanism of water oxidation as well as shown how the coordination of simple ligands can have a great effect upon the reduction potential of high valent intermediates. The electrochemical studies shown here will hopefully lead to the first catalytic oxidation of water with a manganese catalyst using one electron oxidants.
In this thesis, we also detail the development of TiO2 based photochemistry capable of oxidizing manganese complexes. Manganese model chemistry is very close to oxidizing water through discrete one electron steps, but to truly mimic the natural system, we must carry out oxidation with light. The new photochemical system shown in this thesis details the mechanism involved in oxidizing a manganese complex immobilized on a semiconductor surface using visible light.
Green plants and cyanobacteria possess the four manganese single calcium cluster necessary to oxidize water to O2. The photosynthetic process by which four flashes of light and two water molecules are transformed into O2 and a proton gradient is one of the most interesting and challenging in nature. We, along with many others, work to better understand the first step in photosynthesis by mimicking it with small molecules.
We attempt to understand the mechanism for oxidizing water by single electron steps through the use of electrochemistry. This study has demonstrated the necessity of proton coupled electron transfer (PCET) in the mechanism of water oxidation as well as shown how the coordination of simple ligands can have a great effect upon the reduction potential of high valent intermediates. The electrochemical studies shown here will hopefully lead to the first catalytic oxidation of water with a manganese catalyst using one electron oxidants.
In this thesis, we also detail the development of TiO2 based photochemistry capable of oxidizing manganese complexes. Manganese model chemistry is very close to oxidizing water through discrete one electron steps, but to truly mimic the natural system, we must carry out oxidation with light. The new photochemical system shown in this thesis details the mechanism involved in oxidizing a manganese complex immobilized on a semiconductor surface using visible light.
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