有機(jī)化學(xué)中的光譜方法

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作　者：	（英）威廉姆斯著
出版社：	世界圖書(shū)出版公司
叢編項(xiàng)：
標(biāo)　簽：	有機(jī)化學(xué)

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ISBN：	9787510004506	出版時(shí)間：	2009-05-01	包裝：	平裝
開(kāi)本：	16開(kāi)	頁(yè)數(shù)：	291	字?jǐn)?shù)：

內(nèi)容簡(jiǎn)介

　　《有機(jī)化學(xué)中的光譜方法（第6版）》是一本由英國(guó)劍橋大學(xué)D. H. Williams和I. Fleming合著的有機(jī)化學(xué)光譜方法經(jīng)典教材。第1版出版于1966年，《有機(jī)化學(xué)中的光譜方法（第6版）》為第6版。書(shū)中講述了近年來(lái)迅猛發(fā)展的二維核磁共振（如Tocsy、遠(yuǎn)‘H-13C COSY）、MALDI、FT-ICR、TOF等新技術(shù)。與時(shí)俱進(jìn)，本版較前版在內(nèi)容上做了較大的改動(dòng)，有關(guān)UV和IR光譜的部分講述的更加準(zhǔn)確；豐富了關(guān)于NMR的內(nèi)容；介紹MS的部分更加講求結(jié)合實(shí)際。全書(shū)共分為五章，第1章為紫外和可見(jiàn)光譜，論述了電子吸收光譜在測(cè)定有機(jī)基團(tuán)中的應(yīng)用；第2章紅外光譜，闡述了傅里葉紅外和喇曼光譜的樣品制備、光譜選律以及各官能團(tuán)的特征吸收頻率；第3章核磁共振波譜，主要介紹了‘H和13C核磁共振的經(jīng)驗(yàn)參數(shù)、各種二維NMR的具體應(yīng)用；第4章質(zhì)譜，介紹了各種粒子譜以及氣相和液相色譜與質(zhì)譜的聯(lián)用；第5章實(shí)例和習(xí)題，為讀者提供了一些選自研究課題、具有啟發(fā)性的實(shí)例，也為讀者鞏固所學(xué)的知識(shí)提供了練習(xí)。《有機(jī)化學(xué)中的光譜方法（第6版）》理論和實(shí)踐并舉，因此也適合有機(jī)化學(xué)工作者做為手冊(cè)使用。讀者對(duì)象：高校化學(xué)系師生、有關(guān)研究人員。

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圖書(shū)目錄

Preface
Chapter 1： Ultraviolet and visible spectra
1.1 Introduction
1.2 Chromophores
1.3 The absorption laws
1.4 Measurement of the spectrum
1.5 Vibrational fine structure
1.6 Choice of solvent
1.7 Selection rules and intensity
1.8 Solvent effects
1.9 Searching for a chromophore
1.10 Definitions
1.11 Conjugated dienes
1.12 Polyenes
1.13 Polyeneynes and poly-ynes
1.14 Ketones and aldehydes; π-π* transitions
1.15　Ketones and aldehydes; π-π* transitions
1.16　α，β-Unsaturated acids， esters， nitriles and amides
1.17　The benzene ring
1.18　Substituted benzene rings
1.19　Polycyclic aromatic hydrocarbons
1.20　Heteroaromatic compounds
1.21　Quinones
1.22　Corroles， chlorins and porphyrins
1.23　Non-conjugated interacting chromophores
1.24　The effect ofsteric hindrance to coplanarity
1.25　Internet
1.26　Bibliography
Chapter 2： Infrared spectra
2.1　Introduction
2.2　Preparation of samples and examination in an infrared spectrometer
2.3　Examination in a Raman spectrometer
2.4　Selection rules
2.5　The infrared spectrum
2.6　The use of the tables of characteristic group frequencies
2.7　Absorption frequencies of single bonds to hydrogen 3600-2000 cm-
2.8 Absorption frequencies of triple and cumulated double bonds2300-1930 cm-
2.9 Absorption frequencies of the double-bond region 1900-1500 em-1
2.10　Groups absorbing in the fingerprint region <1500 cm-1
2.11 Internet
2.12　Bibliography
2.13 Correlation charts
2.14　Tables of data
Chapter 3： Nuclear magnetic resonance spectra
3.1 Nuclear spin and resonance
3.2 The measurement of spectra
3.3 The chemical shift
3.4 Factors affecting the chemical shift
3.4.1 Intramolecular factors affecting the chemical shift
3.4.2 Intermolecular factors affecting the chemical shift
3.5 Spin-spin coupling to 13C
3.5.1 13C-2H Coupling
3.5.2 13C-1H Coupling
3.5.3 13C-13C Coupling
3.6 1H-1H Vieinal coupling (3JHH)
3.7 1H-1H Geminal coupling (2JHH)
3.8 1H-1H Long-range coupling (4JHH and 5JHH)
3.9 Deviations from first-order coupling
3.10　The magnitude of 1H-1H coupling constants
3.10.1　Vicinal coupling 3JHH
3.10.2　Geminal coupling (2JHH)
3.10.3　Long-range coupling (4JHH and 5JHH)
3.11 Line broadening and environmental exchange
3.11.1　Efficient relaxation
3.11.2　Environmental exchange
3.12　Improving the NMR spectrum
3.12.1　The effect of changing the magnetic field
3.12.2　Shift reagents
3.12.3　Solvent effects
3.13　Spin decoupling
3.13.1　Simple spin decoupling
3.13.2　Difference decoupling
3.14　The nuclear Overhanser effect
3.14.1　Origins
3.14.2　NOE Difference spectra
3.15　Assignment ofCH3， CH2， CH and quaternary carbons in 13C NMR
3.16　Identifying spin systems——1D-TOCSY
3.17 The separation of chemical shift and coupling onto different axes
3.18 Two-dimensional NMR
3.19 COSY spectra
3.20 NOESY spectra
3.21 2D-TOCSY spectra
3.22 1H-13C COSY spectra
3.22.1　Heteronuclear Multiple Quantum Coherence (HMQC) spectra
3.22.2　Heteronuclear Multiple Bond Connectivity (HMBC) spectra
3.23 Measuring 13C-IH coupling constants (HSQC-HECADE spectra)
3.24 Identifying 13C-13C connections (INADEQUATE spectra)
3.25 Three- and four-dimensional NMR
3.26 Hints for spectroscopic interpretation and structure determination
3.26.1 Carbon spectra
3.26.2 Proton spectra
3.26.3 Hetero-correlations
3.27 Internet
3.28 Bibliography
3.29 Tables of data
Chapter4： Mass spectra
4.1 Introduction
4.2 Ion production from readily volatile molecules
4.2.1 Electron impact (EI)
4.2.2 Chemical Ionisation (CI)
4.3 Ion production from poorly volatile molecules
4.3.1 Fast ion bombardment (FIB or LSIMS)
4.3.2 Laser desorption (LD) and matrix-assisted laser desorption (MALDI)
4.3.3 Electrospray ionisation (ESI)
4.4 Ion analysis
4.4.1 Magnetic analysers
4.4.2 Combined magnetic and electrostatic analysers——high-resolution mass spectra (HRMS)
4.4.3 Ion cyclotron resonance (ICR) analysers
4.4.4 Time-of-flight (TOF) analysers
4.4.5 Quadrupole analysers
4.4.6 Ion-trap analysers
4.5 Structural information from mass spectra
4.5.1 Isotopic abundances
4.5.2 EI spectra
4.5.3 CI spectra
4.5.4 FIB (LSMIS) spectra
4.5.5 MALDI spectra
4.5.6 ESI spectra
4.5.7 ESI-FT-ICR and ESI-FT-Orbitrap spectra
4.6 Separation coupled to mass spectrometry
4.6.1 GC/MS and LC/MS
4.6.2 MS/MS
4.7 MS data systems
4.8 Specific ion monitoring and quantitative MS (SIM and MIM)
4.9 Interprcting the spectrum of an unknown
4.10 Internet
4.11 Bibliography
4.12 Tables of data
Chapter 5： Practice in structure determination
5.1 General approach
5.2 Simple worked examples using 13C NMR alone
5.3 Simple worked examples using 1H N-MR alone
5.4 Simple worked examples using the combined application of all fourspectroscopic ethods
5.5 Simple problems using 13C NMR or joint application of IR and 13C NMR
5.6 Simple problems using 1H NMR
5.7 Problems using a combination of spectroscopic methods
5.8 Answers to problems 1-33
Index