ライフサイエンスコーパス: physical chemistry

1 e layer (EDL) at a liquid-solid interface in physical chemistry.

2 acterization is a long-standing challenge in physical chemistry.

3 ion spectroscopy, cold molecule physics, and physical chemistry.

4 esses and is also a key fundamental issue in physical chemistry.

5 nted in an advanced undergraduate lecture on physical chemistry.

6 al fluids is largely governed by interfacial physical chemistry.

7 a frontier of ultrafast optical science and physical chemistry.

8 were predictable by the first principles of physical chemistry.

9 roviding quantitative data on the underlying physical chemistry.

10 me an indispensable tool within the field of physical chemistry.

11 The relationship between the physical chemistry and biology of self-assembly is poorl

12 ast tentative conclusions about the physics, physical chemistry and biology which underpin the proces

13 ools for many applications in analytical and physical chemistry and engineering.

14 ion ranging from crystallography research to physical chemistry and materials science.

15 The physical chemistry and sequence of the pHD peptides affe

16 tool for research in the fields of biology, physical chemistry and soft condensed matter physics.

17 The results are of interest to fundamental physical chemistry and they have important consequences

18 nd education led me to an academic career in physical chemistry and ultimately to a study of proteins

19 ckages dedicated to numerical simulations in physical-chemistry and atomic and solid-state physics.

20 f problems of interest to materials science, physical chemistry, and condensed-matter physics have be

21 ical studies of DNA replication and then DNA physical chemistry, and DNA studies ended with the energ

22 implications in the fields of spectroscopy, physical chemistry, and drug analysis, providing valuabl

23 grand challenge in condensed matter physics, physical chemistry, and materials science and engineerin

24 r datasets, involving quantitative toxicity, physical chemistry, and physiology datasets.

25 er-plant surface interactions, plant surface physical chemistry, and plant ecophysiology.

26 e link between properties, structures, their physical chemistry, and their mathematical description,

27 However, an understanding of the underlying physical chemistry, and therefore the ability to exert c

28 ational spectroscopy throughout the field of physical chemistry are limited by detectors with poor te

29 omprehensive understanding of the underlying physical chemistry as well as accurate parameterizations

30 ntities and to assess their functions from a physical chemistry aspect.

31 biquitous in bacterial cells, the underlying physical chemistry behind heat shock response remains po

32 approach that involves materials chemistry, physical chemistry, chemical engineering, and materials

33 In fundamental physical chemistry, Criegee intermediates have unique an

34 c advances depend on advances in physics and physical chemistry, development of the right preparation

35 ne of the greatest challenges in physics and physical chemistry, due to the prohibitively large compu

36 hip between E(ad-CO) and E(ad-N) with atomic physical chemistry features were further identified.

37 of materials science, analytical chemistry, physical chemistry, food science, pharmaceutical science

38 or ion identification and it is also used in physical chemistry for 3D structure elucidation with com

39 of the computed models are determined by the physical chemistry implicit in the Rosetta all-atom ener

40 o focus on the role of carbohydrate/selectin physical chemistry in mediating rolling.

41 bination of two powerful diagnostic tools in physical chemistry: ion mobility and single molecule flu

42 In our physical chemistry lab in spring 2024, students practice

43 e gap between what is currently known in the physical chemistry literature of quantum dots and the qu

44 ological convergence from polymer chemistry, physical chemistry, materials science and engineering di

45 nce of thermal fluctuations in the fields of physical chemistry, materials sciences, and the biologic

46 ents, suggesting that there may be important physical chemistry missing in the energy calculations.

47 luated according to a scoring system for the physical chemistry of cholelithiasis during feeding of a

48 connection between enzyme evolution and the physical chemistry of enzyme catalysis, and it deepens o

49 ning sites of IgG are discussed based on the physical chemistry of fullerenes and previously describe

50 suggests the origin of the effect is in the physical chemistry of L-selectin interaction with its li

51 ology becomes more closely entwined with the physical chemistry of lipids in explaining membrane stru

52 anes pose conceptual problems related to the physical chemistry of liquids.

53 s a substantial advance in the excited-state physical chemistry of luminescent nanoclusters and a gen

54 past several years toward understanding the physical chemistry of membrane protein stability, the st

55 In the current work, the physical chemistry of molten solutions of lithium chlori

56 ous mathematical model that incorporates the physical chemistry of nucleation and fibril growth dynam

57 In the physical chemistry of polar liquids, systems that evade

58 roteins inside living cells, focusing on the physical chemistry of quinary structure and cellular org

59 sults show that incorporation of appropriate physical chemistry of the reactions with accurate kineti

60 ion of isoform distribution in fish, and the physical chemistry of the synergistic crystal growth inh

61 ition that involves direct alteration of the physical chemistry of the virus membrane.

62 ral and dynamic behavior and to describe the physical chemistry of their interaction trajectories.

63 e host-guest chemistry and discuss the basic physical chemistry of these complexes.

64 nal theory of isotope fractionation, but the physical chemistry of these isotope effects remains poor

65 Gram-positive bacteria led to studies on the physical chemistry of these lipids and the cellular regu

66 We present a detailed description of the physical chemistry of this hitherto little explored memb

67 nt point in the life cycle of any virus, the physical chemistry of virus capsid assembly is poorly un

68 tions that violate established principles of physical chemistry, particularly as it concerns the expo

69 raction is temporally controlled by the same physical chemistry principle in the cell as in vitro.

70 atic membranes is discussed, emphasizing new physical chemistry principles and computational methodol

71 edox catalysis by comparing their underlying physical chemistry principles and describing their impac

72 y and photoredox catalysis differ in several physical chemistry principles.

73 It is necessary to couple the physical chemistry, reaction kinetics, ion flow, heat ge

74 dition, new applications of these effects to physical chemistry, solar system origin models, terrestr

75 d from these new molecules, in the fields of physical chemistry, spectroscopy, materials preparation,

76 ed through the insights of computational and physical chemistry studies.

77 Taxis is ubiquitous in biological and physical chemistry systems as a response to various exte

78 at merge control and information theory with physical chemistry, that seemingly mild constraints on t

79 The classical polymer physical chemistry theory developed by Flory and Stockma

80 nce of the tip fail to capture the essential physical chemistry underpinning the imaging mechanism.

81 r at the forefront of this exciting field of physical chemistry, we believe that this tutorial review

82 tiful and complex example of non-equilibrium physical chemistry, whose explanation and understanding