ライフサイエンスコーパス: hyperfine coupling constant

1 round state, and a(N) is the isotropic (14)N hyperfine coupling constant.

2 py at X-band allowed the measurement of (1)H hyperfine coupling constants.

3 anides exhibit similar, but distinguishable, hyperfine coupling constants.

4 Most strikingly, the isotropic (13)C hyperfine coupling constant (50 MHz) is far smaller than

5 gely a type 1 copper protein at low pH (with hyperfine coupling constant A( parallel) = 54 x 10(-4) c

6 indicate that electron spin resonance (ESR) hyperfine coupling constants (aH values) computed at the

7 spectra and < 8 gauss changes in the copper hyperfine coupling constants (AII) in the X-band electro

8 in the ligand moiety and the (13)C isotropic hyperfine coupling constants, Aiso((13)C), for the indiv

9 The (13)C hyperfine coupling constants also provide an independent

10 The measured hyperfine coupling constant and associated bond length s

11 ned to allow the accurate description of the hyperfine coupling constants and g-tensors of an alkyl g

12 The hyperfine coupling constants and geometry of the NH(2) m

13 ons of molecular spin-orbitals (MSOs) to the hyperfine coupling constants and the spatial distributio

14 agreement with the observed g values, ligand hyperfine coupling constants, and FTIR stretching freque

15 tructures, energetics, harmonic frequencies, hyperfine coupling constants, and isomerization pathways

16 ance for predicting NMR chemical shifts, EPR hyperfine coupling constants, and low-energy transitions

17 ble-temperature magnetic susceptibility, EPR hyperfine coupling constants, and the results of X-ray c

18 = 1.9887, g(y) = 1.9957, g(z) = 1.9775, and hyperfine coupling constants are A(III)(x) = |171| G, A(

19 The hyperfine coupling constants are consistent with a struc

20 et constraints on the relative amplitudes of hyperfine coupling constants, both for protons at chemic

21 emarkable, with an extremely small isotropic hyperfine coupling constant, (C)a = +0.86 MHz.

22 and 3/2 exhibited near-zero (13)C isotropic hyperfine coupling constants, (C)a = [-1.3 <-> +2.7] MHz

23 addition to electron paramagnetic resonance hyperfine coupling constants, can now be calculated for

24 Moreover, the 19F hyperfine coupling constants computed with the MP2 metho

25 three new nitrogen resonances appear having hyperfine coupling constants consistent with histidine l

26 These hyperfine coupling constants correlate well with those r

27 MDL 101,002 yielded a six-line spectrum with hyperfine coupling constants distinct from that of PBN.

28 all magnitude of the (13)C carbide isotropic hyperfine-coupling constant essentially unchanged, (C)a

29 Isotropic hyperfine coupling constants for the ligand nitrogen ato

30 the Hyperion package to obtain relativistic hyperfine coupling constants from relativistic multiconf

31 5F10*-) are reported and their isotropic 19F hyperfine coupling constants (hfcc) of 198.6 +/- 0.4 G,

32 The results show that the calculated hyperfine coupling constants (HFCCs) for the proposed or

33 The hyperfine coupling constants (HFCs) determined from the

34 The magnitude of the nitrogen hyperfine coupling constant in the latter species unambi

35 shifts, and electron paramagnetic resonance hyperfine coupling constants in a model Fe(II)(NO)(imida

36 urately estimated by correlation with proton hyperfine coupling constants in antecedent monoradicals,

37 J/k in the high-spin species vs experimental hyperfine coupling constants in the corresponding monora

38 C isotope shifts in the IR spectra and (13)C hyperfine coupling constants in the EPR spectra exhibit

39 pectroscopy revealed a 9-line spectrum, with hyperfine coupling constants indicative of four almost m

40 The hyperfine coupling constant is determined for each compo

41 rongly coupled nonexchangeable proton with a hyperfine coupling constant of 50 MHz.

42 isotropic signal with a g value of 2.003 and hyperfine coupling constant of 8 x 10(-4) cm(-1) to the

43 The 17O hyperfine coupling constant of H2(17)O is determined as

44 The hyperfine coupling constant of the g = 2 signal in the E

45 t polarity constant E(T)(N) and the nitrogen hyperfine coupling constant of the released nitroxide a(

46 different pictures of the dependence of the hyperfine coupling constant of the trapped H atom upon t

47 an S = 3 ground state with isotropic (55)Mn hyperfine coupling constants of -75, -88, -91, and 66 MH

48 ) gave rise to a distinct (13)C signal, with hyperfine coupling constants of 4.9 MHz for (13)C(a), 1.

49 n of the cluster is highly anisotropic, with hyperfine coupling constants of 9.1 and 2 x 33.3 G for t

50 a tetrahydrofuran solution show large (89)Y hyperfine coupling constants of A( ) = 23 MHz and A(||)

51 igned to a thiyl radical adduct based on its hyperfine coupling constants of aN = 14.7 G and abetaH =

52 ontributions when interpreting the isotropic hyperfine coupling constants of pai radicals.

53 A comparison of g tensors and (1)H hyperfine coupling constants of the PTB7-type oligomers

54 ild-type ESEEM modulation (denoted N1) has a hyperfine-coupling constant of Aiso = 1.05 MHz and nucle

55 Hyperfine coupling constants range from small for the Ni

56 stretching frequency and the imidazole (14)N hyperfine coupling constants show a good correlation wit

57 The Sc-based hyperfine structure with large hyperfine coupling constants shows that both oxidation a

58 duced two radical species in urine, one with hyperfine coupling constants similar to the 4-POBN/methy

59 (1/2)H and (13)C hyperfine coupling constants to 5'-deoxyadenosyl (5'-dAd

60 In contrast, the anisotropic hyperfine coupling constant undergoes a symmetry change

61 troxides which exhibit a change in their EPR hyperfine coupling constants upon enzymatic activity and

62 Assuming a free-ion value for the Pu(4+) hyperfine coupling constant, we estimated a bare (239)ga

63 erved radicals, muon, proton, and phosphorus hyperfine coupling constants were determined by muSR and

64 Following DFT calculations, the predicted hyperfine coupling constants were used to simulate the E

65 r mechanics calculations of isotropic proton hyperfine coupling constants, with direct comparisons to