1、单击此处编辑母版标题样式,单击此处编辑母版文本样式,第二级,第三级,第四级,第五级,*,*,二维核磁共振谱原理专业知识,COSY:Hypothetical Coupling,COSY:1H-1H Coupling,Coupling networks can be traced out,as shown in the figure below.,The colored arrows trace out coupling networks,corresponding to:,H-3 H-5 H-10 OH,H-10-H-9,H-3 H-16,H-16 H-11,COSY Spectrum of C
2、odeine,Table of COSY correlations,shift,shift,Assignments,6.6,6.7,7-8,5.7,5.3,3-5,5.7,2.7,3-16,5.7,4.9,3-9 weak,5.3,4.2,5-10,5.3,2.7,5-16,4.9,4.2,9-10,4.2,2.9,10-OH,3.3,2.7,11-16,3.3,2.4,11-14,3.3,2.3,11-18,3.0,2.4,18-14,3.0,2.3,18-18,2.6,2.4,13-13,2.6,2.1,13-17,2.6,1.9,13-17,2.4,2.1,13-17,2.4,1.9,1
3、3-17,2.1,1.9,17-17,COSY Spectrum of Codeine,What You See In a NOESY.,突出体现,NOE,效应旳,NOESY,谱,NOESY.,NOESY Spectrum of Codeine,The sample is 3.3 mg of codeine in.65 ml CDCl,3,A contour plot of the NOESY spectrum is shown below.As with all homonuclear 2D plots,the diagonal consists of intense peaks that
4、match the normal spectrum,as do projections onto each axis.The interesting information is contained in the cross-peaks,which appear at the coordinates of 2 protons which have an NOE correlation.,For small molecules,the NOE is negative.Exchange peaks have the opposite sign from NOE peaks,making them
5、easy to identify.The water peak at 1.5 ppm exchanges with the OH at 2.9 ppm,shown here in red.,The spectrum is phased with the large diagonal peaks inverted(shown in red here),so the NOE cross-peaks are positive.,Expansion of the upfield region:,8-7,127-18,183-5,105-11,16,189-10,17,1710-1611-18,16,1
6、4,1818-13,1816-14,1713-14,17,1713-17,1717-17,NOESY Spectrum of Codeine,Table of NOEs:(indicates the more upfield of geminal CH,2,protons),In addition to confirming assignments,the NOESY spectrum allows stereospecific assignments of methylene Hs.The 3 cross-peaks indicated in red on the plot below di
7、stinguish between the 3 CH,2,pairs:,5-1816-1718-13,NOESY Spectrum of Codeine,2 D C-H,有关谱(,C-H COSY),2 D,远程,C-H COSY,Heteronuclear Multiple Quantum Coherence(HMQC)and Heteronuclear Multiple Bond Coherence(,HMBC,):,2-D inverse H,C correlation techniques that allow for the determination of carbon(or ot
8、her heteroatom)to hydrogen connectivity.,Gradient HMBC(gHMBC)improves the acquired spectra by significantly,reducing unwanted signal artifacts.,HMQC is selective for direct C-H coupling,HMBC will give longer range couplings(2-4 bond coupling).,HMQC and HMBC,HMQC(,trans,-ethyl 2-butenoate),HMQC Heter
9、onuclear Multiple-Quantum Coherence Experiment,C(9)-H,C(9)-H,HMQC Heteronuclear Multiple-Quantum Coherence Experiment,HMQC(1-Bond CH Correlation)of Codeine,1,H,13,C,Assignment,6.6,113,8,6.5,120,7,5.7,133,3,5.3,128,5,4.8,91,9,4.2,66,10,3.8,56,12,3.3,59,11,3.0&2.3,20,18,2.6,40,16,2.6&2.4,46,13,2.4,43,
10、14,2.0&1.8,36,17,This is a 2D experiment used to correlate,or connect,1H and 13C peaks for atoms separated by multiple bonds(usually 2 or 3).,The coordinates of each peak seen in the contour plot are the 1H and 13C chemical shifts.This is extremely useful for making assignments and mapping out coval
11、ent structure.,The information obtained is an extension of that obtained from an,HMQC,spectrum,but is more complicated to analyze.Like HMQC,this is an inverse detection experiment,and is possible only on newer model spectrometers.,Acorn NMRs new JEOL Eclipse+400 is equipped to perform inverse experi
12、ments,and uses Z-gradients for improved spectral quality.,The time required for an HMBC depends on the amount of material,but is much greater than for HMQC,and can take from an hour to overnight.,HMBC(Multiple-Bond CH Correlation)of Codeine,Peaks occur at coordinates in the 2 dimensions correspondin
13、g to the chemical shifts of a carbon and protons separated by(usually)2 or 3 bonds.,The experiment is optimized for couplings of 8 Hz.Smaller couplings are observed,but their intensities are reduced.,Compare to the spectrum obtained when the experiment is optimized for,4 Hz,.,The experiment is desig
14、ned to suppress 1-bond correlations,but a few are observed in most spectra.In concentrated samples of conjugated systems,4-bond correlations can be observed.,There is no way to know how many bonds separate an H and C when a peak is observed,so analysis is a process of attempting to assign all observ
15、ed peaks,testing for consistency and checking to be sure none of the assignments would require implausible or impossible couplings.,Because of the large number of peaks observed,analysis requires several expanded plots.In this case,the spectrum has been divided into 4 sections,each of which is discu
16、ssed below.,HMBC(Multiple-Bond CH Correlation)of Codeine,HMBC(Multiple-Bond CH Correlation)of Codeine,The discussion below uses the numbering system shown at right.,The numbers were assigned to peaks in the 1D 13C spectrum,starting downfield,moving upfield,and numbering each sequentially.This genera
17、tes a unique identifier for each Carbon,even before knowing any assignments.,HMBC(Multiple-Bond CH Correlation)of Codeine,C9-H,C3-H,C5-H,1,2,3,4,5,6,C9-H,C3-H,C5-H,17,HMBC(Multiple-Bond CH Correlation)of Codeine,More 1D and 2D-Sepctra for Codeine,1D,1,H and,13,C NMR Spectra of Codeine,C,18,H,21,NO,3
18、MW=299.4,Data acquired on a JEOL Eclipse,+,400 spectrometer,1,H spectrum:,C3-H,C5-H,C10-H,C7-H,C8-H,C9-H,C12-H3,C11-H,C16-H,C18-H,C18-H,C17-H,C14-H,C3-H,C5-H,C9-H,C3-H,C5-H,13,C spectra,18 mg sample,1.3 hrs acquisition time,1,2,3,4,5,6,7,9,10,11,12,13,14,15,16,17,18,1D,1,H and,13,C NMR Spectra of C
19、odeine,Peak Assignments for Codeine,13,C(ppm),1,H(ppm),1,146.3,q,2,142.23,q,3,133.43,CH,5.71,4,131.13,q,5,128.30,CH,5.29,6,127.30,q,7,119.58,CH,6.57,8,113.03,CH,6.66,9,91.39,CH,4.89,10,66.43,CH,4.18,11,58.92,CH,3.35,12,56.40,CH,3,3.84,13,46.47,CH,2,2.59,2.40,14,43.12,CH,3,2.44,15,42.99,q,16,40.82,CH
20、2.67,17,35.85,CH,2,2.06,1.88,18,20.46,CH,2,3.04,2.30,OH,2.99,Both experiments are used to identify multiplicity(quaternary,CH,CH,2,or CH,3,)of peaks in a,13,C spectrum.Usually,DEPT is preferred because much less time is required.For DEPT,1,H magnetization is generated first,then transferred to,13,C
21、This polarization transfer enhances sensitivity.Also,the experiment repetition rate is dependent on relaxation of,1,H,rather than,13,C,so a shorter delay is needed.DEPT also can distinguish between CH and CH,3,unlike APT,although quaternary Cs are not observed in DEPT.,The sample is 18 mg of codein
22、e in.65 ml CDCl,3,DEPT and APT spectra of codeine,DEPT-135 CH and CH,3,peaks up,CH,2,peaks invertedDEPT-90 CH peaks onlyDEPT-45 all protonated carbons normal,13,C spectrum,13,C(ppm),1,146.3,2,142.23,3,133.43,4,131.13,5,128.30,6,127.30,7,119.58,8,113.03,9,91.39,10,66.43,11,58.92,12,56.40,13,46.47,14,43.12,15,42.99,16,40.82,17,35.85,18,20.46,DEPT Spectra,






