ライフサイエンスコーパス: aberration-corrected

1 ield imaging of WO(3)/ZrO(2) catalysts in an aberration-corrected analytical electron microscope allo

2 Using aberration-corrected analytical transmission electron mi

3 f their structure, which were obtained using aberration-corrected atomic number contrast scanning tra

4 rce microscopy (PFM), and is corroborated by aberration-corrected atomic-resolution scanning transmis

5 pearance of aberrant microtubule structures, aberrations corrected by addition of purified recombinan

6 ed through synchrotron-based diffraction and aberration corrected electron microscopy.

7 With the introduction of aberration-corrected electron lenses, both the spatial r

8 oval from the nanopore edge in situ using an aberration-corrected electron microscope, measure the cr

9 c-scale characterizations based on spherical aberration-corrected electron microscopy and ab initio c

10 neutron reflectivity, x-ray reflectivity and aberration-corrected electron microscopy confirm that th

11 Aberration-corrected electron microscopy confirms BaTiO3

12 Using aberration-corrected environmental transmission electron

13 Here we use aberration-corrected environmental transmission electron

14 y of the catalyst surface was followed using aberration-corrected HAADF-STEM, which showed that atomi

15 Aberration corrected high angle annular dark field scann

16 ure (EXAFS) measurements in combination with aberration corrected high-resolution transmission electr

17 s observed in various Mo-V-O materials using aberration-corrected high-angle annular dark-field (HAAD

18 Aberration-corrected high-angle annular dark-field scann

19 nations by X-ray absorption spectroscopy and aberration-corrected high-angle annular dark-field scann

20 hape faulted dipole are observed directly by aberration-corrected high-angle annular-dark-field imagi

21 f Pt alloy nanoparticles were obtained using aberration-corrected high-angle dark field imaging, whic

22 usters detected through direct imaging on an aberration-corrected high-resolution scanning transmissi

23 ty with the SWNT, as revealed by low-voltage aberration-corrected high-resolution transmission electr

24 Aberration-corrected high-resolution transmission electr

25 Aberration corrected images of biological specimens show

26 ion limit, comparable to that obtained using aberration corrected instruments.

27 ctive optics to demonstrate planar chromatic-aberration-corrected lenses.

28 We elucidate their behavior using aberration-corrected Lorentz transmission electron micro

29 Aberration-corrected, low-voltage, high-resolution trans

30 With a transmission electron aberration-corrected microscope capable of simultaneous

31 arch for STEM measurements carried out using aberration corrected microscopes, approaches that hold c

32 We report an aberration-corrected multifocus microscopy method capabl

33 ined with a parallelized and computationally aberration-corrected optical coherence tomography system

34 dvanced greatly owing to the introduction of aberration-corrected optics.

35 calculations and surface monolayer-sensitive aberration-corrected plan-view high-resolution transmiss

36 Aberration corrected scanning transmission electron micr

37 Using spherical aberration-aberration corrected scanning transmission electron micr

38 ure characterized by means of powder XRD and aberration corrected scanning transmission electron micr

39 By using aberration corrected scanning transmission electron micr

40 t catalysts are quantitatively studied using aberration corrected scanning transmission electron micr

41 We present direct images from an aberration-corrected scanning TEM that resolve a lattice

42 dered manganite Bi0.35Sr0.18Ca0.47MnO3 using aberration-corrected scanning transmission electron micr

43 Using a fifth-order aberration-corrected scanning transmission electron micr

44 We have used aberration-corrected scanning transmission electron micr

45 Here we use aberration-corrected scanning transmission electron micr

46 tile titania nanorods was investigated using aberration-corrected scanning transmission electron micr

47 liated ZrTe5 thin flakes from the studies of aberration-corrected scanning transmission electron micr

48 oscopy (TEM) techniques, including spherical aberration-corrected scanning transmission electron micr

49 through homotopy group theory and spherical aberration-corrected scanning transmission electron micr

50 Using aberration-corrected scanning transmission electron micr

51 eport a combined investigation of SYCO using aberration-corrected scanning transmission electron micr

52 properties determined on an atomic level by aberration-corrected scanning transmission electron micr

53 Using aberration-corrected scanning transmission electron micr

54 Aberration-corrected scanning transmission electron micr

55 porous gold catalysts are investigated using aberration-corrected scanning transmission electron micr

56 The aberration-corrected scanning transmission electron micr

57 Aberration-corrected scanning transmission electron micr

58 Aberration-corrected scanning transmission electron micr

59 ified and their concentrations determined by aberration-corrected scanning transmission electron micr

60 Using aberration-corrected scanning transmission electron micr

61 Using aberration-corrected scanning transmission electron micr

62 Aberration-corrected scanning transmission electron micr

63 through the local, real-space capability of aberration-corrected scanning transmission electron micr

64 Here we report on gentle aberration-corrected scanning transmission electron micr

65 the unprecedented resolution attainable with aberration-corrected scanning transmission electron micr

66 ace composition, and further confirmed using aberration-corrected scanning transmission electron micr

67 Atomic-resolution imaging in an aberration-corrected scanning transmission electron micr

68 Using state-of-the-art, aberration-corrected scanning transmission electron micr

69 electron energy-loss spectrum imaging in an aberration-corrected scanning transmission electron micr

70 Using aberration-corrected scanning transmission electron micr

71 Aberration-corrected scanning transmission electron micr

72 Atomic mappings via aberration-corrected scanning transmission electron micr

73 sample infused with bismuth atoms, by using aberration-corrected scanning transmission electron micr

74 ell nanoparticles have been characterized by aberration-corrected scanning transmission electron micr

75 ed iron (FeN4), was directly visualized with aberration-corrected scanning transmission electron micr

76 e show that annular dark-field imaging in an aberration-corrected scanning transmission electron micr

77 Here, we show that aberration-corrected scanning transmission electron micr

78 Here we show that aberration-corrected scanning transmission electron micr

79 al electrocatalysts--as carried out using an aberration-corrected scanning transmission electron micr

80 e-off can be defeated, we apply in situ, and aberration-corrected scanning, transmission electron mic

81 From aberration-corrected, scanning transmission electron mic

82 de by using annular dark field imaging in an aberration-corrected STEM.

83 ol of a sub-A sized electron probe within an aberration-corrected STEM.

84 c tilt grain-boundary of YSZ bicrystal using aberration-corrected TEM operated under negative spheric

85 BaSnO3 thin film using both conventional and aberration corrected transmission electron microscopes.

86 yer MoS2 sheet as directly observed using an aberration-corrected transmission electron microscope (T

87 idual ligand-free silver nanoparticles using aberration-corrected transmission electron microscope (T

88 e through the use of in situ straining in an aberration-corrected transmission electron microscope, w

89 ction with XeF2 were obtained at 80 kV in an aberration-corrected transmission electron microscope.

90 graphene and imaged after creation using an aberration-corrected transmission electron microscope.

91 ion and sensitivity of the latest generation aberration-corrected transmission electron microscopes a

92 inorganic nanoparticles by state-of-the-art aberration-corrected transmission electron microscopy (T

93 In this work, by the combination of aberration-corrected transmission electron microscopy (T

94 tures were observed on ultrathin supports by aberration-corrected transmission electron microscopy (T

95 Aberration-corrected transmission electron microscopy (T

96 Aberration-corrected transmission electron microscopy ha

97 ges by means of cathodoluminescence mapping, aberration-corrected transmission electron microscopy im

98 Aberration-corrected transmission electron microscopy ob

99 r-coordinated atoms at edges of the pores by aberration-corrected transmission electron microscopy re

100 We used aberration-corrected transmission electron microscopy to

101 electron microanalysis (focused ion beam and aberration-corrected transmission electron microscopy) t

102 lectric structural distortions obtained from aberration-corrected transmission electron microscopy, c

103 mination of a Au68NP at atomic resolution by aberration-corrected transmission electron microscopy, p

104 We demonstrate, via aberration-corrected transmission electron microscopy, r

105 We demonstrate that using aberration-corrected transmission electron microscopy, w

106 BaCo2O5.5 (delta = 0) structure evidenced by aberration-corrected transmission electron microscopy.

107 observed in individual Pt nanoparticles with aberration-corrected transmission electron microscopy.

108 on nanotubes (SWNTs) by direct imaging using aberration-corrected transmission electron microscopy.

109 ns in the sheet structure was achieved using aberration-corrected transmission electron microscopy.

110 s typically found at grain boundaries, using aberration corrected Z-contrast scanning transmission el

111 Here, we use direct imaging by aberration-corrected Z-contrast scanning transmission el

112 precision measurements of atom positions in aberration-corrected Z-contrast scanning transmission el