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Rhenium complexes with multidentate benzazoles and related N,X-donor (X = N, O, S) ligandsPotgieter, Kim Carey January 2012 (has links)
The coordination behaviour of 4-aminoantipyrine (H2pap) and its Schiff base derivatives with the oxorhenium(V) and tricarbonyl rhenium(I) cores are reported. The reactions of trans-[ReOX3(PPh3)2] (X = Cl, Br) with H2pap were studied, and the complexes cis-[ReX2(pap)(H2pap)(PPh3)](ReO4) were isolated. The ligand pap is coordinated monodentately through the doubly deprotonated amino nitrogen as an imide, and H2pap acts as a neutral bidentate chelate, with coordination through the neutral amino nitrogen and the ketonic oxygen. The reactions of trans-[ReOBr3(PPh3)2] and cis-[ReO2I(PPh3)2] with -(2-aminobenzylideneamino)-1,2-dihydro-2,3-dimethyl-1-phenylpyrazol-5-one (H2nap) and 4-(2-hydroxybenzylideneamino)-1,2-dihydro-2,3-dimethyl-1-phenylpyrazol-5-one (Hoap) are also reported. The complexes cis-[Re(nap)Br2(PPh3)]Br, [ReO(OEt)(Hnap)(PPh3)]I and [ReO(OMe)(oap)(PPh3)]I were isolated and structurally characterized. The reactions of the Schiff base derivatives 1,2-(diimino-4’-antipyrinyl)ethane (dae) and 2,6-bis(4-amino-1,2-dihydro-2,3-dimethyl-1-phenylpyrazol-5-one)pyridine (bap) with [Re(CO)5X] (X = Br or Cl) produced fac-[Re(CO)3(dae)Cl] and fac-[Re(CO)3(bap)Br] respectively. A series of rhenium(I) tricarbonyl complexes containing bidentate derivatives of aniline was synthesized and structurally characterized. With 1,2-diaminobenzene (Hpda) the ‘2+1’ complex salt fac-[Re(CO)3(κ1-Hpda)(κ2-Hpda)]Br was isolated, but with 2-mercaptophenol (Hspo) the bridged dimer [Re2(CO)7(spo)2] was found. The neutral complex [Re(CO)3(ons)(Hno)] was isolated from the reaction of [Re(CO)5Br] with 2-[(2-methylthio)benzylideneimino]phenol (Hons; Hno = 2-aminophenol), with ons coordinated as a bidentate chelate with a free SCH3 group. In the complex [Re(CO)3(Htpn)Br] (Htpn = N-(2-(methylthio)benzylidene)benzene-1,2-diamine) the potentially tridentate ligand Htpn is coordinated via the methylthiol sulfur and imino nitrogen atoms only, with a free amino group. These rhenium(I) complexes, with the exception of [Re2(CO)7(spo)2], revealed broad emissions centred around 535 nm. The reactions of the rhenium(V) complex cis-[ReO2I(PPh3)2] with 2-aminothiophenol (H2atp), benzene-1,2-dithiol (H2tdt) and 2-hydroxybenzenethiol (H2otp) led to the formation of the rhenium(III) compounds [Re(Hatp)(ibsq)2].OPPh3, [Re(sbsq)3].OPPh3 and [Re(obsq)3].OPPh3 (ibsq = 2-iminothiobenzosemiquinonate, sbsq = 1,2-dithiobenzosemiquinonate, obsq = 2-hydroxothiobenzosemiquinonate) respectively. The complexes adopt a trigonal prismatic geometry around the rhenium centre with average twists angles between 3.20-26.10˚. The E1/2 values for the Re(III)/Re(IV) redox couple were found to be 0.022, 0.142 and 0.126 V for [Re(Hatp)(ibsq)2].OPPh3, [Re(sbsq)3].OPPh3 and [Re(obsq)3].OPPh3 respectively. The reactions of the benzoxazole ligands, 3-(benzoxazol-2-yl)pyridin-2-ol (Hbop) and 5-amino-2-(benzoxazol-2-yl)phenol (Habo) with a [ReO]3+ precursor led to the rhenium(III) complex, [ReCl2(bop)(PPh3)2], and the complex salt, [ReO(abo)I(PPh3)2]ReO4, respectively. A variety of benzothiazole and benzimidazole derivatives were reacted with [Re(CO)5Br]. In the case of bis(benzothiazol-2-ylethyl)sulfide (bts), the neutral complex fac-[Re(CO)3(bts)Br] was obtained. The dimeric complexes (μ-dbt)2[Re(CO)3]2 and (μ-mbt)2[Re(CO)3]2 were formed when 1,3-bis(benzothiazol-2-yl)thiourea (Hdbt) and 1-(benzothiazol-2-ylidene)-3-methylthiourea (Hmbt) were used as ligands. The reaction of 2,2’-(oxybis(methylene))bis(benzimidazole) (bmb) with [Re(CO)5Cl] resulted in the rhenium(I) complex salt fac-[Re(CO)3(bmb)]+, with the tri-μ-chlorohexacarbonyl dirhenate [Re2(CO)6Cl3]- as the counter anion. The neutral complex fac-[Re(CO)3(btp)Cl] was isolated from the reaction of the 2,9-bis(benzothiazol-2-yl)-1,10-phenanthroline (btp) ligand and [Re(CO)5Cl]. The reactions of trans-[ReOCl3(PPh3)2] with bis(benzimidazol-2-ylethyl)sulfide (btn) and 1-(benzothiazol-2-ylidene)-3-methylthiourea (Hmbt) led to the formation of the cationic compounds (μ-O)2[Re2O2(btn)2]I2 and [ReCl2(bte)(PPh3)2]Cl (bte = (benzothiazole-2-yl)-N-ethylidenemethanamine) respectively.
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Complexes of the ReO³⁺/Re(CO)₃cores with multidentate N,O-Donor chelatesPotgieter, Kim Carey January 2009 (has links)
This study investigates the coordination modes of multidentate N,O-donor ligands toward the [ReVO]3+ and fac-[ReI(CO)3]+ cores. The reactions of trans-[ReOX3(PPh3)2] (X = Cl, Br) with 4-aminoantipyrine (H2pap) were studied, and the complexes cis-[ReX2(pap)(H2pap)(PPh3)](ReO4) were isolated. The X-ray crystal structures show that both complexes display a distorted octahedral geometry around the central rhenium atom, and are mirror images of each other. The ligand pap is coordinated monodentately through the doubly deprotonated amino nitrogen as an imide, and H2pap acts as a neutral bidentate chelate, with coordination through the neutral amino nitrogen and the ketonic oxygen. The attempted synthesis of the potentially hexadentate Schiff base ligand 1,2-bis(2-{(Z)- [(2-hydroxyphenyl)imido]methyl}phenoxy)benzene from the condensation reaction of 2- (2-((2-aminophenoxy)methyl)benzyloxy)benzenamine and salicylaldehyde produced the zwitterion derivative (H2ono) of 2-{(Z)-[2-(hydroxyphenyl)imino]methyl}phenol. The tridentate Schiff bases (Z)-2-(2-aminobenzylideneamino)phenol (H3onn) and (Z)-2-(2- (methylthio)benzylideneamino)phenol (Hons) were prepared in a similar manner. The reaction of H2ono with trans-[ReOBr3(PPh3)2] surprisingly led to the isolation of the rhenium(III) complex [ReBr(PPh3)2(ono)], in which ono acts as a dianionic tridentate ligand. The reaction of H3onn with trans-[ReOBr3(PPh3)2] produced the imidorhenium(V) complex salt [ReBr(PPh3)2(onn)]Br, in which onn is coordinated as a trianionic tridentate imidoiminophenolate. The reaction of Hons with [Re(CO)5Br] led to the further decomposition of the Hons ligand, and the rhenium(I) product fac- [Re(CO)3(ons)(Hno)] (Hno = 2-aminophenol) was isolated, with ons coordinated as a monoanionic bidentate chelate (with a free SCH3 group), and Hno present as a neutral monodentate ligand with coordination through the amino nitrogen atom. Abstract Nelson Mandela Metropolitan University vi The reactions of the potentially hexadentate ligand N,N’-{ethane-1,2- diylbis[nitrilomethylidenebenzene-1,2-diyl]}bis(2-aminobenzeneimine) (H2ted) with rhenium(V) starting materials resulted in the decomposition of the H2ted molecule to give different coordinated multidentate ligands coordinated to the rhenium(V) centers. In the reaction of H2ted with trans-[ReOBr3(PPh3)2] in ethanol, the highly unusual ‘3+3’ complex cation [Re(tnn)(Htnn)]Br2 was isolated, in which tnn is coordinated as a tridentate imido-imino-amine, and Htnn is present as a tridentate monoanionic amidoimino- amine chelate (H2tnn = N-(2-aminophenylmethylidene)ethane-1,2-diamine). With trans-[ReO2(py)4]Cl as starting material, the neutral complex [ReO(dne)] was found, in which the tetradentate chelate dne acts as a triamido-imine. The reaction of cis- [ReO2I(PPh3)2] with H2ted led to the formation of the monocationic complex salt [ReO(ane)]PF6, with ane acting as a tetradentate dianionic diamidodiimine (H2ane = N,N’-bis[(2-aminophenyl)methylidene] ethane-1,2-diamine). The seven-coordinate rhenium(III) complex cation [Re(dhp)(PPh3)2]+ (H2dhp = 2,6-bis(2- hydroxyphenyliminomethyl)pyridine) was isolated as the iodide salt from the reaction of cis-[ReO2I(PPh3)2] with H2dhp in ethanol and as the perrhenate salt from the reaction of trans-[ReOBr3(PPh3)2] with H2dhp in methanol. Both products result from a disproportionation reaction with perrhenate also being produced in the process. The complex fac-[Re(CO)3(H2dhp)Br] was prepared from [Re(CO)5Br] and H2dhp in toluene, where the H2dhp ligand acts as a neutral bidentate NN-donor chelate. The metal is coordinated to three carbonyl donors in a facial orientation, to a neutral imino nitrogen, a pyridinic nitrogen and a bromide.
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Curcumin analogues as ligands for Re (I) and (V)Schmitt, Bonell January 2012 (has links)
Coordination properties of 4-bromo-N-(diethylcarbamothioyl)benzamide (Hbeb) and 4-bromo-N-(diphenylcarbamothioyl)benzamide (Hbpb) with oxorhenium(V) and rhenium(I) are reported and discussed. Transition metal complexes of these ligands were studied due to the wide range of applications of thiourea derivatives in biological fields. N-[Di(alkyl/aryl)carbamothioyl]benzamide derivatives readily coordinate to metal ions as O,S-donors and the catalytic property of the complexes can be altered by these ligands, due to steric and electronic properties provided by various substituents. The coordination possibilities of curcumin with rhenium(V) are discussed, as well as the difficulties encountered. Analogues of curcumin have been made, which also contains a seven-spacer unit between the phenyl rings, which would be more reactive and more effective in bonding to rhenium and which have greater or a similar biological activity to curcumin. This was done by assessing the coordination properties of 1,5-bis(salicylidene)thiocarbohydrazide (H4salt) and 2,4-bis(vanilidene)thiocarbohydrazide (H4vant) with oxorhenium(V) and rhenium(I) starting materials. Two rhenium(V) complex salts of the core [ReX(PPh3)2]4+ (X = Br, I), containing a coordinated imido nitrogen, are reported. One is a ‘2+1’ complex, coordinating bi- and monodentately, with the other a similar ‘3+0’ complex containing a tridentate imido-coordinated Schiff base. Selected compounds were tested against oesophageal cancer cell lines in order to evaluate and compare their effectiveness in eliminating or reducing the cancer cells in the test medium during biological testing.
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Rhenium catalysis I. Hydrogenation and hydroformylation using rhenium carbonyl compounds ; II. Hydrogenation using catalysts obtained from the reduction of perrhenates with metals in aqueous solutionSelin, Terry G. 01 September 1957 (has links)
The purpose of this work was to investigate the catalytic activity in both hydrogenation and hydroformylation reactions of rhenium preparations which have not been previously characterized. Rhenium pentacarbonyl was prepared in good yield from rhenium heptoxide and carbon monoxide. The optimum conditions for preparation were 25 hours per gram of dry rhenium heptoxide at 250° under 3000 psig. (initial) of carbon monoxide. Rhenium chloropentacarbonyl was prepared in 62% yield from potassium chlororhenite and carbon monoxide at high temperatures and pressures. The iodopentacarbonyl was prepared in 29% yield from potassium perrhenate, methyl iodide, and carbon monoxide. The preparation of rhenium hydrocarbonyl was attempted using sever approaches; however, no indication of the hydrocarbonyl was observed. Hydrogenative decomposition of rhenium pentacarbonyl in benzene solutions yielded an active catalyst which upon analysis proved to be metallic rhenium. Other solvents besides benzene were used but in each case the catalyst appeared as a rhenium mirror which was difficult to remove from the container. The use of rhenium pentacarbonyl as a homogeneous hydrogenation catalyst failed in attempts to reduce hexene-1 and cyclohexanone. The hydrogenation was accomplished only when temperatures were used which were high enough to decompose the carbonyl (200-250°). The metallic rhenium catalysts were characterized against a variety of substrates. With the exception of styrene, the substrates were all reduced in the temperature range 160-200°. Comparatively, the most successful reductions were those of benzene (179/3350 psig. for 22 hours) and acetic acid (2000/4190 psig. for 16 hours). Notably, nitrobenzene required 198° for complete reduction. When activated charcoal was added to the rhenium pentacarbonyl-benzene solution, a slightly more active catalyst was obtained. However, milder conditions of hydrogenative decomposition were not achieved. The addition of iron, zinc, or tin to acidified solutions of ammonium perrhenate resulted in the formation of a "rhenium black" which exhibited catalytic activity in hydrogenation reactions. This catalyst was obtained in a quantitative yield when an excess of reductant was present at all times. Analysis of this catalyst (both quantitatively and qualitatively) indicated that this catalyst was a hydrated rhenium oxide, probably ReO_2•3H_2O or ReO_2•2½H_2O. The activity of these hydrated rhenium oxide catalysts was greater than that of the metallic rhenium catalysts in all cases. Using the hydrated rhenium oxide catalyst, the carbon-carbon double bonds of hexene-1, cyclohexene, and styrene were reduced at 90-130°/3400-3900 psig. Interestingly, the presence of this catalyst did not effect the reduction of cycloheptanone until a temperature of 167° was reached. The reduction of 2-propyn-1-ol at 163° yielded both saturated and unsaturated alcohol. Adam's catalyst resulted in total decomposition of this substrate at 250° with no reduction occurring at lower temperatures. Benzene was also reduced at relatively mild conditions (177°/3935 psig. for 14 hours) using a hydrated rhenium oxide catalyst; pyridine was reduced at 230°/4520 psig. in 22 hours. Acetic acid was reduced at a mild 156° in the presence of a hydrated rhenium oxide catalyst. This is comparable with other rhenium catalysts and much better than Adam's catalyst which will not reduce acetic acid at 250° and better than any other reported catalyst except those of rhenium. The catalysts prepared using iron as a reductant were more active than those which were obtained using zinc; however, this difference was not great in the reduction of most substrates. The hydrated rhenium oxide catalysts were used in the reduction of a series of bifunctional substrates which contained the possible combinations of carbon-carbon double bond, carbonyl, carboxyl, and nitro groups. These reductions were compared with Adam's catalyst in many cases. The olefinic bonds in allylacetone and 2-allylcyclohexanone were preferentially reduced using both the hydrated rhenium oxide catalyst and Adam's catalyst. However, the rhenium catalyst reduced crotonaldehyde to n-butanol while Adam's catalyst yielded n-butyraldehyde. The olefinic bonds in vinyl-acetic, maleic, crotonic, and undecylenic acids were reduced in preference to the carboxyl group using the rhenium oxide catalyst. Under milder conditions, Adam's catalyst also reduced vinylacetic acid to n-butyric acid as expected. The carbonyl group was reduced completely in the presence of the carboxyl group in levulinic acid using the rhenium oxide catalyst. The nitro group was reduced (in the presence of the rhenium catalyst) in preference to the carbon- carbon double bond, carboxylic, or carbonyl groups in m-nitrostyrene, p-nitrophenyl-acetic acid, and m-nitroacetophenone, respectively. The same results were obtained using Adam's catalyst in the reduction of m-nitroacetophenone. The ease of reduction of different groups using the hydrated rhenium oxide catalyst was in the order: aromatic ring < carboxyl < carbonyl < carbon-carbon double bond < nitro. The order was the same using Adam's catalyst except that the carboxylic acid group and aromatic system were not reduced at all in the latter case under conditions of 250°/4500 psig. for 24 hours. However, the order of ease of reduction using the rhenium catalyst in the reduction of mono-functional substrates was aromatic ring < carboxyl < nitro < carbon-carbon double bond < carbonyl. Thus, the nitro group exhibited a poisoning effect when present in bifunctional substrates. Generally, the activity of the catalysts prepared in this study are comparable with previously characterized rhenium catalysts. This applies especially to the reduction of benzene and acetic acid. Rhenium pentacarbonyl, rhenium iodopentacarbonyl, and rhenium hepta-sulfide were used as catalysts in the attempted hydroformylation of cyclohexene and hexene-1 . However, in the temperature range 30-260° no hydroformylation was observed other than that which resulted from iron impurities. However, increased hydrogenation of substrate and products occurred when a rhenium compound was added as a catalyst. Dicobalt octacarbonyl was prepared and used in the hydroformylation reaction for comparison. As reported, the yields of hydroformylated products was excellent.
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Carrier-free separation of bromine and rhenium from cyclotron targets and the gamma radiation of arsenic-76, bromine-76, and bromine-77 /Comerford, John Richard January 1960 (has links)
No description available.
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The use of a solid state detector for conversion electron spectroscopy and a study of the radioactive decay of ⁹⁷Ru /Gillespie, Claude Milton January 1966 (has links)
No description available.
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Microwave-Assisted Synthesis, Characterization, and Photophysical Properties of New Rhenium(I) Pyrazolyl-Triazine ComplexesSalazar Garza, Gustavo Adolfo 05 1900 (has links)
The reaction of the chelating ligand 4-[4,6-bis(3,5-dimethyl-1H-pyrazol-1-yl)-1,3,5-triazin-2-yl]-N,N-diethyl-benzenamine, L, with pentacarbonylchlororhenium by conventional heating method produces the complexes fac-[ReL(CO)3Cl2] and fac-[Re2L(CO)6Cl2] in a period of 48 hours. The use of microwaves as the source of heat and the increase in the equivalents of one of the reactants leads to a more selective reaction and also decreases the reaction time to 1 hour. After proper purification, the photophysical properties of fac-[ReL(CO)3Cl] were analyzed. The solid-state photoluminescence analysis showed an emission band at 628 nm independent of temperature. However, in the solution studies, the emission band shifted from 550 nm in frozen media to 610 nm when the matrix became fluid. These results confirm that this complex possess a phenomenon known as rigidochromism.
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Oligothiophenes and conducting metallopolymers : fundamental studies and development of functional materialsLytwak, Lauren Ashley 17 July 2014 (has links)
Diimine rhenium(I) tricarbonyl complexes are known as phosphorescent emitters and electro- and photocatalysts for the reduction of CO₂ to CO. Conducting metallopolymers containing this rhenium(I) moiety should not only retain the photoluminescent and catalytic properties of the complex but also gain the conductivity, processability, and mechanical flexibility typical of [pi]-conjugated polymers. A series of tricarbonyl rhenium(I) diimine-type monomers and metallopolymers have been prepared. Appended to the ligands are thiophene and 3,4-ethylenedioxythiophene (EDOT) groups for electropolymerization of the metal complexes. UV-Vis absorption and emission spectroscopy studies of the monomers indicate that light emission originates from triplet ligand-centered (³LC) [pi] [right arrow] [pi]* and triplet metal-to-ligand charge transfer (³MLCT) excited states. Additionally, both the monomers and metallopolymers show electrocatalytic activity towards the reduction of CO₂ to CO. Furthermore, the EDOT-functionalized diimine-type ligand (EDOT₂-BPP) also serves as a good sensitizing ligand for luminescent lanthanide emission. A series of lanthanide complexes that utilize tris([beta]-diketonates) and EDOT₂-BPP ligands have been synthesized and studied using X-ray crystallography and photophysical techniques. Large quantum yields and microsecond lifetimes were found for the EuIII and SmIII complexes. Complexes of TbIII were found to have weak luminescent emission due to the less-than-optimal energy gap between the sensitizing ligands and the excited state of the TbIII ion. Oligothiophenes are models for polymeric systems because of solution processability, controlled chain length, and a well-defined structure. We have synthesized a library of alkyl and polyfluoroalkyl-substituted oligothiophenes to study how molecular structure, long-range order, spatial orientation, and varying degree of electronic coupling between molecules influences charge separation in photovoltaics. These oligoalkylthiophenes have been characterized by X-ray diffraction, photophysical methods, electrochemistry, and UV-Vis and EPR spectroscopies. Although the electronic properties of these oligoalkylthiophenes do not vary with alkyl group, aggregates of oligooctylthiophene, made through solution processing, have distinct morphologies with varying amounts of electronic disorder. The extent of electronic disorder within the aggregate is determined by comparing the suppression of the 0-0 vibronic band in the fluorescence spectra to that of the non-aggregated parent molecule. This extent of electronic disorder was correlated with the local contact potential of individual aggregates through Kelvin probe force microscopy (KPFM) measurements. / text
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Experimental studies in the isomerism and structural variations in molybdenum and rhenium halo-compoundsAnderson, Ian Robert. January 1968 (has links) (PDF)
Includes bibliography.
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Synthesis and characterization of Rhenium (III & V) Schiff base complexes for nuclear medicine /Benny, Paul January 2001 (has links)
Thesis (Ph. D.)--University of Missouri-Columbia, 2001. / Typescript. Vita. Includes bibliographical references. Also available on the Internet.
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