ライフサイエンスコーパス: water layer

1 d guest, can then be manipulated back into a water layer.

2 the lipid membranes are separated by a thin water layer.

3 influence, and testing for the presence of a water layer.

4 binding led to the ordering of the adjacent water layer.

5 ree OD' transition found only in the topmost water layer.

6 with the typical hysteresis indicative of a water layer.

7 gap has closed to sterically permit a single water layer.

8 s frictional coupling across an interstitial water layer.

9 idity imposed by residues and by the surface water layer.

10 in an ice shell, possibly overlying a liquid water layer.

11 enough heat to maintain a subsurface liquid water layer.

12 in beyond the bilayer, and the intermembrane water layer.

13 of the adsorbed water film is more than two water layers.

14 y and hydrogen-bonding properties in central water layers.

15 are separated from the surface by one or two water layers.

16 For the saturated water layer ((2)/(3) ML) we find a stable structure with

17 The 3470 cm(-1) feature comes from the top water layer adjacent to the hydrophilic headgroup of DMP

18 Results show that a tightly bound water layer adjacent to the OEG-SAMs is mainly responsib

19 Understanding the influence of water layers adjacent to interfaces is fundamental in or

20 on mechanism is dictated by the existence of water layers adjacent to the solid and orientational ord

21 domain with charged surfaces separated by a water layer and a hydrophobic tunneling domain with atom

22 ll, two apposed monolayers merged across the water layer and developed into an hourglass structure co

23 h excellent resistance to the formation of a water layer and no interference caused by light, O2, and

24 tron conductor suppresses the formation of a water layer and results in an electrode-to-electrode sta

25 before the entropy increase of releasing the water layers and the short-range van der Waals attractio

26 served as a defect in a partially structured water layer, and favored relaxed, weakly helical, coiled

27 ral Arctic Basin (PML, intermediate Atlantic Water Layer, and the Arctic Deep Water Layer) are 158 +/

28 kilometers, which is equivalent to a global water layer approximately 11 meters thick.

29 Triple emulsion drops with an ultrathin water layer are developed to achieve high encapsulation

30 rested in phenomena in which nanometer-sized water layers are involved.

31 not the protein itself but ordered ice-like water layers are responsible for the recognition and bin

32 te Atlantic Water Layer, and the Arctic Deep Water Layer) are 158 +/- 77 kg, 6320 +/- 235 kg and 3080

33 The extent of an external water layer around moss tissue influences CO(2) assimila

34 ion of water within ~10 A of, i.e., up to ~3 water layers around the spin probes located on hydrophil

35 5 billion years ago) had a global equivalent water layer at least 137 meters deep.

36 clear evidence for the presence of ice-like water layers at the ice-binding site of the protein in a

37 the outer limit of the first cosolvent (not water) layer; B(i) mainly counts the solvent near the ma

38 This water layer, between the tip and specimen, could act as

39 the appearance and the evaporation of a thin water layer cannot enhance the charge diffusion.

40 bstituents showed modulations of the surface water layers coating the protein-bound inhibitors.

41 t chain recoil by adhesion to the structured water layer covering the surface.

42 rom the moon's silicate interior by a liquid water layer, delayed or prevented from freezing by tidal

43 nd endowing it with a charged character, the water layers ensure the peptide feels the effect of the

44 is a test for the presence of an undesirable water layer, if the conditions for this test are not sel

45 fectively prove the presence or absence of a water layer in a short time period.

46 shoaling of the intermediate-depth Atlantic Water layer in the eastern Eurasian Basin have increased

47 1) to count only the waters within the first water layer is a poor approximation; 3) when determining

48 of the surface water reveal that the topmost water layer is affected structurally at high concentrati

49 de films reaches a maximum when one complete water layer is intercalated between the graphitic planes

50 of hydrophobic molecules across hydrophilic water layers, just as membrane carriers catalyze the tra

51 cations that the presence of such an ordered water layer may have for imaging of biological samples a

52 /quasifree water molecules and surface-bound water layer (minimum binding energy of 1-2 kcal/mol).

53 s within the sediment and anoxic hypolimnion water layer of five humic lakes in WI, USA.

54 2 +/- 2 cm/s, close to the permeability of a water layer of the same thickness.

55 The presence of a water layer on the surface of muscovite mica under ambie

56 Since water layers on Pt are important in many catalytic proce

57 r, which shelters the chemistry of life, the water layer protects other water molecules and allows fo

58 ized the height and contact angle of ordered water layer(s) formed by wetting and de-wetting processe

59 limited delivery of AEA through an unstirred water layer surrounding the cells (1).

60 Water layer test, reversibility, and selectivity for chl

61 as a model for passage across the unstirred water layer that lines the small intestine.

62 ed by forming a hydrogel network within this water layer that serves as a physical barrier.

63 o-dimensional lamellar structures with known water layer thickness as well as well-defined monodisper

64 The water layer thickness between the bilayer planes in the

65 he resultant internal dimensions (d-spacing, water layer thickness, average lipid length, and headgro

66 panned up to 24 orders of magnitude from the water layer to the bilayer center, due primarily to its

67 s have neglected the effect of the unstirred water layer (UWL).

68 ctly at the cell surface across an unstirred water layer, via a hydrophobic channel in the receptor,

69 The polymer was isolated in the water layer when cells were extracted by phenol/water an

70 ells distinguished by numbers of intervening water layers, which reach a minimum when aligned.

71 apposed leaflets becomes coupled across the water layer, while the "outer" leaflets remain unaffecte

72 nanotubes, this feature also results from a water layer with "free" OH (dangling) bonds facing the n

73 molecules more loosely bonded to the topmost water layer with oxygen toward the interface, and thus e