ライフサイエンスコーパス: nanoindentation

1 g., Fourier-transform infrared spectroscopy, nanoindentation).

2 (Zn or Cu) as well as hardness determined by nanoindentation.

3 al tools such as atomic force microscopy and nanoindentation.

4 is difficult to measure strain hardening via nanoindentation.

5 tion site in polycrystalline graphene during nanoindentation.

6 ion under microscope, to nanoscale, by using nanoindentation.

7 Upper incisors were tested by nanoindentation.

8 These results integrating nanoindentation, acoustic microscopy, and finite-element

9 We report the application of nanoindentation and atomic force microscopy to establish

10 Nanoindentation and bend tests were carried out to deter

11 oth experimentally and computationally using nanoindentation and dispersion-corrected density functio

12 Nanoindentation and gas transport experiments showed tha

13 easy accommodation of the deformation during nanoindentation and hence their low E.

14 chanisms are also identified using high-load nanoindentation and in situ transmission electron micros

15 individual, submicrometer particles by using nanoindentation and nano-Wilhelmy methodologies as a fun

16 rect correlations with other methods such as nanoindentation and quantitative backscatter electron im

17 ncluding FT-FIR using synchrotron radiation, nanoindentation and skin delivery assays) to systematica

18 +) mice were determined by histomorphometry, nanoindentation, and quantitative reverse transcriptase-

19 onfirmed by an atomic force microscopy-based nanoindentation approach.

20 Thin-film buckling and nanoindentation are used to evaluate the mechanical beha

21 not equate with greater rigidity, because in nanoindentation assays immature virions exhibit greater

22 ween Young's modulus, as determined by using nanoindentation atomic force microscopy (AFM), and atomi

23 ase digestion and had greater resistivity to nanoindentation by atomic force microscopy and increased

24 Nanoindentation by modified AFM was used to determine si

25 how quantitative tandem epifluorescence and nanoindentation can reveal the spatial and temporal dyna

26 perovskite (IP) single crystal by measuring nanoindentation creep and stress relaxation.

27 that the load-displacement data of a single nanoindentation do not provide a unique solution for the

28 ocation loops in a near-surface region using nanoindentation, drive the dislocations with a shockwave

29 Nanoindentation experiment using atomic force microscopy

30 Through atomically characterized nanoindentation experiments and first-principles quantum

31 Rheology and nanoindentation experiments are used to ensure that the

32 cantly advance the quantitative potential of nanoindentation experiments for the study of dislocation

33 ividual video frames acquired during in situ nanoindentation experiments in a transmission electron m

34 Here we report atomic force microscopy nanoindentation experiments on T=4 hepatitis B virus (HB

35 A series of recent nanoindentation experiments on the protein shells (capsi

36 Quantitative nanoindentation experiments recorded show an increase of

37 scattering, electron-microscopy imaging, and nanoindentation experiments suggest that its mesoscale o

38 was initiated with both microcompression and nanoindentation experiments, followed by site-specific t

39 s in the mechanical properties by performing nanoindentation experiments.

40 primarily sensed in atomic force microscopy nanoindentation experiments.

41 amic deformations in Atomic Force Microscopy nanoindentation experiments; but a comprehensive theory

42 that combines quantification of topography, nanoindentation force measurements, and an interpretatio

43 We also demonstrate that nanoindentation hardness increased with amino acid conte

44 From micro- and nanoindentation hardness testing, all of the composition

45 Nanoindentation has become ubiquitous for the measuremen

46 Nanoindentation has been recently used to measure the me

47 -azobenzene dicarboxylate) by single-crystal nanoindentation, high-pressure X-ray diffraction, densit

48 ree-standing monolayer graphene membranes by nanoindentation in an atomic force microscope.

49 ans of transmission electron microscopy with nanoindentation in order to study the mechanical propert

50 using multiscale computational modeling and nanoindentations in silico of a contiguous microtubule f

51 lure behavior of polycrystalline graphene by nanoindentation is critically dependent on the indentati

52 simulations, the onset of plasticity during nanoindentation is now widely believed to be associated

53 Nanoindentation is the penetration of a surface to nanom

54 Site-specific nanoindentation leads to grain growth that is retarded b

55 This research performs nanoindentation (local deformation) and compression test

56 In this paper, nanoindentation measurements are combined with finite el

57 Based on atomic force microscopy nanoindentation measurements of phage lambda, we previou

58 nsition is confirmed by means of independent nanoindentation measurements on single crystals.

59 Nanoindentation measurements performed by atomic force m

60 rectly correlated to atomic force microscopy nanoindentation measurements to allow a more detailed in

61 mottle virus have been examined at pH 4.8 by nanoindentation measurements with an atomic force micros

62 he discontinuous elastic plastic response in nanoindentation measurements, and a guide to fundamental

63 Using atomic force microscopy imaging and nanoindentation measurements, we investigated the effect

64 The nanoindentation method known as mechanical interferometr

65 The developed in silico nanoindentation method provides a powerful tool for the

66 lized, to our knowledge, a novel kymographic nanoindentation method to obtain spatiotemporal measurem

67 the indentation deformation by colloid probe nanoindentation method.

68 ndent plastic flow behavior is manifested in nanoindentation, microbending, and pillar-compression ex

69 orotic mottle virus and our estimate for the nanoindentation modulus is in accord with experimental m

70 Glycera dibranchiata, has been evaluated by nanoindentation, nanoscratching, and wear testing.

71 ultrafine scale in the form of quasi-static nanoindentation of a bulk glassy metal alloy at room tem

72 nalyses of the serrated-flow behavior in the nanoindentation of a high-entropy alloy, Al0.5CoCrCuFeNi

73 Nanoindentation of engineering materials is commonly use

74 Atomic force microscopy imaging and nanoindentation of FFS with MCT revealed two-phase struc

75 atom' concept via capillary-pressure-induced nanoindentation of monolayer molybdenum disulphide from

76 In situ nanoindentation of the as-deposited {111}Al/AlN/TiN mult

77 We also performed nanoindentation on both the single basal layer of the fr

78 We perform molecular dynamics simulations of nanoindentation on polycrystalline graphene at different

79 Fourier transform infrared spectroscopy and nanoindentation quantified the material and mechanical p

80 Our Nanoindentation results show that the longitudinal elast

81 ntitative fracture toughness measurements by nanoindentation show a rapid brittle-to-ductile transiti

82 Vibrational spectroscopy and nanoindentation showed that tissue from bisphosphonate-t

83 application of recently developed spherical nanoindentation stress-strain protocols in characterizin

84 incoherent twin boundaries based on in situ nanoindentation studies in a transmission electron micro

85 Through nanoindentation studies on a series of omeprazole polymo

86 Nanoindentation studies on alpha,omega-alkanedicarboxyli

87 Nanoindentation studies showed that EGCG reduced the sti

88 A novel nanoindentation technique was used to biomechanically ch

89 f C-S-H, we employ two effective techniques, nanoindentation test and molecular dynamics simulation.

90 he first obvious displacement excursion in a nanoindentation test is indicative of the onset of plast

91 Vickers microhardness and nanoindentation testing indicate that the (002) plane po

92 ynthesized CuZr/Cu multilayers and performed nanoindentation testing to explore the dependence of pla

93 elopment and application of high-temperature nanoindentation testing, and the introduction of statist

94 The nanoindentation tests demonstrated that the tissue mimic

95 Grid nanoindentation tests find different porosity of C-S-H i

96 Nanoindentation tests on the monolithic MOF showed robus

97 Nanoindentation tests reveal an out-of-plane decrease in

98 e grain of aluminium plastically deformed by nanoindentation to a dislocation density of approximatel

99 eralization in wet and dry conditions by AFM nanoindentation to determine if the modulus and hardness

100 me correlation of X-ray nano-tomographs of a nanoindentation to measure the sub-surface displacement

101 Here we use nanoindentation to probe shear band nucleation during lo

102 mel structure and thickness, microCT, and by nanoindentation to quantify enamel mechanical properties

103 ustic microscopy and atomic force microscopy nanoindentation) to characterize the elastic properties

104 an in situ transmission electron microscope nanoindentation tool, the direct observation of dynamic

105 ndividual SFs in living endothelial cells by nanoindentation using an atomic force microscope.

106 Dynamic nanoindentation was used to characterize the mechanical

107 Stiffness of the PCA, as characterized via nanoindentation, was lower in SF mice (SF: 3.4+/-0.3 N/m

108 pectroscopy, thermogravimetric analysis, and nanoindentation, we correlated the mechanical properties

109 Using nanoindentation, we show that the mineral has a structur

110 rmed quantitative tandem epifluorescence and nanoindentation, wherein we sequentially determine cellu

111 We measured stiffness via AFM nanoindentation with a spherical indenter and found that