| Record ID | marc_columbia/Columbia-extract-20221130-028.mrc:2073794:8044 |
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LEADER: 08044cam a2200637 a 4500
001 13502766
005 20181022143230.0
008 070524t20082008enkaf b 001 0 eng
010 $a 2007022146
015 $aGBA743082$2bnb
016 7 $a013761354$2Uk
019 $a779895823
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040 $aDLC$beng$cDLC$dUKM$dBAKER$dBTCTA$dYDXCP$dBWKUK$dBWX$dCDN$dDEBBG$dOCL$dEUM$dOCL$dOCLCQ$dDEBSZ$dBDX$dOHS$dTULIB$dOCLCF$dOCLCO$dOCLCQ$dOCLCO$dOCLCQ$dFDA$dLGG$dS3O$dOCLCQ$dMNX$dIOG$dOCLCO$dDHA$dIPL$dOCLCO$dOCLCA$dOCLCQ$dOCLCO$dOCLCQ$dCCH$dMNI
050 00 $aQC793.3.S6$bL47 2008
082 00 $a538/.362$222
084 $aUM 3500$2rvk
084 $aVE 8600$2rvk
084 $aVG 9500$2rvk
084 $aCHE 244f$2stub
084 $aCHE 160f$2stub
084 $aPHY 517f$2stub
100 1 $aLevitt, Malcolm H.,$eauthor.
245 10 $aSpin dynamics :$bbasics of nuclear magnetic resonance /$cMalcolm H. Levitt.
250 $aSecond edition.
264 1 $aChichester, England ;$aHoboken, NJ :$bJohn Wiley & Sons, Ltd,$c[2008]
264 4 $c©2008
300 $axxv, 714 pages, 7 unnumbered pages of plates :$billustrations (some color) ;$c26 cm
336 $atext$btxt$2rdacontent
337 $aunmediated$bn$2rdamedia
338 $avolume$bnc$2rdacarrier
504 $aIncludes bibliographical references and index.
520 $a'Spin Dynamics' focuses on those essential principles and concepts needed for a thorough understanding of the subject, rather than its practical aspects.
505 0 $aNuclear magnetism. Matter ; Magnetism ; NMR spectroscopy -- The NMR experiment. The NMR spectrometer ; Fourier transform NMR -- Quantum mechanics. Mathematical techniques ; Review of quantum mechanics -- Nuclear spin interactions. Nuclear spin Hamiltonian ; Internal spin interactions -- Uncoupled spins. Single spin-1/2 ; Ensemble of spins-1/2 ; Experiments on non-interacting spins-1/2 ; Quadrupolar nuclei -- Coupled spins. Spin-1/2 pairs ; Homonuclear AX system ; Experiments on AX systems ; Many-spin systems ; Many-spin dynamics -- Motion and relaxation. Motion ; Relaxation.
650 0 $aNuclear spin.
650 0 $aNuclear magnetic resonance.
650 7 $aNuclear magnetic resonance.$2fast$0(OCoLC)fst01040325
650 7 $aNuclear spin.$2fast$0(OCoLC)fst01040897
650 7 $aNMR-Spektroskopie$2gnd$0(DE-588)4075421-2
650 7 $aKärnspinnresonans.$2sao
650 4 $aNuclear spin.
650 4 $aNuclear magnetic resonance.
650 2 $aMagnetic Resonance Spectroscopy.
856 41 $3Table of contents$uhttp://catdir.loc.gov/catdir/toc/ecip0719/2007022146.html
856 41 $3Table of contents$uhttp://bvbr.bib-bvb.de:8991/F?func=service&doc_library=BVB01&doc_number=015926414&line_number=0001&func_code=DB_RECORDS&service_type=MEDIA
856 41 $3Table of contents$qapplication/pdf$uhttp://www.ulb.tu-darmstadt.de/tocs/202093794.pdf$v20090711000000
856 42 $3Publisher description$uhttp://catdir.loc.gov/catdir/enhancements/fy0826/2007022146-d.html
856 4 $qimage/jpeg$uhttp://swbplus.bsz-bw.de/bsz27884278xcov.htm$v20090320124457$3Cover
880 0 $6505-00$aPart 1: Nuclear magnetism. Matter. Atoms and nuclei ; Spin ; Nuclei ; Nuclear spin ; Atomic and molecular structure ; States of matter -- Magnetism. The electromagnetic field ; Macroscopic magnetism ; Microscopic magnetism ; Spin precession ; Larmor frequency ; Spin-lattice relaxation: nuclear paramagnetism ; Transverse magnetization and transverse relaxation ; NMR signal ; Electronic magnetism -- NMR spectroscopy. A simple pulse sequence ; A simple spectrum ; Isotopomeric spectra ; Relative spectral frequencies: Case of positive gyromagnetic ratio ; Relative spectral frequencies: Case of negative gyromagnetic ratio ; Inhomogeneous broadening ; Chemical shifts ; J-coupling multiplets ; Heteronuclear decoupling. Part 2: The NMR experiment. The NMR spectrometer. The magnet ; The transmitter section ; The duplexer ; The probe ; The receiver section ; Overview of the radio-frequency section ; Pulsed field gradients -- Fourier transform NMR. A single-pulse experiment ; Signal averaging ; Multiple-pulse experiments: Phase cycling ; Heteronuclear experiments ; Pulsed field gradient sequences ; Arrayed experiments ; NMR signal ; NMR spectrum ; Two-dimensional spectroscopy ; Three-dimensional spectroscopy. Part 3: Quantum mechanics. Mathematical techniques. Functions ; Operators ; Eigenfunctions, eigenvalues and eigenvectors ; Diagonalization ; Exponential operators ; Cyclic commutation -- Review of quantum mechanics. Spinless quantum mechanics ; Energy levels ; Natural units ; Superposition states and stationary states ; Conservation laws ; Angular momentum ; Spin ; Spin-1/2 ; Higher spin. Part 4: Nuclear spin interactions. Nuclear spin Hamiltonian. Spin Hamiltonian hypothesis ; Electromagnetic interactions ; External and internal spin interactions ; External magnetic fields ; Internal spin Hamiltonian ; Motional averaging -- Internal spin interactions. Chemical shift ; Electric quadrupole coupling ; Direct dipole-dipole coupling ; J-coupling ; Spin-rotation interaction ; Summary of the spin Hamiltonian terms. Part 5: Uncoupled spins. Single spin-1/2. Zeeman eigenstates ; Measurement of angular momentum: quantum indeterminacy ; Energy levels ; Superposition states ; Spin precession ; Rotating frame ; Precession in the rotating frame ; Radio-frequency pulse -- Ensemble of spins-1/2. Spin density operator ; Populations and coherences ; Thermal equilibrium ; Rotating-fram density operator ; Magnetization vector ; Strong radio-frequency pulse ; Free precession without relaxation ; Operator transformations ; Free evolution with relaxation ; Magnetization vector trajectories ; NMR signal and NMR spectrum ; Single-pulse spectra -- Experiments on non-interacting spins-1/2. Inversion recovery: Measurement of T₁ ; Spin echoes: Measurement of T₂ ; Spin locking: Measurement of T₁ρ ; Gradient echoes ; Slice selection ; NMR imaging -- Quadrupolar nuclei. Spin I = 1 ; Spin I = 3/2 ; Spin I = 5/2 ; Spins I = 7/2 ; Spins I = 9/2. Part 6: Coupled spins. Spin-1/2 pairs. Coupling regimes ; Zeeman product states and superposition states ; Spin=pair Hamiltonian ; Pairs of magnetically equivalent spins ; Weakly coupled spin pairs -- Homonuclear AX system. Eigenstates and energy levels ; Density operator ; Rotating frame ; Free evolution ; Spectrum of the AX system: Spin-spin splitting ; Product operators ; Thermal equilibrium ; Radio-frequency pulses ; Free evolution of the product operators ; Spin echo sandwich -- Experiments on AX systems. COSY ; INADEQUATE ; INEPT ; Residual dipolar couplings -- Many-spin systems. Molecular spin system ; Spin ensemble ; Motionally suppressed J-couplings ; Chemical equivalence ; Magnetic equivalence ; Weak coupling ; Heteronuclear spin systems ; Alphabet notation ; Spin coupling topologies -- Many-spin dynamics. Spin Hamiltonian ; Energy eigenstates ; Superposition states ; Spin density operator ; Populations and coherences ; NMR spectra ; Many-spin product operators ; Thermal equilibrium ; Radio-frequency pulses ; Free precession ; Spin echo sandwiches ; INEPT in an I₂S system ; COSY in multiple-spin systems ; TOCSY. Part 7: Motion and relaxation. Motion. Motional processes ; Motional time-scales ; Motional effects ; Motional averaging ; Motional lineshapes and two-site exchange ; Sample spinning ; Longitudinal magnetization exchange ; Diffusion -- Relaxation. Types of relaxation ; Relaxation mechanisms ; Random field relaxation ; Dipole-dipole relaxation ; Steady-state nuclear Overhauser effect ; NOESY ; ROESY ; Cross-correlated relaxation. Part 8: Appendices.
852 00 $bsci$hQC793.3.S6$iL47 2008