ライフサイエンスコーパス: telluride

1 N-phenylanthranilates with sodium or lithium telluride.

2 s facile composition control akin to cadmium telluride.

3 ] and [110] superlattices of calcium and tin tellurides.

4 Telluride 2 displayed greater rate acceleration than the

5 of the Te atom of the electron-rich dialkyl telluride 2 was more rapid than oxidation of diaryl tell

6 Rate constants for the oxidation of tellurides 2-4 (k(ox)), rate constants for the introduct

7 Di-n-hexyl telluride (2), di-p-methoxyphenyl telluride (3), and (S)

8 de 2 was more rapid than oxidation of diaryl tellurides 3 and 4.

9 Di-n-hexyl telluride (2), di-p-methoxyphenyl telluride (3), and (S)-2-(1-N,N-dimethylaminoethyl)pheny

10 S)-2-(1-N,N-dimethylaminoethyl)phenyl phenyl telluride (4) catalyzed the oxidation of PhSH to PhSSPh

11 reductive elimination at Te(IV) in oxidized tellurides 5-7 were determined using stopped-flow spectr

12 d to the Te(IV) center (k(PhSH)) of oxidized tellurides 5-7, and thiol-independent (k(1)) and thiol-d

13 lating dimethylaminoethyl ligand of oxidized telluride 7 diminished k(PhSH) by a fator of 10(3).

14 results for both bismuth telluride/antimony telluride and chromel/alumel structures as examples of a

15 In addition to dimethyl telluride and dimethyl ditelluride, two new organometall

16 morphous silicon, crystalline n-type cadmium telluride, and hydrogenated amorphous silicon.

17 elts dissolved Te is present as the divalent telluride anion, Te(2-), which was found able to be conv

18 We report results for both bismuth telluride/antimony telluride and chromel/alumel structur

19 rimeric polyphenylsulfides, -selenides, and -tellurides are prepared in high yield using propyloxy sp

20 ge-area and high-quality 2D transition metal tellurides are synthesized by the chemical vapor deposit

21 lowest manufacturing GHG footprint (cadmium telluride) are deployed in locations with the most GHG-i

22 Also, using molybdenum telluride as a test case, we performed X-ray diffraction

23 m octadecylphosphonate and trioctylphosphine telluride as precursors, and a TOPO solvent.

24 Our mechanistic study indicates that this telluride-assisted reaction consists of two steps: subst

25 of RbCuTe consists of ribbons of copper and telluride atoms placed antipolar to one another througho

26 films and devices by screen printing bismuth telluride based nanocrystal inks synthesized using a mic

27 The tellurides behave differently for their selenium analogu

28 ric figure of merit (ZT) in bismuth antimony telluride (BiSbTe) bulk alloys has remained around 1 for

29 ional insulators, can be realized in mercury telluride-cadmium telluride semiconductor quantum wells.

30 in multivessel patients using a cadmium zinc telluride camera appear to correlate well with invasive

31 sion reserve estimation using a cadmium zinc telluride camera in a cohort of multivessel patients and

32 ere performed using a dedicated cadmium zinc telluride camera.

33 n diagnostic image quality on a cadmium-zinc-telluride camera.

34 ol as the sulfur source, while selenides and tellurides can be accessed upon mixing with a stoichiome

35 The selenides and tellurides catalyze the oxidation of bromide with hydrog

36 Slow oxidation of tellurium ions in cadmium telluride (CdTe) nanoparticles results in the assembly o

37 Thioglycolic acid (TGA)-capped cadmium-telluride (CdTe) quantum dots (QDs) exposing green emiss

38 nescent, water-soluble semiconductor cadmium telluride (CdTe) quantum dots that emit in the green reg

39 r indium gallium selenide (CIGS) and cadmium telluride (CdTe)-in the United States (U.S.) to those of

40 Cadmium telluride, CdTe, is now firmly established as the basis

41 s (QD-NAPTHs) were prepared based on cadmium telluride (CdTe655) quantum dots as luminescent nanoscaf

42 Critical twinning stress of cadmium zinc telluride (CdZnTe or CZT) calculated is 1.38 GPa.

43 olishing (CMP) is developed for cadmium zinc telluride (CdZnTe or CZT) wafers.

44 tomic solids assembled from molecular nickel telluride clusters and fullerenes undergo a ferromagneti

45 stals functionalized with molecular antimony telluride complexes belonging to the family of Zintl ion

46 hemotherapy utilizing multifunctional copper telluride (Cu2-XTe) nanocubes (NCs) as photothermal and

47 e obtained using a multipinhole cadmium-zinc-telluride (CZT) camera with that obtained using conventi

48 al (3D) dynamic approach with a cadmium zinc telluride (CZT) camera.

49 fferences in the performance of cadmium-zinc-telluride (CZT) cameras or collimation systems that have

50 A small cadmium zinc telluride (CZT) detector was evaluated.

51 gamma-cameras with solid-state cadmium-zinc-telluride (CZT) detectors have better count sensitivity

52 compared two SPECT cameras with cadmium-zinc-telluride (CZT) detectors to a conventional Anger camera

53 s in SPECT technology including cadmium-zinc-telluride (CZT) semiconductor detector material may pave

54 erfusion imaging (MPI) with the cadmium-zinc-telluride (CZT) SPECT camera is not well established.

55 l perfusion imaging (MPI) using cadmium-zinc-telluride (CZT) SPECT cameras for the measurement of lef

56 or clinical indications using a cadmium-zinc-telluride dedicated cardiac camera.

57 filter in combination with a mercury cadmium telluride detector was used to reduce the instrument noi

58 st thermoelectrically cooled mercury-cadmium-telluride detector.

59 ction in Bi(0.5)Sb(1.5)Te3 (bismuth antimony telluride) effectively scatter midfrequency phonons, lea

60 The layered telluride, Fe(1+x)Te, is a parent compound of the isostr

61 e bulk of pure and Cr-doped bismuth antimony telluride films, we provide signatures related to the TI

62 leobases (thymine) derivatized with 5-phenyl-telluride functionality (5-Te).

63 pseudo-1D material family-monoclinic gallium telluride (GaTe)-is synthesized by physical vapor transp

64 stallization of amorphous germanium antimony telluride (Ge2Sb2Te5).

65 Germanium telluride (GeTe) is both polar and metallic, an unusual

66 mony telluride (Sb2Te3) core and a germanium telluride (GeTe) shell, as well as an improved synthesis

67 luminescence, of (A) Er(3+)(8%)Tm(3+)(0.5%):telluride glass are very similar to those of Er(3+) ions

68 ence intensity of (A) Er(3+)(8%)Tm(3+)(0.5%):telluride glass was approximately 4.4 to 19.5 times larg

69 tting luminescence in Er(3+)/Tm(3+) co-doped telluride glass was studied.

70 5 times larger than that of (B) Tm(3+)(0.5%):telluride glass, and approximately 5.0 times larger than

71 to those of Er(3+) ions in (C) Er(3+)(0.5%):telluride glass, with respect to the shapes of their exc

72 0 times larger than that of (C) Er(3+)(0.5%):telluride glass.

73 lcogenides including sulfides, selenides and tellurides has been developed by the reaction of diazoni

74 shing (CMP) is developed for mercury cadmium telluride (HgCdTe or MCT) semiconductors.

75 the monolayer (ML) low-buckled (LB) mercury telluride (HgTe) and mercury selenide (HgSe), with tunab

76 tion of a copper salt with trioctylphosphine telluride in the presence of lithium bis(trimethylsilyl)

77 ization of a new nanostructured platinum/tin/telluride inorganic/surfactant composite.

78 dronucleosides with a telluride monoanion, a telluride intermediate is formed, and its elimination le

79 The behavior of both tellurides is strikingly different.

80 he Te was switched out, reduced to a soluble telluride, leaving the Ge (one "bait and switch" cycle).

81 te with the state-of-the-art mercury-cadmium-telluride material system in the field of infrared detec

82 ed, open framework platinum tin selenide and telluride materials assembled using K4SnQ4 (Q = Se, Te)

83 uctures that consist of a germanium antimony telluride matrix and cobalt germanide precipitates can b

84 relate with complex phase transitions of the telluride matrix.

85 ith a liquid nitrogen cooled mercury cadmium telluride (MCT) detector and compare their performance t

86 planar waveguides made from mercury-cadmium-telluride (MCT)-a material to date exclusively used for

87 is of d4Ns by discovering and applying a new telluride-mediated elimination reaction.

88 e synthesized with yields up to 90% via this telluride-mediated elimination.

89 Telluride misfit layer compounds are reported for the fi

90 bstitution of 2,2'-anhydronucleosides with a telluride monoanion, a telluride intermediate is formed,

91 cedure to prepare highly monodisperse copper telluride nanocubes, nanoplates, and nanorods.

92 onstrate such assemblies, we combine cadmium telluride nanoparticles with cytochrome C protein and ob

93 are transformed into chiral gold and silver telluride nanostructures with very large chiroptical act

94 Metal telluride nanowires are attractive materials for many ap

95 step, these nanowires are converted to metal telluride nanowires by adding metal precursors.

96 We also show that well-defined copper telluride NCs (Cu(2-x)Te, x > 0) display a NIR LSP, in a

97 Monodisperse lead telluride (PbTe) nanocrystals ranging from approximately

98 late, monodisperse PEDOT-functionalized lead telluride (PbTe) nanoparticles were crafted via the stro

99 use of the thallium impurity levels in lead telluride (PbTe).

100 rder has also been reported for the tantalum telluride phase with an approximate Ta(1.6)Te compositio

101 a thermoelectrically cooled mercury-cadmium-telluride photodetector and liquid nitrogen-cooled indiu

102 n rates of two industrially important binary tellurides-polycrystalline cadmium and bismuth telluride

103 ted cyclization event initiated from an acyl telluride precursor.

104 We synthesized cadmium telluride quantum dots (CdTe QDs) capped with thioglycol

105 organism to determine the impact of cadmium telluride quantum dots (CdTe QDs).

106 ergy transfer with l-cysteine-capped cadmium telluride quantum dots (CdTe-QDs) in aqueous solution.

107 tructured composite of chitosan (CS)-cadmium-telluride quantum dots (CdTe-QDs) onto indium-tin-oxide

108 de self-oligomerization and the platinum:tin telluride ratio both vary, indicating that the composite

109 ial heterostructures composed of an antimony telluride (Sb2Te3) core and a germanium telluride (GeTe)

110 The scandium antimony telluride (Sc0.2Sb2Te3) compound that we designed allows

111 ign, as recently discussed during the second Telluride Science Research Center workshop organized in

112 gh geometrically matched and robust scandium telluride (ScTe) chemical bonds that stabilize crystal p

113 Bismuth chalcogenides and lead telluride/selenide alloys exhibit exceptional thermoelec

114 We find that the extent of tin telluride self-oligomerization and the platinum:tin tell

115 st-generation gamma-camera with cadmium-zinc-telluride semiconductor detectors in patients with high

116 can be realized in mercury telluride-cadmium telluride semiconductor quantum wells.

117 lished across a range of metal selenides and tellurides, showing that conductive materials result in

118 spontaneous polarization in atomic-thick tin telluride (SnTe), down to a 1-unit cell (UC) limit.

119 emplating of selenocadmate, or the analogous telluride species, to create ordered organic-inorganic h

120 tion of (123)I-mIBG on a hybrid cadmium zinc telluride SPECT/CT system.

121 Here we show that the layered telluride T2PTe2 (T=Ti, Zr) displays exclusive insertion

122 In comparison to the corresponding pure tellurides, the figure of merit (ZT) values of heterostr

123 report here the first synthesis of 5-phenyl-telluride-thymidine derivatives and the Te-phosphoramidi

124 llurides-polycrystalline cadmium and bismuth tellurides- were studied over the pH range 3-11, at vari

125 In various tellurides with applications as thermoelectrics and as p

126 scribe a two-step synthesis of various metal tellurides with nanowire morphology using a nonhazardous

127 rated on various technologically interesting tellurides with spectra spanning up to 170 kHz, at 22 kH

128 semiconductor quantum dots (cadmium selenium telluride) with both homogeneous and gradient internal s