Optical Spectral Features Research Articles

Chips off of Asteroid 4 Vesta: Evidence for the Parent Body of Basaltic Achondrite Meteorites

For more than two decades, asteroid 4 Vesta has been debated as the source for the eucrite, diogenite, and howardite classes of basaltic achondrite meteorites. Its basaltic achondrite spectral properties are unlike those of other large main-belt asteroids. Telescopic measurements have revealed 20 small (diameters </= 10 kilometers) main-belt asteroids that have distinctive optical reflectance spectral features similar to those of Vesta and eucrite and diogenite meteorites. Twelve have orbits that are similar to Vesta's and were previously predicted to be dynamically associated with Vesta. Eight bridge the orbital space between Vesta and the 3:1 resonance, a proposed source region for meteorites. These asteroids are most probably multikilometer-sized fragments excavated from Vesta through one or more impacts. The sizes, ejection velocities of 500 meters per second, and proximity of these fragments to the 3:1 resonance establish Vesta as a dynamically viable source for eucrite, diogenite, and howardite meteorites.

IRAS 03202-5150 - A new ring active galactic nucleus with obscured Seyfert 1 nucleus

view Abstract Citations (4) References (106) Co-Reads Similar Papers Volume Content Graphics Metrics Export Citation NASA/ADS IRAS 03202-5150: A New Ring Active Galactic Nucleus with Obscured Seyfert 1 Nucleus Lipari, Sebastian ; Macchetto, F. Abstract Aperture spectroscopy and deep-CCD broad- and narrow-band images are presented for the new narrow-line Seyfert 1/Ring AGN: IRAS 03202-5150. Far-IR data are also used to analyze this object. Physical conditions are derived for the emission-line regions. We find optical spectral features characteristic of narrow-line Seyfert 1 AGNs, very similar to a prototype of this object: Mrk 359. We detect high-excitation emission lines (especially strong (Fe VII] λ6087 emission) and also broad faint Hα emission. The broad- band CCD imaging shows an outer ring, bar, and several possible companions. We detect several knots in the ring, and the two principal knots are located approximately in opposition and at the same distance from the nucleus. The narrow-band imaging shows that the nuclear Hα + [N II] emission is elongated mainly in the north direction. In the far-IR, we find very similar luminosities at 25 and 60 microns [very flat spectral index α(60, 25)], typical of the nonthermal emission of Seyfert 1/QSOs. The characteristics of this AGN are also compared with other ring and narrow-line Seyfert 1 AGNs. It is proposed that obscuration of the Seyfert 1 nucleus can explain the observed optical and far-IR properties of IRAS 03202-5150; and that internal forces (orbital resonances due to central bar and/or oval distortion) probably caused the ring. Publication: The Astrophysical Journal Pub Date: September 1992 DOI: 10.1086/171771 Bibcode: 1992ApJ...397..126L Keywords: Active Galactic Nuclei; Astronomical Spectroscopy; Charge Coupled Devices; Infrared Astronomy Satellite; Seyfert Galaxies; Emission Spectra; Far Infrared Radiation; H Alpha Line; Orbital Resonances (Celestial Mechanics); Astrophysics; GALAXIES: ACTIVE; GALAXIES: INDIVIDUAL ALPHANUMERIC: IRAS 03202-5150; GALAXIES: NUCLEI; GALAXIES: SEYFERT full text sources ADS | data products SIMBAD (16) NED (1)

Alteration of sperm whale myoglobin heme axial ligation by site-directed mutagenesis

Three mutant proteins of sperm whale myoglobin (Mb) that exhibit altered axial ligations were constructed by site-directed mutagenesis of a synthetic gene for sperm whale myoglobin. Substitution of distal pocket residues, histidine E7 and valine E11, with tyrosine and glutamic acid generated His(E7)Tyr Mb and Val(E11)Glu Mb. The normal axial ligand residue, histidine F8, was also replaced with tyrosine, resulting in His(F8)Tyr Mb. These proteins are analogous in their substitutions to the naturally occurring hemoglobin M mutants (HbM). Tyrosine coordination to the ferric heme iron of His(E7)Tyr Mb and His(F8)Tyr Mb is suggested by optical absorption and EPR spectra and is verified by similarities to resonance Raman spectral bands assigned for iron-tyrosine proteins. His(E7)Tyr Mb is high-spin, six-coordinate with the ferric heme iron coordinated to the distal tyrosine and the proximal histidine, resembling Hb M Saskatoon [His(beta E7)Tyr], while the ferrous iron of this Mb mutant is high-spin, five-coordinate with ligation provided by the proximal histidine. His(F8)Tyr Mb is high-spin, five-coordinate in both the oxidized and reduced states, with the ferric heme iron liganded to the proximal tyrosine, resembling Hb M Iwate [His(alpha F8)Tyr] and Hb M Hyde Park [His(beta F8)Tyr]. Val(E11)Glu Mb is high-spin, six-coordinate with the ferric heme iron liganded to the F8 histidine. Glutamate coordination to the ferric iron of this mutant is strongly suggested by the optical and EPR spectral features, which are consistent with those observed for Hb M Milwaukee [Val(beta E11)Glu]. The ferrous iron of Val(E11)Glu Mb exhibits a five-coordinate structure with the F8 histidine-iron bond intact.(ABSTRACT TRUNCATED AT 250 WORDS)

Synthesis and Structure of Ferrocene-Linked Schiff Base Porphyrins

Abstract A series of mono ferrocene Schiff-base porphyrins in which the ferrocene unit is disposed in different orientations to the porphyrin core have been synthesized from meso-5(o or p)aminophenyl-10, 15, 20-triphenyl-21,23-H-porphyrin and ferrocenealdehyde. The optical and magnetic resonance spectral features of these derivatives reveal weak interactions between ferrocene and porphyrin units. The kinetics of metal incorporation into the free-base ferrocenyl porphyrins indicate the steric features induced by the ferrocene unit. Electrochemical redox behaviour of the compounds shows that the ferrocene and porphyrin entities behave as independent units. Steady-state photolysis experiments reveal no internal electron-transfer, although the energies of the CT state of porphyrin-ferricenium ion indicate the feasibility of electron transfer in these systems.

A tyrosine-derived free radical in apogalactose oxidase.

Oxidation of apogalactose oxidase with ferricyanide leads to the formation of a stable free radical exhibiting distinctive optical absorption and EPR spectral features. The radical is associated with absorption in both near-UV and near-IR spectral regions, and its EPR spectrum is characteristic of an aromatic free radical with gav = 2.005. Reconstitution of both the apoenzyme and the free radical-containing form with copper substantially restores both the absorption spectra and the catalytic activity of the active enzyme, indicating that the preparation of the radical species does not significantly damage the protein. The absence of a free radical EPR signal in reconstituted and activated galactose oxidase containing nearly stoichiometric copper suggests the radical is an active site species relating to the free radical-coupled copper site previously proposed for this enzyme. Isotopic labeling experiments demonstrate that the radical derives from a tyrosine residue. The distinctive spectra associated with this radical indicate an environment which is different from that associated with the tyrosyl phenoxyl sites in other free radical enzymes.

Synthesis, spectral study and thermal behaviour of some 4-(O-acetyl)-glycopyranosylamino-5-nitrosopyrimidine derivatives

The syntheses, specific optical rotations, spectral features (1H-NMR, UV-visible and IR spectroscopy) and thermal characterization of seven 4-(O-acetyl)-glycopyranosylamino-5-nitrosopyrimidine derivatives are reported. With IR spectroscopy, the starting of the pyrolytic decomposition mechanism of the compounds was established.

The absence of apparent correlations between iras and optical spectral features of late-type stars

The spectral signatures of circumstellar dust shells (CS) of late-type stars cannot be tied in a simple manner to their optical spectral features. The spectral indices of featureless low-resolution spectrometer (LRS) spectra of K and early-M (M0-M5) stars are consistent with that of the Rayleigh-Jeans law and those of late-M (M6 and later) stars tend to have lower values showing CS radiation. There is no correlation observed between the optical sub-type and the 10 μm emission strength for M stars. The absence of a simple relationship is also evident for C stars where the temperature and abundance indices show no correlation with the 11 μm emission strength. The sample is confined to the IRC stars identified with accurate spectra observed by the LRS of IRAS. The IRC stars are the whole sky survey done with the 2 μm band, where late-type stars are bright and interstellar extinction is one-tenth of the visual colour band.

Future optical observations of solar flares

The fundamental importance of observing the chromospheric and photospheric components of solar flares is stressed. Careful interpretation of several optical flare spectral features enable us to disentangle the various proposed energy transfer mechanisms during the different phases of the flare development. We can infer information on the primary flare physical processes and on the physical conditions existing at different heights in the flare atmosphere. The diagnostic properties of various spectral signatures of the chromospheric and photospheric flare components are briefly reviewed and the observing constraints defined. Existing observing facilities, able to fit these constraints, are outlined and a working hypothesis of a coordinated ground-based program is given.

Electrochromic Polymers Covalently Anchored to Electrode Surfaces. Optical and Electrochemical Properties of a Viologen‐Based Polymer

Smooth Pt and optically transparent electrodes can be functionalized with redox active polymeric material derived from the hydrolytically unstable {N,N′‐bis[‐3‐(trimethoxysilyl)propyl]‐4,4′‐bipyridinium}dibromide, I. The redox polymer on the surface is reversibly reducible to in either , and in the reduction of to is reversible. The vs. SCE, and vs. SCE in and , respectively. The vs. SCE in . The optical properties of (colorless), . (purple, , ), and (yellow, , ) depend somewhat on solvent/electrolyte. The optical spectral features associated with the three redox states of the surface polymer are easily distinguishable with the naked eye for coverages corresponding to >10−8mol/cm2 of redox active centers. Electrodes bearing are very rugged and do not deteriorate upon repeated cycling between and . Potential step/chronoamperometry experiments establish that the current for oxidation/reduction of the polymer is nearly proportional to , indicating that the rate of oxidation or reduction is controlled by a diffusion process with a diffusion constant, , of 10−9 to 10−10 cm2/sec depending on electrolyte and its concentration. In practical terms a potential step from 0.0 to −0.80V vs. SCE results in ∼50% reduction of to in a time as short as at a coverage of .

Active site Fe 3+ ligation by substrate and transition state analogs of protocatechuate 3,4 dioxygenase

Current proposals for the mechanism [1] of Protocatechuate (PCA) 3,4 Dioxygenase (3,4 PCD) suggest monodentate (OH) binding of PCA to the active site Fe 3+. This would promote ketonization of PCA, thereby creating a carbanion at C-4 which could be directly attacked by O 2. We have tested this proposal using ketonized substrate analogs and various spectroscopic probes. Our results confirm that ketonization is an essential step in the mechanism, but suggest that it occurs later in the cycle than the initial substrate complex. We have shown that water is a ligand for Brevibacterium fuscum 3,4 PCD by observing hyperfine broadening from 17OH 2 on all EPR resonances of the high spin Fe 3+ [2]. The spectrum of the 3,4 PCD-PCA complex is too broad to detect direct displacement of H 2O by PCA. However, no broadening is obeserved in complexes with three slowly metabolized substrate analogs. In contrast, water remains bound in complexes with non-metabolized, monodentate analogs ( e.g. 4-OH benzoate). Other small molecules also bind to Fe in 3,4 PCD. CN − binds in two steps; first it forms a high spin and then a low spin complex. It is likely that 2 CN − molecules bind sequentially to Fe, suggesting that there are two displaceable ligands. This is supported by the observation that PCA binds to the high spin 3,4 PCD-CN − complex to make a distinctly different ternary complex, but CN − does not bind to the, presumably bidentate, 3,4 PCD-PCA complex. The ketonized substrate analogs 2-OH-isonicotinic acid N-oxide (2-OH-INO) and 6-OH-nicotinic acid N-oxide have been synthesized [2]. These analogs form ∼100-fold stronger complexes with 3,4 PCD than does PCA, thus they are propose as transition state analogs. The EPR spectra of the 3,4 PCD-2-OH-INO complex is distinctly different than that of the CPA complex displaying small and negative zero field splitting (D = −0.5 cm −1 and intermediate rhombicity (E/D = 0.25). 17OH 2 remains bound in the inhibitor complexes suggesting that they are monodentate. CN − displaces the water showing that small molecules have access to the iron in the ketonized analog complexes. Transient kinetic studies show that the ketonized analogs bind in at least two phases. In the fast initial phase, a weak, readily reversible complex is formed, while in the slow ( t 1 2 = 0.12 s) second phase, the essentially irreversible complex is formed. At −20 °C in glycerol-buffer solution two complexes can be stabilized. The first complex has optical and EPR spectral features very similar to those of the substrate complex. In contrast, the final complex is dramatically different. The native red color is bleached, due perhaps to a large blue shift of the spectrum. Similar bleached spectra are observed for early transient intermediates in the reaction with PCA [3]. We suggest that, like PCA, ketonized analogs initially assume a bidentate Fe ligation but then change to a monodentate ligation. Such a change could be coincident with a conformational change of the enzyme designed to stabilized a ketonized reaction cycle intermediate. The analogous change in the PCA complex apparently requires interactions with O 2. Thus, the ketonized analogs may model the first oxy complex. Such a complex would apparently have a vacatable Fe ligand site which could be used to stabilized an oxygenous intermediate.

Electronic and geometric structure-function correlations of the coupled binuclear copper active site

Abstract

Electronic and geometric structure-function correlations of the coupled binuclear copper active site

A coupled binuclear copper active site exists in a variety of proteins and enzymes which perform different biological functions. These metalloproteins are listed in Table I. The hemocyanins are highly aggregated molecules whose sub-units exhibit significant intersite interactions, while the multicopper oxidases contain additional coppers which are involved in interactions with the coupled binuclear copper site. The unique spectral features associated with these binuclear copper active sites and their variation in the proteins of Table I provide an important opportunity for structure-function correlations in Bioinorganic Chemistry. ▪ A variety of different spectroscopic and magnetic techniques have been used to probe the unique electronic structure of the coupled binuclear copper active site. However, in order for results from these studies to be meaningful, the system must be subjected to perturbations and the spectral responses systematically investigated. In studying active sites in bioinorganic chemistry, not only can physical perturbations such as magnetic fields (Zeeman effects) or electric fields (Stark effect) be applied, but one also has the ability to chemically perturb the system. For the coupled binuclear copper active site, a series of protein derivatives has been prepared which allows the site to be systematically varied. These are summarized in Fig. 1. ▪ Fig. 1. Coupled binuclear copper active site derivatives. Detailed chemical and spectroscopic studies of these derivatives of the hemocyanin site have led to the ‘spectroscopically effective’ model for the coupled binuclear copper active site shown at the bottom of Fig. 1. A comparison of the half met and met apo derivatives indicates the presence of class 2 mixed valence behavior which correlates with the exogenous bridging ligand providing the pathway for electron delocalization. The met and dimer derivatives both contain formally binuclear cupric active sites, yet met (like oxy) exhibits no EPR signal. This has been related to the presence of an endogenous protein bridge(RO −) which provides a superexchange pathway for antiferromagnetic coupling between the coppers. When the endogenous bridge is broken, either by a group 2 ligand maintaining the coppers at a distance >5 Å (dimer derivative) or by protonation at low pH, EPR signals are observed which can extend over several thousand gauss and which result from zero field splitting of the spin triplet. A comparison of met and oxy demonstrates that the unique optical spectral features of oxy hemocyanin (bands at 600 nm, ϵ ∼ 1000 M −1 cm − and 350 nm, ϵ ∼ 20,000 M −1 cm −1) are O 2 = → Cu(II) charge transfer transitions. Finally, a transition dipole vector coupling model has been developed which predicts the charge transfer spectrum of a peroxide bridged to two copper(II)'s and strongly supports the μ-1,2 O 2 = bridging geometry in Fig. 1. Cooperativity among the hemocyanin biopolymer active sites in dioxygen binding has been studied through the preparation of a spectral probe derivative which contains ∼10% EPR-detectable half met sites dispersed among the EPR-nondetectable oxy sites. Deoxygenation produces large changes in the mixed valence properties of the EPR signal; these effects appear to correlate to a distortion of the site with changes in the endogenous bridge. Finally, chemical and spectroscopic studies have been extended to the metalloproteins in Table I in order to correlate active site structure and biological function. These studies have indicated that hemocyanin from both phyla, and tyrosinase, all have very similar coupled binuclear copper active sites. The lack of catalase activity in arthropod hemocyanin appears to relate to a geometric structural distortion of the active site. The monooxygenase and oxidase activity of tyrosinase correlates with the high accessibility of its active site to organic substrates, and has led to the structural mechanism for monophenol hydroxylation and oxidation shown in Fig. 2. Parallel studies on active site derivatives of the coupled binuclear copper (type 3) active site in laccase have demonstrated very different chemical ▪ Fig. 2. Proposed mechanism of phenol hydroxylation and oxidation to form o-quinones by tyrosinase. and spectroscopic behavior. This has been interpreted in terms of the preliminary ‘spectroscopically effective’ active site model shown in Fig. 3 where exogenous ligands do not bridge the two coppers of the type 3 site. In contrast to the μ-1,2 peroxo bridging geometry found for reversible dioxygen binding in hemocyanin, lack of exogenous ligand bridging in the type 3 site of laccase appears to correlate with irreversible binding of the peroxide intermediate produced in the reduction of dioxygen to water. ▪ Fig. 3. Comparison of the spectroscopically effective models for peroxide binding to the coupled binuclear copper site in hemocyanin, tyrosinase, and laccase. OR and R′ denote the endogenous protein bridge in the hemocyanins and laccase, respectively.

Oxovanadium(IV) complexes of the dithiocarbamate ligands derived from indole, indoline, carbazole and pyrrole

The preparation of four oxovanadium(IV) dithiocarbamate complexes [VOL 2: L = dithiocarbamate ligands derived from pyrrole, indole, indoline, or carbazole] is described. IR, optical and electron spin resonance spectral features of each complex are presented. The optical spectral features when coupled with the spin Hamiltonian parameters in a simple molecular orbital calculation indicate that the electron distribution between the V and S atoms is similar within this series and comparable to other dithiocarbamates with respect to the inplane σ- and π-bonding orbitals. In the out-of-plane π-orbitals, a slightly more covalent orbital is suggested for the title compounds. A rationalization of these data as well as a comparison to other metal dithiocarbamate complexes is presented.