核磁共振基本原理7讲 吴季辉 同核去耦 图a)是正常氢谱, 它是很复杂的,因 为它属于ABCX3体 系。图(b是把去耦 场频率设置在CHO 峰上,此时谱就变 成ABX3体系。图(c) 是把去耦场频率设 置在CH峰上,这时 谱就简化为ABC体 系。图(d)是用两个 去耦场,分别对准 CHO与CH共振照射, 图611是巴豆醛CH3CH= CH-CHO的1HNMR谱及其同核去耦谱 这时谱就极简单
同核去耦 图(a)是正常氢谱, 它是很复杂的,因 为它属于ABCX 3 体 系。图(b)是把去耦 场频率设置在CHO 峰上,此时谱就变 成ABX3体系。图(c) 是把去耦场频率设 置在CH 3峰上,这时 谱就简化为ABC 体 系。图(d)是用两个 去耦场,分别对准 CHO 与CH 3共振照射, 这时谱就极简单。 核磁共振基本原理 7 讲 吴季辉
核磁共振基本原理9讲 吴季辉 谱编辑 按CH中n的奇偶性将碳分类 CH CHICH CH CH CH -Ch- Q b Q :::: CH CH 220 120 20 ppm 图81-3雌甾酮甲基醚的5 MHz13C谱(a通常的宽带去耦谱;(b)τ=4ms:此谱就按所连氢的数 目的奇偶性进行分类;()τ=1.76ms:强信号是季碳,CH是弱的,有正、负信号,CH2,CH3被压掉
谱编辑 按CHn中n的奇偶性将碳分类 核磁共振基本原理 9讲 吴季辉
Q2B 2
核磁共振基本原理10讲 吴季辉 二维谱举例一:COSY LL人 A~减 0 TTTTTTTTTTTTTYTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTT
二维谱举例一:COSY 核磁共振基本原理 10讲 吴季辉
NOE Reference A B positive NoE negative NOE FIGURE I Irradiation of resonance A leads to a increase of peak intensity of the neighboring spin C(positive NOE) or to a decrease of peak intensity (negative NOE
NOE