ライフサイエンスコーパス: ionic radius

1 metal ions with the same charge and similar ionic radius.

2 complexes with cations (bK(AIB)) varies with ionic radius.

3 0-fold higher than alkali cations of similar ionic radius.

4 ared to monovalent alkali cations of similar ionic radius.

5 due to the distinct electronic structure and ionic radius.

6 In Mn(II), ionic radius 0.82 A, DNA binds weakly to mica.

7 s due to its relatively small six-coordinate ionic radius, 0.89 angstroms, vs 1.09 angstroms for Cd2+

8 finity supported by these ions suggests that ionic radius and charge are not critical to the promotio

9 d CMCs was a combination of covalent radius, ionic radius and electron density.

10 cted membrane properties correlated with the ionic radius and electronegativity of the ions.

11 l and theoretical results reveal that dopant ionic radius and electronic structure have a significant

12 The role of ionic radius and metal valence state was explored by con

13 dependent on small variations in lanthanide ionic radius and occurs despite identical coordination-l

14 The considerable adjustments incurred to ionic radius and resultant cation charge density also pr

15 s proposed which predicts effects of charge, ionic radius and temperature on counterion-induced RNA f

16 monovalent cation depends on its unhydrated ionic radius, and at a low monovalent cation concentrati

17 d iodide as a function of bilayer thickness, ionic radius, and sign of charge.

18 can be fulfilled by other cations of similar ionic radius, and that the functional role of Ca2+ to ac

19 ice formation enthalpy (DeltaH(L)) and metal ionic radius are the best predictors of IXZO oxygen gett

20 fecting diffusion, including the valency and ionic radius, are discussed.

21 tuations larger than the small difference in ionic radius between K+ and Na+.

22 has a higher affinity for metal ions with an ionic radius close to 1.0 A, particularly Cd(II), Gd(III

23 ill favor complexation with metal ions of an ionic radius close to 1.0 A.

24 ture is still monovalent-cation specific and ionic-radius dependent, but a larger number of cations (

25 with a transition state lacking significant ionic radius-dependent steric constraints.

26 Lanthanide ionic radius effects and ancillary ligation effects on t

27 This contribution probes mechanism and metal ionic radius effects in the catalytic lanthanide triflat

28 All calculations employed the same ionic radius for Cd(2+) and same cadmium-thiolate bond d

29 The smaller ionic radius for low-spin compared to high-spin Fe(2+) a

30 K(+) and Rb(+) possess the optimal ionic radius, giving the lowest values of aK(PLP).

31 cations that enhance dimer formation have an ionic radius >1.1 A.

32 thanide complexes, namely one with a similar ionic radius (i.e., Nd(III) ) and an isoelectronic one (

33 s the result of both ion charge and hydrated ionic radius, in addition to the level of fracture.

34 These results support the idea that ionic radius is an important determinant of selectivity

35 Effective ionic radius is found to be a primary determinant of the

36 bit the K(+)-activated enzyme, implying that ionic radius is important in binding selectivity.

37 Cd2+, with an ionic radius of 0.96 A, exhibits a strong CHEF (chelatio

38 ecific for ions that closely approximate the ionic radius of calcium.

39 th the larger amount of iron and the smaller ionic radius of Fe(2+) as a result of an electronic spin

40 rk of NH4 subset Rh4Ru3 reflects the smaller ionic radius of NH4+.

41 tion of the larger ReO4-, due to the smaller ionic radius of NO3-.

42 The larger ionic radius of Pb(2+) relative to Ca(2+) is accommodate

43 d cyclability is difficult because the large ionic radius of potassium-ions causes structural distort

44 der Waals radius of methyl (2.00 A) and the ionic radius of silver(I) (1.29 A).

45 F cores, which inversely correlates with the ionic radius of the metal ions.

46 This site is selective toward the ionic radius of the monovalent cation, accepting those l

47 s strongly on valence and, less strongly, on ionic radius or electronegativity.

48 Mg(II) is a Group 2 cation with an ionic radius similar to that of Ni(II).

49 s activated by cations of varying charge and ionic radius, such as Li+, A13+, Tb3+, and Eu3+, as well

50 Divalent cations of larger ionic radius than Sr(2+) are thought to be ineffective a

51 rimary storage sites for elements with large ionic radius--that is, incompatible elements in the Eart