The preparation of [15N]- and [1-13C]-2-naphthylamine and their conversions into [15N, 15N′]- and [1,1′-13C2]-2,2′-azonaphthalene

## REFERENCE DATA carbons, for various substituent groups and positions were carried out by gated decoupling with NOE. ## RESULTS AND DISCUSSION The I3C NMR chemical shifts of the compounds are shown in Tables 123; 'J(CH) and long-range coupling constants of 2, 9, 13 and 18, measured by gated d

## Abstract We report here the syntheses of tetrazole‐^13^C and 1,2,4‐triazole‐1,2‐^15^N~2~ by simple, one‐step procedures using common, commercially available, isotopically‐labeled starting materials. tetrazole‐ ^13^C is conveniently prepared from K^13^CN and NaN~3~ in 70% yield, almost twice the

Three isotopically enriched samples of ethylenimine [aziridine] hare been prepared, namely, mixtures containing ca. 50 % [2-D]ethylenimine, 25 % [2,2'-Dzlethylenimine, and 25 % parent molecule; 97 % f15N]ethylenimine and 3 parent molecule; 64 % [Wlethylenimine and 36 % parent molecule. Infrared gas

The Preparation of [15N,15N']-and [4,4'-13 C2]-4,4'-Dichloroazobenzene and [ , Nt]-4-Chloroazobenzene 15N 15

## Abstract ^13^C and ^15^N NMR chemical shifts were measured for __N__^1^‐alkyl‐__N__^2^‐arylthioureas. The absence of decoalescence of the __N__^1^‐alkyl group carbon signals down to 190 K, the europium‐induced chemical shifts and the molecular mechanics calculations indicate that the preferred c

A high-yield synthesis of [1-15 N]-2Ј-deoxyinosine ( 5), [4-counterpart, through [1-15 N]-2Ј-deoxyinosine (5), and successively, [4-15 N]-2Ј-deoxyAICAR ( 7). [1-15 N]-2Ј-15 N]-2Ј-deoxyAICAR (7), and [1-15 N]-2Ј-deoxyguanosine (10) from 2Ј-deoxyinosine (1) using relatively low expensive Deoxyguanosi