ライフサイエンスコーパス: nanobelt

1 ct ratio of 1.6, the highest of any reported nanobelt.

2 wo-dimensional structure into nanoribbons or nanobelts.

3 2) O co-intercalated MoO(3-x) (NH-MoO(3-x) ) nanobelts.

4 corresponding isomeric circulenes and carbon nanobelts.

5 electrocatalytic performance of the Ag-CoSe2 nanobelts.

6 anostructures, especially zigzag-phosphorene nanobelts.

7 of the piezophototronic effect in a-axis GaN nanobelts.

8 f nitrogen-doped titanate-anatase core-shell nanobelts.

9 unctions are successfully fabricated in ZnSe nanobelts.

10 id body motion as well as deformation of the nanobelts.

11 using an example of Zn(x)Cd(1-x)S(y)Se(1-y) nanobelts.

12 ysis mechanism of the nitrogen-doped titania nanobelts.

13 electronic properties of zigzag-phosphorene nanobelts.

14 mation together with in situ fracture of the nanobelts.

15 ws formed by bending single-crystal, PSD ZnO nanobelts.

16 l characteristics of the grown nanowires and nanobelts.

17 n and the side surfaces of the nanowires and nanobelts.

18 te species for generating zigzag-phosphorene nanobelts.

19 f-coiling process during the growth of polar nanobelts.

20 building functional devices along individual nanobelts.

21 thod for synthesizing ultra-long alpha-Si3N4 nanobelts along with a few nanowires and nanobranches on

22 The self-assembled :PDI(2-)/PDI(2-) crystal nanobelt alters the spin-dependent excitation evolution,

23 Micrometer-long nanobelt and nanowires from deposition of perylenediimid

24 Pearl chain formation involving short nanobelts and particles was also observed in the two DEP

25 to fewer unpassivated surface states in the nanobelts; and (iii) enhanced charge separation due to t

26 e of unsaturated metal sites, a hierarchical nanobelt architecture, and the Ni-Co coupling effect.

27 Molecular nanobelts are fascinating analogs of carbon nanotubes.

28 The long MoO(3) nanobelts are grinded and then intercalated with Na(+) a

29 Carbon nanobelts are molecules of high fundamental and technolo

30 Nitrogen-doped anatase titania nanobelts are prepared via hydrothermal processing and s

31 The as-synthesized oxide nanobelts are pure, structurally uniform, and single cry

32 The nanobelts are single crystals elongated preferentially i

33 The grown (4,4-DFPD)(2)PbI(4) nanobelt array can be multiple layers to unit-cell thin

34 Here we introduce tin oxide (SnO(2)) nanobelts as a photonic platform for the transport of su

35 ine black phosphorus into zigzag-phosphorene nanobelts, as well as nanosheets and quantum dots, via a

36 We synthesized these nanobelts by nickel-mediated coupling of meso-bromoporph

37 serum albumin modification, the NH-MoO(3-x) nanobelts can efficiently kill cancer cells in vitro and

38 immunoFETs based on nano devices (nanowire, nanobelts, carbon nanotube, etc.) are not treated here.

39 However, the cost of Mo(2)N nanobelt catalyst ($ 31/m(2)) was much less than that of

40 This study demonstrated Mo(2)N nanobelt catalyst as an alternative to Pt catalyst for H

41 ntiometry tests demonstrated that the Mo(2)N nanobelt cathodes had similar catalytic activities for H

42 covery (74% vs. 70%) of MECs with the Mo(2)N nanobelt cathodes were also comparable to those with Pt/

43 Here, inexpensive and efficient Mo(2)N nanobelt cathodes were prepared using an ethanol method

44 red to be initiated by circular folding of a nanobelt, caused by long-range electrostatic interaction

45 The synthesis of carbon nanobelts (CNBs) with well-defined size and structure re

46 , we report the synthesis of triple stranded nanobelts consisting of 8 to 12 edge-fused porphyrin uni

47 perature photoluminescence spectrum of Si3N4 nanobelts consists of three emission peaks centered at 4

48 on of the tin particle with the ZnO nanowire/nanobelt could be ordered (or partially crystalline) dur

49 The nanobelts could be an ideal system for fully understandi

50 .03, and 1/z = 0.39 +/- 0.12; (2) D > 40 nm, nanobelt crystals are formed gradually on the caterpilla

51 pid roughening process, and the formation of nanobelt crystals.

52 ge of a lateral PNG built on a single PMN-PT nanobelt demonstrates the potential application of PMN-P

53 More interesting, ECL of a single nanobelt deposited on an ultramicroelectrode was observe

54 assembled via ultralong molybdenum trioxide nanobelts, displays an excellent average transmittance o

55 inated by transforming into a single-crystal nanobelt dominated by nonpolar (0110) surfaces.

56 Moreover, the nanobelts exhibit a lower electron-hole recombination ra

57 The nanobelts exhibit birefringence enhanced by 1 order of m

58 the inert MoO(3) nanobelts, the NH-MoO(3-x) nanobelts exhibit excellent enzyme-mimicking catalytic a

59 he CoSe2 nanobelts, the as-prepared Ag-CoSe2 nanobelts exhibited a higher current density and a lower

60 s microrods (for 1), nanoprisms (for 2), and nanobelts (for 3).

61 TiO2 was not cytotoxic except for the nanobelt form, which was cytotoxic and induced significa

62 NO3)3 played a crucial role in promoting the nanobelt formation in the initial stage.

63 al and uniradial loop-by-loop winding of the nanobelt formed a complete ring.

64 c and piezophototronic effects in a-axis GaN nanobelts from 77 to 300 K is investigated.

65 The large-scale synthesis of Si3N4 nanobelts from quartz and graphite on a graphite-felt su

66 enerator (PNG) is built on the single PMN-PT nanobelt, generating a maximum output voltage of ~1.2 V.

67 The ultra-long alpha-Si3N4 nanobelts grew via a combined VLS-base and nanobranches

68 The preferential elongation of the nanobelts in the [010] direction contributes to this enh

69 gy, with each nanowire being composed of two nanobelts joined along the growth direction to give a V-

70 calculations show that the morphology of ZnS nanobelts leads to a very high mechanical stability to a

71 nsformation into the superlattice-structured nanobelt led to the formation of a uniform nanohelix due

72 However, the nanobelt may have some initial bending, surface roughnes

73 nc oxide nanorings formed by self-coiling of nanobelts may be useful for investigating polar surface-

74 Orthorhombic Pb3O2Cl2 (mendipite) nanobelts micrometers in length and tens of nanometers w

75 e observations of the wide variety of SnO(2) nanobelt motions induced by ac dielectrophoresis (DEP) i

76 d on the continuous bridged-deformation of a nanobelt/nanowire using an atomic force microscope tip u

77 The transport properties of GaN nanobelts (NBs) are tuned using a piezotronic effect whe

78 The nanobelts of DD-PTCDI fabricated in solution can feasibl

79 Bending of polar-surface-dominated (PSD) nanobelts of ZnO can be explained by one of two processe

80 ion to achieve the synthesis of a new carbon nanobelt on large scale with the introduction of functio

81 A single alpha-Si3N4 nanobelt or nanobranch gave a strong UV-blue emission ba

82 ZnS wurtzite nanobelts provide a model that is useful not only for un

83 This nanobelt represents a diagonal cross section of an armch

84 he high d33 of the single-crystalline PMN-PT nanobelt results from the precise orientation control du

85 monstrate that morphology-tuned wurtzite ZnS nanobelts show a particular low-energy surface structure

86 The prepared nanobelts show an enhanced fluorescence emission and rel

87 As a result, the coated nanobelts show improved rate, cycling, and thermal capab

88 ere we report a mechanistic study on a novel nanobelt structure that overcomes the drawback of sphere

89 truct an efficient photoanode with a coaxial nanobelt structure, comprising a buried-ZrS(3)/ZrOS n-p

90 emble in highly ordered few-micrometer-long 'nanobelts' that can be visualized by conventional micros

91 Relative to the CoSe2 nanobelts, the as-prepared Ag-CoSe2 nanobelts exhibited

92 In contrast to the inert MoO(3) nanobelts, the NH-MoO(3-x) nanobelts exhibit excellent e

93 , formed on the surface of the n-type ZrS(3) nanobelt through a pulsed-ozone-treatment method, acts a

94 Here, we report an organic molecular crystal nanobelt through the self-assembly of spin-one open-shel

95 -P25), anatase spheres (TiO2-A), and anatase nanobelts (TiO2-NBs)] and three forms of multiwalled car

96 , we report the activation of layered MoO(3) nanobelts via aqueous intercalation as an efficient biod

97 ver a Fabry-Perot cavity mechanism in SnO(2) nanobelts via direct detection of phonon-polariton stand

98 phologies in aggregate: one-dimensional (1D) nanobelt vs zero-dimensional (0D) nanoparticle.

99 xide consisting of a superlattice-structured nanobelt was formed spontaneously in a vapor-solid growt

100 Negative DEP (repulsion) of the nanobelts was observed in the low-frequency range (<100

101 1-10 MHz), positive DEP (attraction) of the nanobelts was observed.

102 Ethanol suspended SnO(2) nanobelts were introduced into the microchannel, and the

103 ion, morphology, and microstructure of Si3N4 nanobelts were investigated by X-ray diffraction, Fourie

104 The single crystalline nanobelts were successfully fabricated with an ionic com

105 The Si3N4 nanobelts were well crystallized and grow along the [101

106 The Si3N4 nanobelts were ~4-5 mm long and ~60 nm thick and exhibit

107 ke (or ribbonlike) nanostructures (so-called nanobelts) were successfully synthesized for semiconduct

108 reasons: (i) greater charge mobility in the nanobelts, which is enabled along the longitudinal dimen

109 l (1 - x)Pb(Mg1/3Nb2/3)O3 - xPbTiO3 (PMN-PT) nanobelt with a superior piezoelectric constant (d33 = ~

110 change method to fabricate lamellar Ag-CoSe2 nanobelts with controllable conductivity.

111 electro-optical switches based on single CdS nanobelts with low drive voltage, ultra-high on/off rati

112 esostructure; further exfoliation results in nanobelts with minimum sizes around 4 nm.

113 t also for improving synthesis of metastable nanobelts with quantum effects for electronic and optica

114 Single-crystalline anatase TiO(2) nanobelts with two dominant surfaces of (101) facet exhi

115 ries of nanoscale Li(2)TiO(3)-coated LiMO(2) nanobelts with varied Ni, Co, and Mn contents was prepar

116 ons show that the exposed (101) facet of the nanobelts yields an enhanced reactivity with molecular O