ライフサイエンスコーパス: cobalt oxide

1 insertion cathode materials, such as lithium cobalt oxide.

2 o strong interactions with the aggregates of cobalt oxide.

3 is approximately the length of Co-O bond in cobalt oxide.

4 minant active catalyst and not Co(2+)(aq) or cobalt oxide.

5 d on Au is 40 times higher than that of bulk cobalt oxide.

6 et well-defined functional analogues of bulk cobalt oxide.

7 and provides a molecular model for Mn-doped cobalt oxides.

8 ts with CoN(4) configuration, and commercial cobalt oxides.

9 ulombic efficiency of 98.1% based on lithium cobalt oxide and a high discharge capacity of 166.9 micr

10 LT-LiCoO2 is higher than that of both spinel cobalt oxide and layered lithium cobalt oxide synthesize

11 Cobalt oxides and (oxy)hydroxides have been widely studi

12 rties governing the stability of high-valent cobalt oxides and specifically possible oxygen evolution

13 xed oxide catalyst composed of copper oxide, cobalt oxide, and ceria (dubbed CCC) that outperforms sy

14 thium cobalt oxide, lithium nickel manganese cobalt oxide, and sodium nickel iron manganese oxide che

15 is coupled with a water oxidation phosphate cobalt oxide anode in a home-made electrolyzer by means

16 Cobalt oxides are recognized as one of the most efficien

17 uses to synthesize and assemble nanowires of cobalt oxide at room temperature.

18 the surface energies of the layered lithium cobalt oxide can be significantly lowered as a consequen

19 used a simple two-step method to synthesize cobalt oxide/carbon nanotube (CNT) strongly coupled hybr

20 lack phosphorus anode coupled with a lithium cobalt oxide cathode achieves an ultrafast-charging batt

21 er with good cyclability of a 4-volt lithium cobalt oxide cathode and operation as low as -60 degrees

22 -metal anode can be coupled with a potassium cobalt oxide cathode to achieve dendrite healing in a pr

23 ich, coupled with a lithium nickel-manganese-cobalt oxide cathode with a high nickel content, can lea

24 e report the discovery of subnanometer sized cobalt oxide clusters for oxidative dehydrogenation of c

25 itly exclude the existence of metallic Co or cobalt oxides clusters.

26 Few-atom cobalt-oxide clusters, when dispersed on a Zr-based meta

27 ork, we have developed a simple and reliable cobalt oxide (Co(3)O(4)) based amperometric sensor for t

28 e (IrO(x)) has been uniformly dispersed onto cobalt oxide (Co(3)O(4)) nanocrystals to improve the eff

29 e synthesis of tungsten trioxide (WO(3)) and cobalt oxide (Co(3)O(4)) nanostructures intercalated bal

30 e use of engineered viruses as templates for cobalt oxide (Co(3)O(4)) particles, superparamagnetic co

31 in mass activity at 0.85 V, when compared to cobalt oxide, Co(3)O(4)/C, and a negligible degradation

32 Cobalt oxide/cobalt-based nanoparticles featuring a core

33 Low-dimensional cobalt oxide codoped manganese oxide nanoparticles (CMO

34 anges with the transition between cobalt and cobalt oxide controlled by a voltage applied to the top

35 nged by studies suggesting that formation of cobalt oxide (CoOx) or other byproducts are responsible

36 Cyclic voltammetry of phosphate cobalt oxide (CoPi) films catalyzing O2-evolution from w

37 the OER exhibited by approximately 0.4 ML of cobalt oxide deposited on Au is 40 times higher than tha

38 The higher OER activity of cobalt oxide deposited on Au is attributed to an increas

39 rnover frequency for approximately 0.4 ML of cobalt oxide deposited on Au is nearly three times highe

40 The activity of small amounts of cobalt oxide deposited on Pt, Pd, Cu, and Co decreased m

41 cobalt phosphide, which partially evolved to cobalt oxide during OER.

42 Building upon recent study of cobalt-oxide electrocatalysts in fluoride-buffered elect

43 ommercially-sourced lithium nickel manganese cobalt oxide electrodes.

44 mical properties for a manganese center in a cobalt oxide environment, and provides a molecular model

45 The activated mesoporous cobalt oxide exhibited high oxygen evolution activities

46 sembly bound as Co(II), with no evidence for cobalt oxide film or cluster formation.

47 oxygen evolution reaction (OER) occurring on cobalt oxide films deposited on Au and other metal subst

48 on the oxygen evolution reaction (OER) for a cobalt oxide|fluorine-doped tin oxide coated glass (CoO(

49 rbent (polyaniline) with an electrocatalyst (cobalt oxide) for nitrate to ammonium conversion.

50 as the velocity is maximized for the unitary cobalt oxide [Formula: see text] nanofluid with increasi

51 ula: see text], gold [Formula: see text] and Cobalt oxide [Formula: see text] nanoparticles.

52 Cobalt oxide has shown excellent electrochemical cycling

53 The presence of layered cobalt oxides has been identified experimentally in Co-b

54 Cobalt oxides have long been understood to display intri

55 ansition metal oxide catalysts, particularly cobalt oxide, have shown potential for CO(2) hydrogenati

56 ting the ORR activity compared with the pure cobalt oxide hybrid.

57 stalline platinum and manganese, nickel, and cobalt oxides, illustrating the catalytic potential of p

58 Herein, we report on a cobalt oxide incorporated with iridium single atoms (Ir-

59 functionalized with metallic oxides such as Cobalt oxide, Iron oxide, and Cobalt Iron oxide, at thre

60 spectroscopy revealed that the as-deposited cobalt oxide is present as Co(3)O(4) but undergoes progr

61 erful tools reveal that the curvature of the cobalt oxide layers occurring near the surface dictates

62 The 4.6 V 30 mum Li||4.5 mAh cm(-2) lithium cobalt oxide (LCO) (low N/P ratio of 1.3) cell with our

63 h beta-Li(3)N as SSE interlayers and lithium cobalt oxide (LCO) and Ni-rich LiNi(0.83)Co(0.11)Mn(0.06

64 recycling via the upcycling of spent lithium cobalt oxide (LCO) as a new promising solid lubricant ad

65 rved for Li(1)Si anode paired with a lithium cobalt oxide (LCO) cathode.

66 showcase the transformation of spent lithium cobalt oxide (LCO) cathodes into photothermal catalysts

67 study the active surfaces of layered lithium cobalt oxide (LCO) for the oxygen evolution reaction (OE

68 um-ion battery cathode nanomaterial, lithium cobalt oxide (LCO), on the growth, development, hemoglob

69 nthic species Chironomus riparius to lithium cobalt oxide (Li (x)Co(1- x)O(2), LCO) and lithium nicke

70 1- x)O(2), LCO) and lithium nickel manganese cobalt oxide (Li (x)Ni (y)Mn (z)Co(1- y- z)O(2), NMC) at

71 Among the cobalt oxides, Li2Co2O4 and LaCoO3--especially the latte

72 calation of nanosized stoichiometric lithium cobalt oxide LiCo(III)O(2) from low-spin to intermediate

73 Li anodes paired with lithium cobalt oxide (LiCoO(2) ) and lithium nickel cobalt manga

74 nd inorganic-rich interphases on the lithium cobalt oxide (LiCoO(2)) cathode and graphite anode.

75 Layered lithium cobalt oxide (LiCoO(2), LCO) is the most successful comm

76 capability, considerably better than lithium cobalt oxide (LiCoO2), the current battery electrode mat

77 , in commercial pouch cells based on lithium cobalt oxide, lithium nickel manganese cobalt oxide, and

78 Lithium-rich nickel manganese cobalt oxide (LRNMC) is being explored as an alternative

79 Cobalt oxide materials can catalyze the OER and are pote

80 that obtained from the electrodeposition of cobalt oxide materials from phosphate-buffered electroly

81 el the oxygen evolution reaction activity of cobalt oxide nanoislands and show that the nanoparticle

82 on at under coordinated cobalt edge sites of cobalt oxide nanoislands.

83 Newly synthesized gold and cobalt oxide nanoparticle embedded Polypropylene-g-Polye

84 inable phytogenic route for the synthesis of cobalt oxide nanoparticles (CoO NPs) utilizing Uraria pi

85 d economical electrochemical sensor based on cobalt oxide nanoparticles (CoO(x)NPs) is successfully r

86 arius, that differ in sensitivity to lithium cobalt oxide nanosheets are found to differ in immune-re

87 tic cobalt-platinum alloy nanowires and gold-cobalt oxide nanowires for photovoltaic and battery-rela

88 A self-assembled layer of virus-templated cobalt oxide nanowires serving as the active anode mater

89 n of preorganized NPs to form interconnected cobalt oxide nanowires via the nanoscale Kirkendall effe

90 The preparation of cobalt oxide nanowires with gold nanoparticle (AuNP) inc

91 , a comparison with lithium nickel manganese cobalt oxide (NCM) reveals that performance improvements

92 Cobalt oxide, nickel oxide and cobalt/nickel binary oxid

93 ternative to stoichiometric nickel manganese cobalt oxide (NMC) cathode materials due to its higher,

94 from the gas phase led to a reduction of the cobalt oxide NPs by hydrogen and a reversible two-dimens

95 the size-dependent morphological behavior of cobalt oxide NPs due to strong interactions with the CeO

96 Plasma-enhanced atomic layer deposition of cobalt oxide onto nanotextured p(+)n-Si devices enables

97 Interestingly, cobalt oxide performs better than fully reduced cobalt w

98 High-valent cobalt oxides play a pivotal role in alternative energy

99 icle modified electrode, this nanosheet form cobalt oxide possesses a rapid background subsiding char

100 tructured electrocatalysts, platinum/lithium cobalt oxide (Pt/LiCoO(2) ) composites with Pt nanoparti

101 cathode layers based on graphite and lithium cobalt oxide, respectively, on thin flexible current col

102 While previous studies on cobalt oxide revealed the intermediacy of the unusual Co

103 Attempts to improve cobalt oxide's activity have been stymied by limited mec

104 rodeposition protocol for preparing isolated cobalt oxide single molecules (Co(1)O(x)) and clusters (

105 mpression and tension induced by the lithium cobalt oxide substrate of ~5% were directly observed in

106 the existence of an active interface between cobalt oxide surface layers and manganese oxide nanopart

107 segregation of a thin platinum, rather than cobalt oxide, surface layer occurs concurrently with ord

108 both spinel cobalt oxide and layered lithium cobalt oxide synthesized at 800 degrees C (designated as

109 Here we present lithium cobalt oxide, synthesized at 400 degrees C (designated a

110 er OER reaction conditions is thicker on the cobalt oxides than on the other oxides, which we attribu

111 issues by employing a homogeneous model for cobalt oxide, the [Co(III)4] cubane (Co4O4(OAc)4py4, py

112 terization of novel Li-rich nickel manganese cobalt oxide thin films, which are potential cathode mat

113 Cobalt oxide was in the form of CoO due to a gas-phase a

114 plied for structural characterization of the cobalt oxide water-splitting catalyst films using high e

115 be applied to study the structure of in situ cobalt oxide water-splitting film under functional catal

116 ecently uncovered in praseodymium-containing cobalt oxides, where a first-order coupled spin-state/st

117 nanoparticles supported on mesoporous spinel cobalt oxide, which catalyses the conversion of carbon d

118 nto the filament coat, we formed hybrid gold-cobalt oxide wires that improved battery capacity.

119 aching process, resulting in a highly porous cobalt oxide with a significant amount of defects in the

120 In this report, a mesoporous cobalt oxide with an ultrahigh surface area (up to 250 m

121 le extension of the process yielded platinum-cobalt oxide yolk-shell nanostructures, which may serve