Patent ID: 6184683
Filing Date: 2001-02-06
Classification: G01R

Abstract:
A method of two-dimensional, heteronuclear correlation spectroscopy for the investigation of solid state samples, containing a first (.sup.1 H) and a second (.sup.13 C) nuclear species, in a nuclear magnetic resonance (NMR) spectrometer by means of an NMR pulse sequence, which pulse sequence comprises a preparation interval, an evolution interval, a mixing interval and a detection interval, wherein during the preparation interval the first nuclear species is excited by at least one preparation RF pulse in a first frequency band and is exposed to evolution RF pulses inside the first frequency band during the evolution interval and wherein during the detection interval the first nuclear species is exposed to at least one decoupling RF pulse inside the first frequency band while the free induction decay in the second frequency band is detected and wherein the pulse sequence (1.ltoreq.p.ltoreq.n) is repeated n times in a row with identical preparation interval, mixing interval and detection interval but with changed evolution interval and wherein the sample rotates with a rotation frequency greater than 1 kHz about an axis which is tilted by about 54.degree. with respect to the axis of a homogeneous magnetic field and wherein the at least one preparation RF pulse is broad-banded with a center frequency in the center of the NMR spectrum of the first nuclear species of the sample effecting a rotation of the nuclear magnetization of the first nuclear species about an axis perpendicular to the direction of the magnetic field (X) with an angle of preferably 90.degree. and wherein the evolution RF pulses form a so-called FSLG sequence with two successive broadband evolution RF pulses, phase shifted with respect to each other by 180.degree. (Y, -Y), whose center frequencies are shifted in opposite directions with respect to the preparation RF pulse and which each effect a rotation of the nuclear magnetization of the first nuclear species by about 294.degree.,wherein during the preparation interval the first nuclear species is irradiated with CP radio frequency pulses in the first frequency band in order to transfer the nuclear magnetization to the second nuclear species, and the second nuclear species is irradiated in a second frequency band with at least one excitation radio frequency pulse, the mixing interval is split into two partial intervals, the first of which is located between preparation and evolution interval, and the second one between evolution interval and detection interval, and in both mixing partial intervals the mixing radio frequency pulses form a socalled FSLG sequence with two successive broadband evolution radio frequency pulses, phase shifted (X, -X) with respect to one another by 180.degree. with center frequencies that are shifted with respect to that of the preparation radio frequency pulse in opposite directions and which each effect a rotation of the nuclear magnetization of the first nuclear species by about 294.degree., and wherein in the center of the evolution interval the second nuclear species experiences a broadband 180.degree. refocusing pulse with a center frequency in the center of the nuclear resonance spectrum of the second nuclear species, whereby a correlation spectrum of both nuclear species is created that correlates the chemical shifts of both nuclear species for directly bonded pairs via scalar coupling.