排気ガス中のNOの白金触媒による酸化反応に関する数値解析

YAMAMOTO, Kazuhiro, YAMASHITA, Hiroshi, YANA, Hiroyoshi, 山本, 和弘, 山下, 博史, 家根, 弘好

January 2009

No description available.

Combustion products

Numerical Analysis

Elementary Reaction Kinetics

Platinum

NO Oxidization

Catalyzer

Calcium silicate hydrate : crystallisation and alkali sorption

Hong, Sung-Yoon

January 2000

Homogeneous single C-S-H gels have been prepared for the investigation of alkali binding potential and crystallisation. A distribution coefficient, R_d, was introduced to express the partition of alkali between solid and aqueous phases at 25°C. R_d is independent of alkali hydroxide concentration and depends only on Ca:Si ratio over wide ranges of alkali concentration. The trend of numerical values of R_d indicates that alkali bonding into the solid improves as its Ca:Si ratio decreases. Reversibility is demonstrated, indicating a possibility of constant R_d value of the material. Al has been introduced to form C-A-S-H gels and their alkali sorption properties also determined. Al substituted into C-S-H markedly increases R_d, indicating enhancement of alkali binding. However, the dependence of R_d on alkali concentration is non-ideal with composition. A two-site model for bonding is presented. Crystallisation both under saturated steam and 1 bar vapour pressure has been investigated. It has been shown that heat treatment by saturated steam causes crystallisation of gels. The principal minerals obtained were (i) C-S-H gel and Ca(OH)₂ at ~55°C, (ii) 1.1 nm tobermorite, jennite and afwillite at 85-130°C, and (iii) xonotlite, foshagite and hillebrandite at 150-180°C. Properties of crystalline C-S-H were also reported for reversible phase transformation, pH conditioning ability, seeding effect and solubility. At 1 bar pressure, crystallisation is slower than in saturated steam due to lower water activity. Tobermorite-like nanodomains develop during reaction at low Ca/Si ratios. In some Ca-rich compositions, Ca(OH)₂ is exsolved and occurs as nano-sized crystallites.

541

Gas Phase Reaction Kinetics Of Boron Fiber Production

Firat, Fatih

01 August 2004

In the production of boron fibers using CVD technique, boron deposition and dichloroborane formation reactions take place in a reactor. Boron deposition reaction occurs at the surface while formation of dichloroborane is the result of both gas phase and surface reactions. A CSTR type of reactor was designed and constructed from stainless steel to investigate the gas phase reaction kinetics and kinetic parameters of boron fibers produced from the reaction of boron trichloride and hydrogen gases in a CVD reactor. The gases were heated by passing through the two pipes which were located into the ceramic furnace and they were mixed in the CSTR. The effluent gas mixture of the reactor was quenched by passing through a heat exchanger. An FT-IR spectrophotometer was connected to the heat exchanger outlet stream to perform on-line chemical analysis of the effluent gas mixture. Experiments were carried out at atmospheric pressure and a reactor temperature range of 300-600 &ordm / C with different inlet reactant concentrations. The analysis of the FT-IR spectra indicated that the gas phase reaction and the surface reaction started at reactor temperatures above 170 &ordm / C and 500&ordm / C, respectively. It was concluded that reaction rate of the product increased with an increase in the inlet concentration of both reactants (BCl3 and H2) and with an increase in the reactor temperature. The gas phase reaction rate was expressed in terms of a th and b th orders with respect to the inlet concentrations of BCl3 and H2. The activation energy of the gas phase reaction, a and b were found to be 30.156 , 0.54 and 0.64, respectively. The correlation coefficient was 0.9969.

QD Laboratories 51-63

Zinc Borate Production In A Batch Reactor

Gurhan, Deniz

01 December 2005

Zinc borate is a flame retardant additive used in polymers, wood applications and textile products. There are different types of zinc borate having different chemical composition and structure. In this study, the production of zinc borate that had the molecular formula of 2ZnO.3B2O3.3,5H2O was studied. The aim of this study was to investigate the effects of reaction parameters on the properties of zinc borate that had been synthesized by the reaction of boric acid and zinc oxide at the existence of the seed crystals and to determine the optimum experimental conditions for zinc borate production reaction. Reaction kinetics was also investigated to find a suitable kinetics model. The effect of boric acid to zinc oxide ratio -H3BO3:ZnO ratio- (3:1, 3.5:1, 5:1 and 7:1), the particle size of zinc oxide (10&micro / m and 25&micro / m), stirring rate (275 rpm, 400 rpm, 800 rpm and 1600 rpm), temperature (75&deg / , 85&deg / and 95&deg / ) and size of seed crystals (10&micro / m and smaller size) on reaction rate, reaction completion time, composition and particle size distribution of zinc borate were investigated. Experiments were performed in a continuously stirring, temperature controlled batch reactor with a volume of 1.5L. During the experiments samples were taken to be analyzed in regular time intervals. The analyses of the samples gave the concentration change of zinc oxide and boron oxide in the solid as well as the conversion of zinc oxide to zinc borate with respect to time and the rate of reaction was calculated. The products were also analyzed for particle size distribution. The experimental results showed that the reaction rate increased with the increasing H3BO3:ZnO ratio, particle size of zinc oxide, stirring rate and temperature. The reaction completion time was also decreased by increasing H3BO3:ZnO ratio, stirring rate and temperature. The particle size of final product, zinc borate, decreased with increasing stirring rate and size of zinc borate used as seed and increased with increasing particle size of zinc oxide used as reactant. The average particle sizes of the final product zinc borates synthesized at the end of the experiments were ranged between 4.3 &micro / m and 16.6 &micro / m. The zinc borate production reaction was mainly fitted the unreacted core model for the case of diffusion through product layer controls.

TP Chemical Engineering 155-156

Nitrosyl complexes of ruthenium and osmium

Laing, Kerry Richard

January 1972

This study concerns the synthesis, structure and reactivity of nitrosyl complexes of ruthenium and osmium. Attempts have been made to prepare coordinatively saturated and unsaturated complexes and a study of their oxidative addition reactions bears considerable resemblance to the more familiar carbonyl complexes M(CO)3(PPh3)2. A number of interesting atom transfer reactions, generally involving oxygen, have been observed. The d8 complex RuCl(CO)(NO)(PPh3)2 results from the interaction of RuHCl(CO)(PPh3)3 with N-methyl-N-nitrosotoluene-p-sulphonamide. The labile halide ligand is readily displaced by a large range of anions and it is believed that both linear and bent nitrosyl linkages may exist for different members of this series. The structures of these complexes are discussed in the light of recent X-ray crystal structure data. Halogens and hydrogen halides add to give the familiar RuX3(NO)(PPh3)2; RuCl3(NO)(PPh2Me)2 is prepared in a direct reaction and also by phosphine exchange and 1H n.m.r. data confirm that the phosphine ligands are trans. The complexes RuX(CO)(NO)(PPh3)2 react readily with O2 to form the dioxygen complexes Ru(O2)X(NO)(PPh3)2. Halogens and hydrogen halides produce RuX3(NO)(PPh3)2. The dioxygen complexes react with SO2 and N2O4 to give sulphato and dinitrato complexes respectively. The reaction with CO results in the intramolecular oxidation of the nitrosyl group to coordinated nitrate accompanied by the incorporation of two moles of CO, i.e. RuX(NO3)(CO)2(PPh3)2 is formed. The dioxygen complexes catalytically oxidise triphenylphosphine or triphenylarsine to the respective oxides and RuX(NO)(PPh3)2 can be isolated from this cycle. Reactions of these four-coordinated complexes with O2, CO, Cl2 and NOBF4 are recorded. The dinitrosyl complex Ru(NO)2(PPh3)2 is reported from a number of syntheses, the most successful being via a ligand reaction when RuCl2(CO)2(PPh3)2 is heated with NaNO2 and Ph3P in dimethyl formamide. The P-tolyldiphenylphosphine analogue is also reported and the mono-substituted product Ru(NO)2(PPh3)[P(OPh)3] is produced in an exchange reaction between Ru(NO)2(PPh3)2 and excess triphenylphosphite. This phosphite complex reacts with Ph3P and O2 to produce Ru(O2)(NO2)(NO)PPh3)2 by an atom transfer process. Ru(NO)2(PPh3)2 reacts with the acids HY (Y = BF4, PF6, ClO4) and O2 to give the dinitrosyl cations [Ru(OH)(NO)2(PPh3)2]+Y- in which the two nitrosyl groups are structurally and electronically inequivalent. [RuCl(NO)2(PPh3)2]BF4 is reported and reactions of these dinitrosyl cations with halide ions to give RuX2(NO3)(NO)(PPh3)2, with intramolecular oxidation of the NO group, are also described. OsCl2(OH)(NO)(PPh3)2 reacts irreversibly with alcohols to form OsCl2(OR)(NO)(PPh3)2 (R = CH3, C2H5, n-C3H7, (CH3O)CH2CH2) which readily undergo hydride abstraction to form OsHCl2(NO)(PPh3)2. Sodium borohydride converts this complex to the trihydrido species OsH3(NO)(PPh3)2 and if the reaction is performed in the presence of Ph3P, OsH(NO)(PPh3)3 results. The coordinated perchlorate complex OsHCl(OClO3)(NO)(PPh3)2 results form the reaction of OsHCl2(NO)(PPh3)2 with silver perchlorate; this is readily reversed by chloride ions or the solvents CH2Cl2 and CHCl3. This perchlorato complex also arises from the reaction of OsH(CO)(NO)(PPh3)2 with HClO4 and a related tetrafluoroborato complex, OsH(OC2H5)(FBF3)(NO)(PPh3)2 by substituting HBF4. This complex reacts with Ph3P to give [OsH(OH)(NO)(PPh3)3]BF4, CO to give [Os(CO)2(NO)(PPh3)2]BF4 and LiX (X = Br, I) to give OsHX2(NO)(PPh3)2. OsHCl(OClO3)(NO)(PPh3)2 reacts with NaOH in methanol, in the presence of O2 to produce Os(O2)Cl(NO)(PPh3)2. This dioxygen complex is far less stable than the ruthenium analogue but it undergoes similar reactions. Ph3P is oxidised, SO2 and CO give sulphato and a nitratodicarbonyl complex respectively. Infra-red, 1H n.m.r., conductivity, molecular weight data and elemental analysis have been used in formulation and structural assignment.

Nitrosyl complexes of ruthenium and osmium

Laing, Kerry Richard

January 1972

This study concerns the synthesis, structure and reactivity of nitrosyl complexes of ruthenium and osmium. Attempts have been made to prepare coordinatively saturated and unsaturated complexes and a study of their oxidative addition reactions bears considerable resemblance to the more familiar carbonyl complexes M(CO)3(PPh3)2. A number of interesting atom transfer reactions, generally involving oxygen, have been observed. The d8 complex RuCl(CO)(NO)(PPh3)2 results from the interaction of RuHCl(CO)(PPh3)3 with N-methyl-N-nitrosotoluene-p-sulphonamide. The labile halide ligand is readily displaced by a large range of anions and it is believed that both linear and bent nitrosyl linkages may exist for different members of this series. The structures of these complexes are discussed in the light of recent X-ray crystal structure data. Halogens and hydrogen halides add to give the familiar RuX3(NO)(PPh3)2; RuCl3(NO)(PPh2Me)2 is prepared in a direct reaction and also by phosphine exchange and 1H n.m.r. data confirm that the phosphine ligands are trans. The complexes RuX(CO)(NO)(PPh3)2 react readily with O2 to form the dioxygen complexes Ru(O2)X(NO)(PPh3)2. Halogens and hydrogen halides produce RuX3(NO)(PPh3)2. The dioxygen complexes react with SO2 and N2O4 to give sulphato and dinitrato complexes respectively. The reaction with CO results in the intramolecular oxidation of the nitrosyl group to coordinated nitrate accompanied by the incorporation of two moles of CO, i.e. RuX(NO3)(CO)2(PPh3)2 is formed. The dioxygen complexes catalytically oxidise triphenylphosphine or triphenylarsine to the respective oxides and RuX(NO)(PPh3)2 can be isolated from this cycle. Reactions of these four-coordinated complexes with O2, CO, Cl2 and NOBF4 are recorded. The dinitrosyl complex Ru(NO)2(PPh3)2 is reported from a number of syntheses, the most successful being via a ligand reaction when RuCl2(CO)2(PPh3)2 is heated with NaNO2 and Ph3P in dimethyl formamide. The P-tolyldiphenylphosphine analogue is also reported and the mono-substituted product Ru(NO)2(PPh3)[P(OPh)3] is produced in an exchange reaction between Ru(NO)2(PPh3)2 and excess triphenylphosphite. This phosphite complex reacts with Ph3P and O2 to produce Ru(O2)(NO2)(NO)PPh3)2 by an atom transfer process. Ru(NO)2(PPh3)2 reacts with the acids HY (Y = BF4, PF6, ClO4) and O2 to give the dinitrosyl cations [Ru(OH)(NO)2(PPh3)2]+Y- in which the two nitrosyl groups are structurally and electronically inequivalent. [RuCl(NO)2(PPh3)2]BF4 is reported and reactions of these dinitrosyl cations with halide ions to give RuX2(NO3)(NO)(PPh3)2, with intramolecular oxidation of the NO group, are also described. OsCl2(OH)(NO)(PPh3)2 reacts irreversibly with alcohols to form OsCl2(OR)(NO)(PPh3)2 (R = CH3, C2H5, n-C3H7, (CH3O)CH2CH2) which readily undergo hydride abstraction to form OsHCl2(NO)(PPh3)2. Sodium borohydride converts this complex to the trihydrido species OsH3(NO)(PPh3)2 and if the reaction is performed in the presence of Ph3P, OsH(NO)(PPh3)3 results. The coordinated perchlorate complex OsHCl(OClO3)(NO)(PPh3)2 results form the reaction of OsHCl2(NO)(PPh3)2 with silver perchlorate; this is readily reversed by chloride ions or the solvents CH2Cl2 and CHCl3. This perchlorato complex also arises from the reaction of OsH(CO)(NO)(PPh3)2 with HClO4 and a related tetrafluoroborato complex, OsH(OC2H5)(FBF3)(NO)(PPh3)2 by substituting HBF4. This complex reacts with Ph3P to give [OsH(OH)(NO)(PPh3)3]BF4, CO to give [Os(CO)2(NO)(PPh3)2]BF4 and LiX (X = Br, I) to give OsHX2(NO)(PPh3)2. OsHCl(OClO3)(NO)(PPh3)2 reacts with NaOH in methanol, in the presence of O2 to produce Os(O2)Cl(NO)(PPh3)2. This dioxygen complex is far less stable than the ruthenium analogue but it undergoes similar reactions. Ph3P is oxidised, SO2 and CO give sulphato and a nitratodicarbonyl complex respectively. Infra-red, 1H n.m.r., conductivity, molecular weight data and elemental analysis have been used in formulation and structural assignment.

Nitrosyl complexes of ruthenium and osmium

Laing, Kerry Richard

January 1972

This study concerns the synthesis, structure and reactivity of nitrosyl complexes of ruthenium and osmium. Attempts have been made to prepare coordinatively saturated and unsaturated complexes and a study of their oxidative addition reactions bears considerable resemblance to the more familiar carbonyl complexes M(CO)3(PPh3)2. A number of interesting atom transfer reactions, generally involving oxygen, have been observed. The d8 complex RuCl(CO)(NO)(PPh3)2 results from the interaction of RuHCl(CO)(PPh3)3 with N-methyl-N-nitrosotoluene-p-sulphonamide. The labile halide ligand is readily displaced by a large range of anions and it is believed that both linear and bent nitrosyl linkages may exist for different members of this series. The structures of these complexes are discussed in the light of recent X-ray crystal structure data. Halogens and hydrogen halides add to give the familiar RuX3(NO)(PPh3)2; RuCl3(NO)(PPh2Me)2 is prepared in a direct reaction and also by phosphine exchange and 1H n.m.r. data confirm that the phosphine ligands are trans. The complexes RuX(CO)(NO)(PPh3)2 react readily with O2 to form the dioxygen complexes Ru(O2)X(NO)(PPh3)2. Halogens and hydrogen halides produce RuX3(NO)(PPh3)2. The dioxygen complexes react with SO2 and N2O4 to give sulphato and dinitrato complexes respectively. The reaction with CO results in the intramolecular oxidation of the nitrosyl group to coordinated nitrate accompanied by the incorporation of two moles of CO, i.e. RuX(NO3)(CO)2(PPh3)2 is formed. The dioxygen complexes catalytically oxidise triphenylphosphine or triphenylarsine to the respective oxides and RuX(NO)(PPh3)2 can be isolated from this cycle. Reactions of these four-coordinated complexes with O2, CO, Cl2 and NOBF4 are recorded. The dinitrosyl complex Ru(NO)2(PPh3)2 is reported from a number of syntheses, the most successful being via a ligand reaction when RuCl2(CO)2(PPh3)2 is heated with NaNO2 and Ph3P in dimethyl formamide. The P-tolyldiphenylphosphine analogue is also reported and the mono-substituted product Ru(NO)2(PPh3)[P(OPh)3] is produced in an exchange reaction between Ru(NO)2(PPh3)2 and excess triphenylphosphite. This phosphite complex reacts with Ph3P and O2 to produce Ru(O2)(NO2)(NO)PPh3)2 by an atom transfer process. Ru(NO)2(PPh3)2 reacts with the acids HY (Y = BF4, PF6, ClO4) and O2 to give the dinitrosyl cations [Ru(OH)(NO)2(PPh3)2]+Y- in which the two nitrosyl groups are structurally and electronically inequivalent. [RuCl(NO)2(PPh3)2]BF4 is reported and reactions of these dinitrosyl cations with halide ions to give RuX2(NO3)(NO)(PPh3)2, with intramolecular oxidation of the NO group, are also described. OsCl2(OH)(NO)(PPh3)2 reacts irreversibly with alcohols to form OsCl2(OR)(NO)(PPh3)2 (R = CH3, C2H5, n-C3H7, (CH3O)CH2CH2) which readily undergo hydride abstraction to form OsHCl2(NO)(PPh3)2. Sodium borohydride converts this complex to the trihydrido species OsH3(NO)(PPh3)2 and if the reaction is performed in the presence of Ph3P, OsH(NO)(PPh3)3 results. The coordinated perchlorate complex OsHCl(OClO3)(NO)(PPh3)2 results form the reaction of OsHCl2(NO)(PPh3)2 with silver perchlorate; this is readily reversed by chloride ions or the solvents CH2Cl2 and CHCl3. This perchlorato complex also arises from the reaction of OsH(CO)(NO)(PPh3)2 with HClO4 and a related tetrafluoroborato complex, OsH(OC2H5)(FBF3)(NO)(PPh3)2 by substituting HBF4. This complex reacts with Ph3P to give [OsH(OH)(NO)(PPh3)3]BF4, CO to give [Os(CO)2(NO)(PPh3)2]BF4 and LiX (X = Br, I) to give OsHX2(NO)(PPh3)2. OsHCl(OClO3)(NO)(PPh3)2 reacts with NaOH in methanol, in the presence of O2 to produce Os(O2)Cl(NO)(PPh3)2. This dioxygen complex is far less stable than the ruthenium analogue but it undergoes similar reactions. Ph3P is oxidised, SO2 and CO give sulphato and a nitratodicarbonyl complex respectively. Infra-red, 1H n.m.r., conductivity, molecular weight data and elemental analysis have been used in formulation and structural assignment.

Nitrosyl complexes of ruthenium and osmium

Laing, Kerry Richard

January 1972

This study concerns the synthesis, structure and reactivity of nitrosyl complexes of ruthenium and osmium. Attempts have been made to prepare coordinatively saturated and unsaturated complexes and a study of their oxidative addition reactions bears considerable resemblance to the more familiar carbonyl complexes M(CO)3(PPh3)2. A number of interesting atom transfer reactions, generally involving oxygen, have been observed. The d8 complex RuCl(CO)(NO)(PPh3)2 results from the interaction of RuHCl(CO)(PPh3)3 with N-methyl-N-nitrosotoluene-p-sulphonamide. The labile halide ligand is readily displaced by a large range of anions and it is believed that both linear and bent nitrosyl linkages may exist for different members of this series. The structures of these complexes are discussed in the light of recent X-ray crystal structure data. Halogens and hydrogen halides add to give the familiar RuX3(NO)(PPh3)2; RuCl3(NO)(PPh2Me)2 is prepared in a direct reaction and also by phosphine exchange and 1H n.m.r. data confirm that the phosphine ligands are trans. The complexes RuX(CO)(NO)(PPh3)2 react readily with O2 to form the dioxygen complexes Ru(O2)X(NO)(PPh3)2. Halogens and hydrogen halides produce RuX3(NO)(PPh3)2. The dioxygen complexes react with SO2 and N2O4 to give sulphato and dinitrato complexes respectively. The reaction with CO results in the intramolecular oxidation of the nitrosyl group to coordinated nitrate accompanied by the incorporation of two moles of CO, i.e. RuX(NO3)(CO)2(PPh3)2 is formed. The dioxygen complexes catalytically oxidise triphenylphosphine or triphenylarsine to the respective oxides and RuX(NO)(PPh3)2 can be isolated from this cycle. Reactions of these four-coordinated complexes with O2, CO, Cl2 and NOBF4 are recorded. The dinitrosyl complex Ru(NO)2(PPh3)2 is reported from a number of syntheses, the most successful being via a ligand reaction when RuCl2(CO)2(PPh3)2 is heated with NaNO2 and Ph3P in dimethyl formamide. The P-tolyldiphenylphosphine analogue is also reported and the mono-substituted product Ru(NO)2(PPh3)[P(OPh)3] is produced in an exchange reaction between Ru(NO)2(PPh3)2 and excess triphenylphosphite. This phosphite complex reacts with Ph3P and O2 to produce Ru(O2)(NO2)(NO)PPh3)2 by an atom transfer process. Ru(NO)2(PPh3)2 reacts with the acids HY (Y = BF4, PF6, ClO4) and O2 to give the dinitrosyl cations [Ru(OH)(NO)2(PPh3)2]+Y- in which the two nitrosyl groups are structurally and electronically inequivalent. [RuCl(NO)2(PPh3)2]BF4 is reported and reactions of these dinitrosyl cations with halide ions to give RuX2(NO3)(NO)(PPh3)2, with intramolecular oxidation of the NO group, are also described. OsCl2(OH)(NO)(PPh3)2 reacts irreversibly with alcohols to form OsCl2(OR)(NO)(PPh3)2 (R = CH3, C2H5, n-C3H7, (CH3O)CH2CH2) which readily undergo hydride abstraction to form OsHCl2(NO)(PPh3)2. Sodium borohydride converts this complex to the trihydrido species OsH3(NO)(PPh3)2 and if the reaction is performed in the presence of Ph3P, OsH(NO)(PPh3)3 results. The coordinated perchlorate complex OsHCl(OClO3)(NO)(PPh3)2 results form the reaction of OsHCl2(NO)(PPh3)2 with silver perchlorate; this is readily reversed by chloride ions or the solvents CH2Cl2 and CHCl3. This perchlorato complex also arises from the reaction of OsH(CO)(NO)(PPh3)2 with HClO4 and a related tetrafluoroborato complex, OsH(OC2H5)(FBF3)(NO)(PPh3)2 by substituting HBF4. This complex reacts with Ph3P to give [OsH(OH)(NO)(PPh3)3]BF4, CO to give [Os(CO)2(NO)(PPh3)2]BF4 and LiX (X = Br, I) to give OsHX2(NO)(PPh3)2. OsHCl(OClO3)(NO)(PPh3)2 reacts with NaOH in methanol, in the presence of O2 to produce Os(O2)Cl(NO)(PPh3)2. This dioxygen complex is far less stable than the ruthenium analogue but it undergoes similar reactions. Ph3P is oxidised, SO2 and CO give sulphato and a nitratodicarbonyl complex respectively. Infra-red, 1H n.m.r., conductivity, molecular weight data and elemental analysis have been used in formulation and structural assignment.

Nitrosyl complexes of ruthenium and osmium

Laing, Kerry Richard

January 1972

This study concerns the synthesis, structure and reactivity of nitrosyl complexes of ruthenium and osmium. Attempts have been made to prepare coordinatively saturated and unsaturated complexes and a study of their oxidative addition reactions bears considerable resemblance to the more familiar carbonyl complexes M(CO)3(PPh3)2. A number of interesting atom transfer reactions, generally involving oxygen, have been observed. The d8 complex RuCl(CO)(NO)(PPh3)2 results from the interaction of RuHCl(CO)(PPh3)3 with N-methyl-N-nitrosotoluene-p-sulphonamide. The labile halide ligand is readily displaced by a large range of anions and it is believed that both linear and bent nitrosyl linkages may exist for different members of this series. The structures of these complexes are discussed in the light of recent X-ray crystal structure data. Halogens and hydrogen halides add to give the familiar RuX3(NO)(PPh3)2; RuCl3(NO)(PPh2Me)2 is prepared in a direct reaction and also by phosphine exchange and 1H n.m.r. data confirm that the phosphine ligands are trans. The complexes RuX(CO)(NO)(PPh3)2 react readily with O2 to form the dioxygen complexes Ru(O2)X(NO)(PPh3)2. Halogens and hydrogen halides produce RuX3(NO)(PPh3)2. The dioxygen complexes react with SO2 and N2O4 to give sulphato and dinitrato complexes respectively. The reaction with CO results in the intramolecular oxidation of the nitrosyl group to coordinated nitrate accompanied by the incorporation of two moles of CO, i.e. RuX(NO3)(CO)2(PPh3)2 is formed. The dioxygen complexes catalytically oxidise triphenylphosphine or triphenylarsine to the respective oxides and RuX(NO)(PPh3)2 can be isolated from this cycle. Reactions of these four-coordinated complexes with O2, CO, Cl2 and NOBF4 are recorded. The dinitrosyl complex Ru(NO)2(PPh3)2 is reported from a number of syntheses, the most successful being via a ligand reaction when RuCl2(CO)2(PPh3)2 is heated with NaNO2 and Ph3P in dimethyl formamide. The P-tolyldiphenylphosphine analogue is also reported and the mono-substituted product Ru(NO)2(PPh3)[P(OPh)3] is produced in an exchange reaction between Ru(NO)2(PPh3)2 and excess triphenylphosphite. This phosphite complex reacts with Ph3P and O2 to produce Ru(O2)(NO2)(NO)PPh3)2 by an atom transfer process. Ru(NO)2(PPh3)2 reacts with the acids HY (Y = BF4, PF6, ClO4) and O2 to give the dinitrosyl cations [Ru(OH)(NO)2(PPh3)2]+Y- in which the two nitrosyl groups are structurally and electronically inequivalent. [RuCl(NO)2(PPh3)2]BF4 is reported and reactions of these dinitrosyl cations with halide ions to give RuX2(NO3)(NO)(PPh3)2, with intramolecular oxidation of the NO group, are also described. OsCl2(OH)(NO)(PPh3)2 reacts irreversibly with alcohols to form OsCl2(OR)(NO)(PPh3)2 (R = CH3, C2H5, n-C3H7, (CH3O)CH2CH2) which readily undergo hydride abstraction to form OsHCl2(NO)(PPh3)2. Sodium borohydride converts this complex to the trihydrido species OsH3(NO)(PPh3)2 and if the reaction is performed in the presence of Ph3P, OsH(NO)(PPh3)3 results. The coordinated perchlorate complex OsHCl(OClO3)(NO)(PPh3)2 results form the reaction of OsHCl2(NO)(PPh3)2 with silver perchlorate; this is readily reversed by chloride ions or the solvents CH2Cl2 and CHCl3. This perchlorato complex also arises from the reaction of OsH(CO)(NO)(PPh3)2 with HClO4 and a related tetrafluoroborato complex, OsH(OC2H5)(FBF3)(NO)(PPh3)2 by substituting HBF4. This complex reacts with Ph3P to give [OsH(OH)(NO)(PPh3)3]BF4, CO to give [Os(CO)2(NO)(PPh3)2]BF4 and LiX (X = Br, I) to give OsHX2(NO)(PPh3)2. OsHCl(OClO3)(NO)(PPh3)2 reacts with NaOH in methanol, in the presence of O2 to produce Os(O2)Cl(NO)(PPh3)2. This dioxygen complex is far less stable than the ruthenium analogue but it undergoes similar reactions. Ph3P is oxidised, SO2 and CO give sulphato and a nitratodicarbonyl complex respectively. Infra-red, 1H n.m.r., conductivity, molecular weight data and elemental analysis have been used in formulation and structural assignment.

Radioimunoensaio do hormonio triiodotironina (Tsub(3)) no soro. Desenvolvimento de uma tecnica de fase solida e comparacao com duas tecnicas de fase liquida: polietileno glicol (PEG) e duplo anticorpo.

HAMADA, MARGARIDA M.

09 October 2014

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triiodothyronine

radioimmunoassay

peptide hormones

iodine 125

reaction kinetics

separation process

comparative evaluations