Influence of bridge‐state energy on the electron transfer relaxation and dephasing rate in a donor‐bridge‐acceptor system

Donor-π-Acceptor (D-π-A) porphyrin based photo-sensitizers are extensively utilized in dye sensitized solar cells (DSSCs). However, investigation on how the intramolecular photoinduced energy/electron transfer influences the device performance is still limited....

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Excited-state energy- and electron-transfer reactions in multimetal systems

Coordination Chemistry Reviews ◽

10.1016/0010-8545(91)84037-6 ◽

1991 ◽

Vol 111 ◽

pp. 319-324 ◽

Cited By ~ 12

Author(s):

John D. Petersen ◽

Larry W. Morgan ◽

Iyun Hsu ◽

Mark A. Billadeau ◽

Silvia E. Ronco

Keyword(s):

Electron Transfer ◽

Excited State ◽

State Energy ◽

Transfer Reactions ◽

Excited State Energy ◽

Electron Transfer Reactions ◽

Energy And Electron Transfer

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Near-infrared-induced electron transfer of an uranyl macrocyclic complex without energy transfer to dioxygen

Chemical Communications ◽

10.1039/c5cc00903k ◽

2015 ◽

Vol 51 (31) ◽

pp. 6757-6760 ◽

Cited By ~ 12

Author(s):

Christina M. Davis ◽

Kei Ohkubo ◽

I-Ting Ho ◽

Zhan Zhang ◽

Masatoshi Ishida ◽

...

Keyword(s):

Electron Transfer ◽

Energy Transfer ◽

Excited State ◽

Near Infrared ◽

State Energy ◽

Macrocyclic Complex ◽

Triplet Excited State ◽

Excited State Energy

An uranyl macrocyclic complex acts as an NIR-absorbing photosensitiser with a low triplet excited state energy, undergoing NIR-induced electron transfer.

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A light optical diffractometer for electron microscopical images operating in line

Proceedings, annual meeting, Electron Microscopy Society of America ◽

10.1017/s0424820100107575 ◽

1978 ◽

Vol 36 (1) ◽

pp. 86-87

Author(s):

P. Bonhomme ◽

A. Beorchia

Keyword(s):

Electron Microscopy ◽

Electron Transfer ◽

Electron Microscope ◽

Image Converter ◽

Coherent Light ◽

Spatial Filters ◽

Electron Image ◽

Electron Microscopical ◽

Working Parameters ◽

Amorphous Part

We have already described (1.2.3) a device using a pockel's effect light valve as a microscopical electron image converter. This converter can be read out with incoherent or coherent light. In the last case we can set in line with the converter an optical diffractometer. Now, electron microscopy developments have pointed out different advantages of diffractometry. Indeed diffractogram of an image of a thin amorphous part of a specimen gives information about electron transfer function and a single look at a diffractogram informs on focus, drift, residual astigmatism, and after standardizing, on periods resolved (4.5.6). These informations are obvious from diffractogram but are usualy obtained from a micrograph, so that a correction of electron microscope parameters cannot be realized before recording the micrograph. Diffractometer allows also processing of images by setting spatial filters in diffractogram plane (7) or by reconstruction of Fraunhofer image (8). Using Electrotitus read out with coherent light and fitted to a diffractometer; all these possibilities may be realized in pseudoreal time, so that working parameters may be optimally adjusted before recording a micrograph or before processing an image.

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Electron energy-loss near-edge structure in silicate minerals

Proceedings, annual meeting, Electron Microscopy Society of America ◽

10.1017/s0424820100130924 ◽

1992 ◽

Vol 50 (2) ◽

pp. 1258-1259

Author(s):

D W McComb ◽

R S Payne ◽

P L Hansen ◽

R Brydson

Keyword(s):

Solid State ◽

Energy Loss ◽

Electron Energy ◽

State Energy ◽

Local Environment ◽

Edge Structure ◽

Silicate Minerals ◽

Two Samples ◽

Electron Energy Loss ◽

Careful Processing

Electron energy-loss near-edge structure (ELNES) is an effective probe of the local geometrical and electronic environment around particular atomic species in the solid state. Energy-loss spectra from several silicate minerals were mostly acquired using a VG HB501 STEM fitted with a parallel detector. Typically a collection angle of ≈8mrad was used, and an energy resolution of ≈0.5eV was achieved.Other authors have indicated that the ELNES of the Si L2,3-edge in α-quartz is dominated by the local environment of the silicon atom i.e. the SiO4 tetrahedron. On this basis, and from results on other minerals, the concept of a coordination fingerprint for certain atoms in minerals has been proposed. The concept is useful in some cases, illustrated here using results from a study of the Al2SiO5 polymorphs (Fig.l). The Al L2,3-edge of kyanite, which contains only 6-coordinate Al, is easily distinguished from andalusite (5- & 6-coordinate Al) and sillimanite (4- & 6-coordinate Al). At the Al K-edge even the latter two samples exhibit differences; with careful processing, the fingerprint for 4-, 5- and 6-coordinate aluminium may be obtained.

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Proton-Coupled Electron Transfer

10.1039/9781849733168 ◽

2011 ◽

Cited By ~ 2

Keyword(s):

Electron Transfer ◽

Proton Coupled Electron Transfer

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