ライフサイエンスコーパス: structure factor

1 tified by the principal peak position of the structure factor.

2 which are identified from the scaling of the structure factor.

3 rier transform vectors in the aperture array structure factor.

4 tations below the gap with an incommensurate structure factor.

5 nt within the error margins of the Yamaguchi structure factors.

6 t directional-dependence (anisotropy) in the structure factors.

7 eudo-atoms for normalization of the observed structure factors.

8 e remaining 7 mus of the trajectory, and the structure factors agree well with experiment.

9 Structure factor amplitudes and phases can be computed d

10 ameters necessary to make corrections to the structure factor amplitudes derived from electron cryomi

11 Structure factor amplitudes of a three-dimensional map o

12 accurate measurement of spherically averaged structure factor amplitudes of particles in solution but

13 rees tilt and increasing the completeness of structure factor amplitudes to 84.7 %.

14 ystem, the development of a peak in the spin structure factor and a staggered magnetization that is c

15 haracterized by a rapid decay of the dynamic structure factor and by a square root power law for the

16 By analyzing the structure factor and the radial distribution function, t

17 The structure factors and coordinates of IGF2R domain 11 hav

18 iments agrees with reported x-ray scattering structure factors and intensities for Q > 6.5 A(-1).

19 The R-factor between the experimental structure factors and those derived from this unrestrain

20 ptors such as the pair correlation function, structure factor, and Voronoi statistics show a strong c

21 onent distributions, continuous and discrete structure factors, and overall scattering-density profil

22 scattering, considering both form factor and structure factor, as well as the use of correlation func

23 e satisfactory for determining the phases of structure factors, but not their absolute values.

24 Directional structure factor calculations were made from these simul

25 Structure factor calculations, in conjunction with resul

26 ure model are discussed, with a key focus on structure factor coarse-graining and hydration contribut

27 The respective partial structure factor contributions to F(x)(Q) are obtained b

28 experimental x-ray scattering intensity and structure factor data for Q < 6.5 A(-1).

29 The structure factor data show that the first sharp diffract

30 everal important elements, effective residue structure factors derived from the Protein Data Bank, ex

31 and by a resolution-dependent damping of the structure factor differences between data and model.

32 X-ray crystallography will yield consistent structure factors, even at low resolution, when image re

33 The incoherent structure factor extracted from the velocity autocorrela

34 ficients (A2) were determined from the X-ray structure factors extrapolated to the origin.

35 Total structure factors (F(x)(Q)) are collected on the laser-h

36 We show from analysis of the structure factor for this lattice that the sampling patt

37 e parameters correlate with crystallographic structure factors for Calpha carbons, suggesting that th

38 ggesting the latter's expansion to be a main structuring factor for the parasite.

39 ents yield the scattering intensity (dynamic structure factor) [Formula: see text] as a function of [

40 lculate both the stress and the single-chain structure factor from first principles.

41 The atomic coordinates and experimental structure factors have been deposited in the PDB with th

42 es and other instrumental factors affect the structure factors, however, resulting in decreased accur

43 lin (PSM) surfactant peptides as key biofilm structuring factors in the premier biofilm-forming patho

44 lous diffusion results from a combination of structuring factors including protein-protein interactio

45 th the transcription machinery and chromatin structure, factors integral to nuclear receptor-regulate

46 sed to confirm silica encapsulation, since a structure factor is observed at q approximately 0.25 nm(

47 space mapping of the second-order non-linear structure factor is the source of this contrast and deve

48 ns in the powder patterns preclude separated structure factor measurements for these data.

49 , but model refinement will require accurate structure factor measurements.

50 The absolute-scale structure factors obtained in the experiments provided a

51 cts that the density excitation spectrum and structure factor of a condensed Bosonic system in the ph

52 s work we analyze GISAXS measurements of the structure factor of Si surfaces evolving during 1 keV Ar

53 way as experimental data by determining the structure factors of the system and, via Fourier reconst

54 ce (correlation function) and Fourier space (structure factor) of the cell centroids in the early sta

55 indeed provides access to the spin dynamical structure factor once one considers the full influence o

56 f shifts in radial distribution function and structure factor peaks associated with volume changes in

57 rystallizing the protein and determining the structure factor phases by the method of multiple-energy

58 The ability of the algorithm to find structure-factor phases rapidly is found to assist with

59 of such order is the first peak in the total structure factor, referred to as the first sharp diffrac

60 In concentrated mucin solutions, the structure factor S(q, t) derived from DLS measurements c

61 This technique directly measures the dynamic structure factor S(q,omega) which is the space-time Four

62 density fluctuations, or, equivalently, the structure factor S(q-->0) = 0; the smaller the value of

63 Scaling of the structure factor, S(q) proportional, variant q(-1/nu), w

64 to test the so-called fluid-minus method of structure-factor scaling.

65 ndles confirmed the theoretically predicated structure-factor scattering peak line shape.

66 pproach to quantify correlations between the structure factor sets.

67 During the whole procedure, the Structure Factor Size and Attenuation Estimator cellular

68 The Structure Factor Size and Attenuation Estimator is propo

69 n that can be quantified with the ultrasound Structure Factor Size and Attenuation Estimator.

70 pounds that vary in volatility and molecular structure-factors that influence their contributions to

71 I developed a new method of using molecular structure factors to solve the crystal structure, which

72 A noise-dependent structure factor weight is derived and used in conjuncti

73 Amplitudes and phases of structure factors were computed and combined to produce

74 generate a model for the electronic dynamic structure factor, which offers an avenue for measuring h

75 y to investigate interactions between fibrin structure, factor XIII Val34Leu, fibrinogen Aalpha Thr31