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100   $a20090408d2009      uy         0
101 0 $aeng
135   $aur|n|---|||||
181   $ctxt
182   $cc
183   $acr
200 10$aMagnetic isotope effect in chemistry and biochemistry$b[electronic resource] /$fAnatoly Buchachenko
205   $a1st ed.
210   $aNew York $cNova Science Publishers$dc2009
215   $a1 online resource (159 p.)
300   $aDescription based upon print version of record.
311   $a1-60741-363-9 
320   $aIncludes bibliographical references and index.
327   $aIntro -- MAGNETIC ISOTOPE EFFECT IN CHEMISTRY AND BIOCHEMISTRY -- MAGNETIC ISOTOPE EFFECT IN CHEMISTRY AND BIOCHEMISTRY -- CONTENTS -- PREFACE -- INTRODUCTION -- Chapter 1    ENERGY AND ANGULAR MOMENTUM AS THE REACTION CONTROLLING FACTORS -- 1.1. ENERGY -- 1.2. ANGULAR MOMENTUM -- 1.2.1. Rotational Angular Momentum -- 1.2.2. Electron Orbital Momentum -- 1.2.3. Electron Angular Momentum: Spin States and Spin Multiplicity -- 1.2.4. Nuclear Angular Momentum and Nuclear Spin States -- Chapter 2    SPIN CONTROL OF CHEMICAL REACTIONS -- 2.1. SPIN STATES AND CHEMICAL REACTIVITY -- 2.2. MAGNETIC INTERACTIONS AND MAGNETIC EFFECTS -- Chapter 3    MAGNETIC ISOTOPE EFFECT (MIE) -- 3.1. HOW TO DISCRIMINATE CLASSICAL AND MAGNETIC ISOTOPE EFFECTS -- 3.2. MIE: HOW IT FUNCTIONS -- 3.3. MIE AS A TEST OF REACTION MECHANISM -- 3.4. NUCLEAR SPIN POLARIZATION -- 3.5. MIE AND ISOTOPE TECHNOLOGY -- 3.6. MIE: THE ROAD OF DISCOVERIES -- Chapter 4    KINETICS OF ISOTOPE FRACTIONATION -- 4.1. MEASUREMENT OF ISOTOPE COMPOSITION -- 4.2. ANALYSIS OF THE KINETIC SCHEMES -- 4.3. ABSOLUTE MEASURE OF ISOTOPE SEPARATION -- 4.4. DYNAMIC CHARACTERISTICS OF SPIN SELECTIVE NANOREACTOR -- 4.5. IS THERE A LIMIT IN MIE INDUCED ISOTOPE FRACTIONATION? -- Chapter 5    PHYSICS OF THE MIE -- 5.1. SPIN-SELECTIVE NANOREACTOR: HOW IT FUNCTIONS? -- 5.2. SPIN DYNAMICS -- 5.3. MOLECULAR DYNAMICS -- 5.4. CHEMICAL DYNAMICS -- 5.5. GENERALIZED SPIN DYNAMICS -- Chapter 6    MIE FOR DEUTERIUM-HYDROGEN DYAD -- Chapter 7    13C MIE: CONTROLLING FACTORS -- 7.1. SPIN PROHIBITION: HOW IT IS RIGOROUS -- 7.2. HYPERFINE COUPLING AND CHEMICAL REACTIVITY -- 7.3. MIE AS A FUNCTION OF THE MAGNETIC FIELD -- 7.4. VISCOSITY, LIFETIME OF RADICALS AND A SIZE OF MICROREACTORS -- 7.5. SPIN MULTIPLICITY AND COMPETITION OF RADICAL AND NON-RADICAL REACTION CHANNELS -- 7.6. MIE AS A FUNCTION OF MOLECULAR ENERGY.
327   $aChapter 8    OXYGEN MIE -- 8.1. FRACTIONATION OF ISOTOPES IN CHAIN REACTIONS OF MOLECULAR OXYGEN -- 8.2. ADDITION OF MOLECULAR OXYGEN TO RADICALS -- 8.3. INTERACTION OF PEROXY RADICALS (CHAIN TERMINATION REACTION) -- 8.4. TEMPERATURE AND VISCOSITY AS CONTROLLING FACTORS OF CHEMICAL SPIN SELECTIVITY -- 8.5. NONCHAIN PROCESSES: ENDOPEROXIDES - SYNTHESIS AND DECOMPOSITION -- 8.6. GEOCHEMICAL ANOMALIES OF 17? -- Chapter 9    SILICON MIE -- 9.1. PHOTOLYSIS OF PHENYLSILYLKETONE -- 9.2. PHOTOLYSIS OF BENZYLSILYLKETONE -- 9.3. SPIN MULTIPLICITY AND THE SIGN OF MIE -- Chapter 10    MIE FOR SULFUR, GERMANIUM AND TIN NUCLEI -- 10.1. SULFUR -- 10.2. GERMANIUM -- 10.3. TIN -- Chapter 11    URANIUM MIE -- 11.1. SPIN-SELECTIVE REACTIONS OF URANYL -- 11.2. URANIUM NANOREACTOR -- 11.2.1. Proton CIDNP -- 11.2.2. Magnetic Field Effect -- 11.3. FRACTIONATION OF URANIUM ISOTOPES -- Chapter 12    MERCURY MIE -- 12.1. MIE IN PHOTOCHEMICAL REACTIONS -- 12.2. MERCURY MIE IN ENZYMATIC PHOSPHORYLATION BY CREATINE KINASE -- Chapter 13    MAGNESIUM ISOTOPE EFFECTS -- 13.1. CLASSICAL ISOTOPE EFFECTS -- 13.2. MAGNETIC ISOTOPE EFFECTS IN ENZYMATIC PHOSPHORYLATION -- 13.2.1. Materials and Experimental Techniques -- 13.2.2. Experimental Detection of Magnesium Isotope Effects -- 13.2.3. Enzymatic Phosphorylation as a Spin-Selective Reaction -- 13.2.4. Quantitative Measure of Magnesium MIE -- 13.2.5. ATP Hydrolysis: No Isotope Effect -- 13.2.6. Magnetic Field Dependence of the Phosphorylation -- 13.2.7. Magnesium MIE Is a Key to Mechanochemistry of Enzymes as the Molecular Machines -- Chapter 14    MICROWAVE EFFECTS -- 14.1. MICROWAVE MIE -- 14.2. Biological Microwave Effects -- 14.2.1. Resonant Microwave Fields -- 14.2.2. Non-Resonant Low Frequency Fields -- ACKNOWLEDGEMENTS -- REFERENCES -- INDEX.
606   $aFree radical reactions
606   $aNuclear spin
606   $aChemical kinetics
606   $aIsotopes
615  0$aFree radical reactions.
615  0$aNuclear spin.
615  0$aChemical kinetics.
615  0$aIsotopes.
676   $a541/.38
700   $aBuchachenko$b A. L$g(Anatolii Leonidovich)$01701308
801  0$bMiAaPQ
801  1$bMiAaPQ
801  2$bMiAaPQ
906   $aBOOK
912   $a9910824161103321
996   $aMagnetic isotope effect in chemistry and biochemistry$94084960
997   $aUNINA