Photodissociation of (DMSO)2Fe(II)TPP, (TMSO)2Fe(II)TPP, and (PSO)2Fe(II)TPP to form a transient Five-Coordinate Complex as Studied Using Transient Resonance Raman Spectroscopy

Boone, Kenneth Patrick

January 2008

No description available.

Chemistry

resonance Raman

porphyrin

photolysis

Development of SERS for the determination of environmental pollutants

Carella, Yvonne

January 2003

No description available.

628

Development and application of a combined MAS-NMR/Raman spectroscopic probe for catalytic processes

Camp, Jules Colwyn Jack

January 2015

No description available.

660

In Situ Resonance Raman Studies of Molybdenum Oxide Based Selective

Dieterle, Martin, martin.dieterle@dieterle-wolfach.de, 1968-10-06, Alpirsbach

21 March 2001

No description available.

Relations Between Resonance Raman Spectra and The Second Order Optical Nonlinearity of Charge Transfer Chromophores

Hung, Sheng-Ting

10 July 2003

The linear absorption spectrum and resonance Raman spectrum of a series of charge-transfer molecules in solution are measured. The results are fitted to theoretical expressions. The dispersion of the first hyper-polarizability is investigated by substituting the parameters, which are obtained from the fit. The results are compared with Wang's formula modified from the simple Oudar and Chemla two-level model. The resonance Raman spectra and Raman profiles show that only one excited state exists in two of the charge-transfer molecules and two excited states are present in three other molecules investigated in this expeariment. It is concluded that Wang's modified formula is only valid to account for the dispersion of the first hyperpolarizability when there is only one excited vibronic state.

first hyperpolarizability

charge transfer

resonance Raman

Resonance Raman studies of isotopically labeled heme proteins

Rwere, Freeborn.

January 2009

Thesis (Ph. D.)--Marquette University, 2009. / James R. Kincaid, Daniel Sem, Michael D. Ryan, Advisors. Access available to Marquette University only.

Resonance Raman Investigations of [NiFe] Hydrogenase Models

Behnke, Shelby Lee

January 2016

No description available.

Chemistry

Resonance Raman

Spectroscopy

Hydrogenase

small molecules

SPECTROSCOPIC CHARACTERIZATIONS OF THE COMPOUND II INTERMEDIATE OF SOYBEAN PEROXIDASE FROM SOYBEAN SEED COATINGS

Agyepong, Andoh-Baidoo Rosemarie

30 April 2009

Spectroscopic characterization of ferric soybean peroxidase with peroxides were studied to determine the ligand coordination and to characterize the structure of the heme active site and its intermediates (ferryl species). The lifetime, chemical reactivity and distinctive colors of the ferryl species (FeIV) formed during the oxidation of peroxidase (FeIII) by peroxides enabled structure, dynamics and reaction mechanisms to be studied. Resonance Raman spectroscopy was used as a means of characterizing the structure of the soybean peroxidase and its intermediates. Excitation in the Soret absorption band at 406.7nm with 2-5mW laser power was used for this study. Resonance Raman spectra in the 200 to 1700 cm-1 region were obtained for the soybean peroxidase. However, the focus of this study was on the vibrational region of the resonance Raman spectra from 900 to 500cm-1 where the FeIV=O stretching frequencies for heme compound II intermediates are expected. Several pH and pD (deuterium substitution) samples of the soybean peroxidase were analyzed using resonance Raman spectroscopy. The vibrational stretching frequencies of the ferryl peroxidases varied with varying pH/pD were observed within the 773–787cm-1 range. From the deuterium experiment, accompanied with changes in the vibrational frequencies of the iron-ligand, a 3cm-1 upshift and intense resonant enhancement of the peaks, we observed the ferryl nature of compound II intermediate for soybean peroxidase. Badger’s rule was used to estimate the bond distances that existed within Fe-O which offers additional insight into the structure of the ferryl species. The estimated bond distance for the soybean peroxidase was significantly less than Fe-O bond distances proposed by X-ray crystallographers for other peroxidases in the same family. Comparing the vibrational frequencies of the ferryl intermediates in soybean peroxidase to that in heme proteins portrayed the effect the protein environment has on the vibrational frequencies.

Resonance Raman

Soybean Peroxidase

hemeproteins

peroxidases

Chemistry

Physical Sciences and Mathematics

Caracterização espectroscópica da tiossemicarbazona do formilferroceno (TFF) através das técnicas SERS (Surface-Enhanced Raman Scattering) e Raman ressonante / Spectroscopic characterization of formylferrocene thiosemicarbazone (TFF) by SERS (Surface-Enhanced Raman Scattering) and Resonance Raman techniques

Andrade, Gustavo Fernandes Souza

03 July 2003

Nesta dissertação o processo de adsorção da tiossemicarbazona do formilferroceno (TFF) em eletrodos de prata e ouro, em soluções aquosas 0,1 mol.L-1 de KCl e de acetonitrila. 0,1 mol.L-1 de NaClO4, foi caracterizado através da técnica espectroscópica SERS. Verificou-se através das variações espectrais que a adsorção da TFF ocorre através dos átomos N1 do grupo imínico e do S do grupo tiocarbonílico. Os processos faradáicos do TFF foram monitorados pela técnica SERS e de absorção no UV-visível. Os espectros SERS para potencial de -1,4 V (Ag/AgCl) sugerem a formação de um novo composto, produto de redução da TFF, o aminometilferroceno. Através da técnica de absorção no UV-visível verificou-se, neste potencial, o aparecimento no espectro de absorção de uma nova banda em 240 nm, atribuída à formação de tiouréia. A identificação deste dois produtos de redução indica que, para o composto TFF, o mecanismo geral de redução dos derivados de tiossemicarbazonas é obedecido. Nenhuma variação espectral, tanto utilizando a técnica SERS como a absorção no UV-visível, foi detectada durante o processo redox FeII/FeIII (E1/2=0,55 V). Os comportamentos de adsorção e faradáico da tiossemicarbazida (TSC), em eletrodo de prata em soluções aquosas neutra e ácida, foram estudados através da técnica SERS. Verificou-se que em meios neutro e ácido, a TSC está adsorvida na configuração cis para potenciais próximos de 0,0 V, interagindo com a superfície através do átomo de S do grupo tiocarbonílico e dos átomos de H ligados ao N1 hidrazínico, através da formação de pares iônicos com os ânions Cl- adsorvidos. Para potenciais mais negativos, os íons cloreto deixam a superfície e a TSC sofre reorientação, assumindo a conformação trans. Não foi observado através da técnica SERS nenhum processo faradáico em solução ácida para potenciais negativos, como havia sido proposto na literatura. A não redução do composto foi confirmada através da técnica de eletroforese capilar. Foi estudado o comportamento Raman ressonante da TFF, verificando-se a ocorrência de um mínimo no perfil de excitação experimental devido à interferência destrutiva das transições dos grupos tiossemicarbazona e ferrocenil. Os perfis de excitação teóricos foram calculados utilizando o método da transformada e os resultados dos ajustes obtidos indicam que existe considerável distorção dos modos do grupo ferrocenil na transição eletrônica em 312 nm, atribuída a n-p* do grupo tiossemicarbazona, caracterizando uma grande interação eletrônica entre os cromóforos da TFF. Para comparar o comportamento Raman ressonante do TFF com o do ferroceno, os espectros Raman ressonante deste composto foram obtidos. Verificou-se que o ferroceno apresenta, também, o efeito Raman anti-ressonante, mas as bandas vibracionais do ferroceno apresentam perfis distintos dos apresentados no composto TFF, indicando que a incorporação do grupo tiossemicarbazona no anel ciclopentadienil modifica a estrutura eletrônica do grupo ferrocenil. / In this dissertation, the adsorption process of the formylpyridine thiosemicarbazone (TFF) at silver and gold surfaces in aqueous and in acetonitrile solutions has been characterized by using the SERS (Surface-enhanced Raman Scattering) technique. It has been verified that TFF adsorbs through N1’ and S atoms on the metallic surfaces. The faradaic processes of TFF have been monitored through the SERS and UV-visible absorption spectroscopies. The SERS spectra at -1,4 V (Ag/AgCl) suggest aminomethylferrocene as one of the reduction products of TFF. By using the UV-visible absorption technique, it has been verified, at this potential, a new band at 240 nm in the spectrum, which indicates the presence of thiourea. The observation of these two reduction products has confirmed that the general reduction mechanism for thiosemicarbazonas works for TFF. Neither SERS nor UV-vis spectral changes have been observed during the redox process of FeII/FeIII (E1/2= 0,55 V). The adsorption and faradaic processes of thisemicarbazide (TSC) at silver electrode have also been studied by SERS technique. It has been verified that, in acidic and neutral media, the TSC is adsorbed through a cis-configuration at a potential close to 0,0 V, showing an interaction of the S atom through bond formation with the surface and through the H atoms bonded to N1 via ion pair formation with the adsorbed Cl- anions. At more negative potentials, the chloride anions leave the electrode surface and the TSC changes to trans-configuration. No faradaic process has been observed as reported in the literature. This result has been confirmed by using the capillary electrophoresis technique. The resonance Raman effect of the TFF has been studied, and the excitation profiles of the bands have been shown as minimum, which indicates an electronic interaction between the two cromophores of the TFF (thiosemicarbazone and ferrocenyl). The theoretic excitation profiles have been calculated by using the transform method, and the results of the obtained adjustment has indicated that there has been a distortion of the ferrocenyl vibrational modes for an electronic transition at 312 nm, assigned to the n-p* of thiosemicarbazone moiety. This result has indicated a great interaction between the two cromophores of TFF. In order to compare the resonance Raman behavior of the TFF with that of the ferrocene, the resonance Raman spectra of the ferrocene have been obtained. It has been verified that the two compounds present an anti-resonant Raman effect, even though the bands have presented very different excitation profiles from those observed in the TFF, which indicates that the incorporation of the thiosemicarbazone group into the ciclopentadienyl has changed the electronic structure of the ferrocenyl group.

ferrocene

ferroceno

Raman ressonante

resonance Raman

SERS

SERS

thiosemicarbazone

tiossemicarbazona

Subunit Disassembly of Human Hemoglobin and the Site-specific Roles of Its Cysteine Residues

Kan, Heng-I

28 July 2012

Hemoglobin plays an important role in transporting oxygen in human beings and other mammals. Hemoglobin is a tetrameric protein composed of two alpha and two beta subunits. The £\ and £] subunits are both necessary and the stoichiometric ratio of the two dislike subunits is critical for hemoglobin to perform its oxygen-carrying function properly. To better understand the coupling between the £\ and £] subunits and the subunit disassembly pathway, p-hydroxymercuri-benzoate (PMB) has been used to react with the cysteine residues in hemoglobin. The hemoglobin tetramer becomes unstable and disassembles into £\ and £] subunits when the cysteine sites are perturbed upon reacting with PMB. There are three kinds of cysteine residues, £]93, £\104 and £]112, in human hemoglobin. The reactivity of different cysteine residues with PMB and their reaction sequence have been studied via the Matrix-assisted laser desorption ionization time-of-flight mass spectrometry (MALDI-TOF MS). The resonance Raman spectroscopy has been used to investigate the structural changes of hemoglobin accompanying the PMB-modification under the oxygenated and deoxygenated conditions. At last, a hemoglobin subunit disassembly mechanism is proposed and the site-specific roles of cysteine residues in human hemoglobin are discussed in detail.

resonance Raman spectroscopy

MALDI-TOF MS

Cysteine

Hemoglobin

Subunit disassembly