ライフサイエンスコーパス: conversion reaction

1 lybdenum dioxide electrode is not based on a conversion reaction.

2 formation of Fe nanoparticles and LiF via a conversion reaction.

3 tors can influence significantly the cluster conversion reaction.

4 st and adaptable to rate fluctuations in the conversion reaction.

5 , providing a biochemical model of the prion conversion reaction.

6 ) to, or by sonication of, the cell-free PrP conversion reaction.

7 ycosaminoglycans can directly affect the PrP conversion reaction.

8 ures when placed under the conditions of the conversion reaction.

9 ability to enhance or inhibit this cell-free conversion reaction.

10 -5 nm) nanoparticles through lithium-induced conversion reactions.

11 y (even under acidic conditions) for biomass conversion reactions.

12 r lithium-ion batteries that operate through conversion reactions.

13 plicability of electrode materials entailing conversion reactions.

14 or very active catalysts that promote energy conversion reactions.

15 investigate the species specificity of these conversion reactions.

16 flected in the specificities of in vitro PrP conversion reactions.

17 r in the kinetics of electrocatalytic energy conversion reactions.

18 on or Na-ion battery cell that undergoes the conversion reaction 2 A(+) +2 e(-) +CoS -->Co+A2 S with

19 scribed extends the scope of the amine-azide conversion reaction and may be adaptable for the introdu

20 The mechanism of the cluster conversion reaction and the nature of the released iron

21 ffers insights into intricate multi-electron-conversion reactions and manifests as an effective and e

22 le lithium transport and kinetics of lithium conversion reactions, and may help to pave the way to de

23 A cell-free conversion reaction approximating physiological conditio

24 ects of the use of phases that react through conversion reactions as both positive and negative elect

25 vice platform for performing in-flow gaseous conversion reactions based on ultraviolet (UV) irradiati

26 High-frequency gene conversion reactions between many silent pilin loci and

27 analyzing the initial binding and subsequent conversion reactions between PrP-sen and PrP-res.

28 tease-resistant PrP generated in a cell-free conversion reaction, but only if treated with GdnHCl.

29 sheet aggregates under the conditions of the conversion reaction, but this was also true of certain p

30 also report that a solid-liquid interfacial conversion reaction can create a highly crystalline, nan

31 identifies that the slow solid-state sulfur conversion reaction causes large voltage hysteresis and

32 dictate the efficiency of biological energy-conversion reactions, concepts that will aid the design

33 dependence on protein concentration, and the conversion reaction displayed a dramatic volume-dependen

34 had similarities to the strain-specific PrP conversion reaction during the elongation phase.

35 hydrogen evolution reaction, and hydrocarbon conversion reactions for fuel cells (electrooxidation of

36 ode by insertion reaction and to an anode by conversion reaction in corresponding voltage ranges, in

37 ave significance for the in vivo FNR cluster conversion reaction in the cell cytoplasm, provides an e

38 suggest that sulfur undergoes a solid-state conversion reaction in the electrolyte.

39 O(2) sensing by FNR and iron-sulfur cluster conversion reactions in general, and suggest unique mech

40 A major route for such VSG switching is gene conversion reactions in which RAD51, a universally conse

41 nderstanding of a series of key clean energy conversion reactions including oxygen reduction reaction

42 Sc) is derived from cellular PrP (PrPC) in a conversion reaction involving a dramatic reorganization

43 nique kinetic features, we proposed that the conversion reaction is regulated by the dynamics between

44 Our findings suggest that the in situ PrP conversion reaction leads to additional polymerization o

45 ssociated with both insertion/extraction and conversion reaction mechanisms for lithium storage.

46 ions is demonstrated, which explains how the conversion reaction occurs in alpha-MnO2 material.

47 In this study, we investigated the conversion reaction of binary metal fluorides, FeF(2) an

48 Contribution of conversion reaction of Li/MoS2 system on overall capacit

49 Electrochemical conversion reactions of transition metal compounds creat

50 Cell-free conversion reactions performed using ionic denaturants,

51 ing in situ HRTEM, we captured the atomistic conversion reaction processes during Li, Na, Ca insertio

52 However, detailed conversion reaction processes in terms of the oxidation

53 This conversion reaction provides a target for possible anti-

54 es are catalysts for a number of hydrocarbon conversion reactions, such as the dehydrogenation of pro

55 The inhibition observed in the cell-free conversion reaction suggests that the mechanism involved

56 In the second region, the conversion reaction, superparamagnetic, nanosized ( appr

57 Results provide the atomistic view of this conversion reaction that forms nanocrystals of LiF and F

58 The detection is based on cascadic conversion reactions that result in an amperometric elec

59 We have adapted a cell-free conversion reaction to a high-throughput, solid-phase fo

60 ent was investigated using the cell-free PrP conversion reaction to determine the role of distinct Pr

61 The electrode materials conducive to conversion reactions undergo large volume change in cycl

62 h capacity lithium ion batteries, in which a conversion reaction upon exposure to Li ions enables acc

63 Here, we report studies of the FNR cluster conversion reaction using time-resolved electrospray ion

64 The efficiencies of these heterologous conversion reactions were similar but much lower than th

65 Here we demonstrate a direct chemical conversion reaction, which systematically converts the h

66 Materials that undergo a conversion reaction with lithium (e.g., metal fluorides