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Gallagher LA Serron SA Wen X Hornstein BJ Dattelbaum DM Schoonover JR Meyer TJ 《Inorganic chemistry》2005,44(6):2089-2097
Photocurrent measurements have been made on nanocrystalline TiO2 surfaces derivatized by adsorption of a catalyst precursor, [Ru(tpy)(bpy(PO3H2)2)(OH2)]2+, or chromophore, [Ru(bpy)2 (bpy(PO3H2)2)]2+ (tpy is 2,2':6',2' '-terpyridine, bpy is 2,2'-bipyridine, and bpy(PO3H2)2 is 2,2'-bipyridyl-4,4'-diphosphonic acid), and on surfaces containing both complexes. This is an extension of earlier work on an adsorbed assembly containing both catalyst and chromophore. The experiments were carried out with the I3-/I- or quinone/hydroquinone (Q/H2Q) relays in propylene carbonate, propylene carbonate-water mixtures, and acetonitrile-water mixtures. Electrochemical measurements show that oxidation of surface-bound Ru(III)-OH2(3+) to Ru(IV)=O(2+) is catalyzed by the bpy complex. Addition of aqueous 0.1 M HClO4 greatly decreases photocurrent efficiencies for adsorbed [Ru(tpy)(bpy(PO3H2)2)(OH2)]2+ with the I3-/I- relay, but efficiencies are enhanced for the Q/H2Q relay in both propylene carbonate-HClO4 and acetonitrile-HClO4 mixtures. The dependence of the incident photon-to-current efficiency (IPCE) on added H2Q in 95% propylene carbonate and 5% 0.1 M HClO4 is complex and can be interpreted as changing from rate-limiting diffusion to the film at low H2Q to rate-limiting diffusion within the film at high H2Q. There is no evidence for photoelectrochemical cooperativity on mixed surfaces containing both complexes with the IPCE response reflecting the relative surface compositions of the two complexes. These results provide insight into the possible design of photoelectrochemical synthesis cells for the oxidation of organic substrates. 相似文献
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Infrared data in the nu(CO) region (1800-2150 cm(-1), in acetonitrile at 298 K) are reported for the ground (nu(gs)) and polypyridyl-based, metal-to-ligand charge-transfer (MLCT) excited (nu(es)) states of cis-[Os(pp)2(CO)(L)](n)(+) (pp = 1,10-phenanthroline (phen) or 2,2'-bipyridine (bpy); L = PPh3, CH(3)CN, pyridine, Cl, or H) and fac-[Re(pp)(CO)3(4-Etpy)](+) (pp = phen, bpy, 4,4'-(CH3)2bpy, 4,4'-(CH3O)2bpy, or 4,4'-(CO2Et)2bpy; 4-Etpy = 4-ethylpyridine). Systematic variations in nu(gs), nu(es), and Delta(nu) (Delta(nu) = nu(es) - nu(gs)) are observed with the excited-to-ground-state energy gap (E(0)) derived by a Franck-Condon analysis of emission spectra. These variations can be explained qualitatively by invoking a series of electronic interactions. Variations in dpi(M)-pi(CO) back-bonding are important in the ground state. In the excited state, the important interactions are (1) loss of back-bonding and sigma(M-CO) bond polarization, (2) pi(pp*-)-pi(CO) mixing, which provides the orbital basis for mixing pi(CO)- and pi(4,4'-X(2)bpy)-based MLCT excited states, and (3) dpi(M)-pi(pp) mixing, which provides the orbital basis for mixing pipi- and pi(4,4'-X(2)bpy*-)-based MLCT states. The results of density functional theory (DFT) calculations on the ground and excited states of fac-[Re(I)(bpy)(CO)3(4-Etpy)](+) provide assignments for the nu(CO) modes in the MLCT excited state. They also support the importance of pi(4,4'-X2bpy*-)-pi(CO) mixing, provide an explanation for the relative intensities of the A'(2) and A' ' excited-state bands, and provide an explanation for the large excited-to-ground-state nu(CO) shift for the A'(2) mode and its relative insensitivity to variations in X. 相似文献
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Orange crystals of Cs(4)Th(4)P(4)Se(26) were grown from the reaction of (232)Th and P in a Cs(2)Se(3)/Se molten salt flux at 750 degrees C. Cs(4)Th(4)P(4)Se(26) crystallizes in the orthorhombic space group Pbca with the unit cell parameters: a = 12.0130(6), b = 14.5747(7), c = 27.134(1) A; Z = 8. The compound exhibits a three-dimensional structure, consisting of dimeric [Th(2)Se(13)] polyhedral units. The two crystallographically independent, nine-coordinate, bicapped trigonal prismatic thorium atoms share a triangular face to form the dimer, and each dimer edge-shares two selenium atoms with two other dimers to form kinked chains along the [010] direction. While this structure shares features of the previously reported Rb(4)U(4)P(4)Se(26), including phosphorus in the 5+ oxidation state, careful inspection of the structure reveals that the selenophosphate anion that knits the structure together in three directions in both compounds is a unique (P(2)Se(9))(6-) anion. The formula may be described best as [Cs(2)Th(2)(P(2)Se(9))(Se(2))(2)](2). The (P(2)Se(9))(6-) anion features a nearly linear Se-Se-Se backbone with an angle of 171 degrees and Se-Se distances that are approximately 0.2-0.3 A longer than the typical single Se-Se bond. Magnetic studies confirm that this phase contains Th(IV). Raman data for this compound is reported, and structural comparisons will be drawn to its uranium analogue, Rb(4)U(4)P(4)Se(26). 相似文献
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Schoonover JR Dattelbaum DM Osborn JC Bridgewater JS Kenney JW 《Spectrochimica acta. Part A, Molecular and biomolecular spectroscopy》2003,59(2):309-319
The effects of hydrostatic pressure upon (1) a segmented poly (ester urethane), (2) a hydrolytically degraded sample of the same polymer, and (3) models for the polyurethane and polyester segments in this polymer have been studied by Fourier transform infrared spectroscopy using high-pressure diamond anvil cells (DACs). The pressure responses of the vibrational frequencies of specific functional groups of the poly (ester urethane) in the 0-100-kbar range are compared with data for individual segment models and the partially degraded sample. The results indicated that the polymer is highly stable in this pressure regime, with no measurable degradation or phase changes. Differences in the pressure dependency of specific infrared bands between the poly (ester urethane) sample and the partially degraded sample are slight and consistent with changes in hydrogen-bonding interactions and shorter chain lengths in the degraded sample. 相似文献
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W. Hiltner H. A. Freye R. J. Fosbinder J. W. Schoonover M. Kilpatrick E. F. Chase L. C. Riesch A. Janke F. Sekera G. F. Davidson J. O. Burton H. Matheson S. F. Acree G. Haugaard F. L. Vodret F. Hovorka W. C. Dearing T. Mikawa E. Newbery A. Itano S. Arakawa T. R. Ball W. B. Schmidt K. S. Bergstresser E. Vellinger A. E. Lorch F. Lux W. von Brehmer M. Déribéré A. F. Peters und A. Osol 《Fresenius' Journal of Analytical Chemistry》1935,103(7-8):285-292
Ohne Zusammenfassung 相似文献
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Excess tosyl chloride used in the tosylation of alcohols is quickly and easily removed by reacting it with cellulosic materials, e.g., filter paper, and filtering. 相似文献
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R. C. Wiley I. P. Bewley R. Irey I. C. Schoonover N. H. Furman Erich Müller D. Junck B. S. Evans S. G. Clarke M. Fitz Gibbon J. Stalé H. Koelsch und Z. Rabinowitsch 《Fresenius' Journal of Analytical Chemistry》1934,99(1-2):50-56
Ohne Zusammenfassung 相似文献
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Open-framework materials synthesized in the TMA+/TEA+ mixed-template system: the new low Si/Al ratio zeolites UZM-4 and UZM-5. 总被引:1,自引:0,他引:1
C Scott Blackwell Robert W Broach Michael G Gatter Jennifer S Holmgren Deng-Yang Jan Gregory J Lewis Beckay J Mezza Thomas M Mezza Mark A Miller Jaime G Moscoso R Lyle Patton Lisa M Rohde Michael W Schoonover Wharton Sinkler Ben A Wilson Stephen T Wilson 《Angewandte Chemie (International ed. in English)》2003,42(15):1737-1740
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Harry W. Gibson Zhenbin Niu Minjae Lee Terry L. Price Daniel V. Schoonover Michael A.G. Berg 《Tetrahedron letters》2018,59(11):1055-1058
Reaction of isoquinoline Reissert compound 1 with NaH and then isopropyl iodide in DMF at 22?°C led to four isolated products. Ketone 3 is the expected product of the well-known rearrangement of the intermediate Reissert anion. Cyano lactam 4 results from SNAr intramolecular displacement of the fluoride ion from the activated aroyl moiety of the anion. Isopropyl lactam 5 is proposed to result from a SET (single electron transfer) process via formation of the radical anion of 4, subsequent loss of the cyanide ion, and coupling of the resultant radical with isopropyl radicals formed via copper used to “stabilize” the alkyl iodide. The expected alkylated product 2 is also formed via a SET process involving electron transfer from the Reissert anion to 4, leading to the Reissert radical. Use of “non-stabilized” bromide or iodide led to 3 and 4, but did not produce 2 or 5. 相似文献