ライフサイエンスコーパス: manganese oxide

1 beta-MnO(2)) to 1.18 +/- 0.01 W/m(2) (sodium manganese oxide).

2 an that of previous reports for electrolytic manganese oxide.

3 xide (TMAO), nitrite, and insoluble iron and manganese oxides.

4 ificantly acts as a source of oxygen next to manganese oxides.

5 ce of DOM composition on its reactivity with manganese oxides.

6 ease or decrease phenol oxidation rates with manganese oxides.

7 fluence the multistage oxidation pathways of manganese oxides.

8 marily mediated by the reduction of iron and manganese oxides.

9 patterns gathered from natural and synthetic manganese oxides.

10 ws activity for Mn(2+)(aq) oxidation to form manganese oxides.

11 ns during a solid-state chemical reaction in manganese oxides.

12 3 virus with earth-abundant elements such as manganese oxides.

13 ugh binding to reactive metal (e.g. iron and manganese) oxides.

14 er copper(6,7), nickel(8,9), iron(10,11) and manganese oxides(12).

15 es growing on agar amended with all the test manganese oxides after growth of A. niger and S. himanti

16 Manganese oxide (alpha-MnO2 ) has been considered a prom

17 As a result, monolithic manganese oxide ambigels exhibit an equilibrium conducto

18 anganese oxides, including a fungal-produced manganese oxide and birnessite, was investigated.

19 manganese ore and ferric oxide as sources of manganese oxide and iron oxide through solid state react

20 ide film has a cubic structure isomorphic to manganese oxide and is (110)-oriented in single domain o

21 was conducted with dispersed nanoparticulate manganese oxides and a standard ruthenium dye photo-oxid

22 o some literature reports with polydispersed manganese oxides and electro-deposited films.

23 Manganese oxides are a highly promising class of water-o

24 Manganese oxides are capable of rapidly oxidizing U(IV)

25 Manganese oxides are important environmental oxidants th

26 Manganese oxides are often highly reactive and easily re

27 Manganese oxides are ubiquitous marine minerals which ar

28 m ultradilute solutions using spinel lithium manganese oxide as the model electrode.

29 Here, using manganese oxides as examples, we report the successful c

30 ethod can be generally used for synthesis of manganese oxides as well as for in situ characterization

31 eggin/organic ions intercalated into layered manganese oxide at room temperature in 1 day.

32 Using this method and a novel process for manganese oxide atomic layer deposition, we produced man

33 The AFM coupling in iron oxide-manganese oxide based, soft/hard and hard/soft, core/she

34 Gold nanoparticles supported on manganese oxide belong to the most active gold catalysts

35 5)Tl/(203)Tl ratios indicative of widespread manganese oxide burial on an oxygenated seafloor and hig

36 However, this assumes that manganese oxides can be produced only in the presence of

37 Manganese oxides can oxidize organic compounds, such as

38 e highest power densities were achieved with manganese oxides capable of intercalating sodium ions wh

39 The decomposition of ozone on supported manganese oxide catalysts, studied here, exemplifies rea

40 nganese cobalt oxide, and sodium nickel iron manganese oxide chemistries, (7)Li and (23)Na NMR data u

41 media, we measured the ability of passivated manganese-oxide coated sand to oxidize bisphenol A after

42 to levels comparable to those of the virgin manganese-oxide coated sand.

43 Manganese oxide-coated sand can oxidize electron-rich or

44 sotope measurements on postdepositional iron-manganese oxide coatings precipitated on planktonic fora

45 a metallacryptand shell that encapsulates a manganese oxide core.

46 Our results suggest that manganese oxides could have formed abiotically on the su

47 et in which hydrous ferric oxide and hydrous manganese oxide deposits had formed as a consequence of

48 Nanostructured manganese oxides, e.g. MnO2, have shown laccase-like cat

49 Electrodeposited manganese oxide films (MnOx) are promising stable oxygen

50 promise, among the studied materials, while manganese oxide, flake graphite, and carbon nanotube pow

51 Manganese oxide formation in cell-free filtrates occurre

52 microporous octahedral molecular sieve with manganese oxide framework.

53 Manganese oxides from anthropogenic sources can promote

54 became prominent, light-driven formation of manganese oxides from dissolved Mn(2+) ions may have pla

55 of proteins inside the bacteria labeled with manganese oxide has been identified and this distributio

56 tion of water, our detailed study of several manganese oxides has shown that trivalency of Mn is an i

57 Manganese oxides have been proposed as promising geomedi

58 Manganese oxides have been recently investigated as exce

59 Manganese oxides have been shown to rapidly oxidize As(I

60 Cryptomelane-type manganese oxides have been synthesized, characterized, a

61 Recent computational studies of models for manganese oxides have revealed a rich phase diagram, whi

62 We synthesized 12 manganese oxides having different crystal structures and

63 Mesoporous silica-coated hollow manganese oxide (HMnO@mSiO(2)) nanoparticles were develo

64 ting network hydrogel with confined hydrogen manganese oxide (HMO) via an innovative in-situ crosslin

65 accumulated hydrous ferric oxide and hydrous manganese oxide in the well bore and pump riser provides

66 ago on the basis of the inferred presence of manganese oxides in Archaean sedimentary rocks.

67 room temperature may affect the behavior of manganese oxides in technological applications and in ge

68 Mn(II) exchanges with structural Mn(III) in manganese oxides in the absence of any mineral transform

69 photosynthetic microorganisms biomineralize manganese oxides in the absence of molecular oxygen and

70 The shuttling of Na(+) into and out of the manganese oxides in the hydrogen and oxygen evolution st

71 his light-dependent process may also produce manganese oxides in the photic zones of modern anoxic wa

72 pula himantioides to tolerate and solubilize manganese oxides, including a fungal-produced manganese

73 anic cluster of the stoichiometry CaMn4 O5 , manganese oxide is one of the materials of choice in the

74 An amorphous manganese oxide layer bound by oleate ligands helps to r

75 t 2% coverage of what is likely an amorphous manganese oxide layer.

76 ng a non-superconducting cuprate between two manganese oxide layers, we find a novel form of magnetoe

77 electrodes and tested them on lithium nickel manganese oxide [Li(Ni(0.5)Mn(0.5))O2], a safe, inexpens

78 ochemical reversibility of a layered lithium manganese oxide, Li-birnessite, which extends the practi

79 oxide (LiCoO(2) ) and lithium nickel cobalt manganese oxide (LiNi(0.8) Co(0.1) Mn(0.1) O(2) , NCM 81

80 ell-ordered organic-inorganic hybrid layered manganese oxide (LMO) nanocomposites and Keggin/organic

81 er oxides, and colossal magnetoresistance in manganese oxides ('manganites').

82 nvolve a combination of factors: The calcium manganese oxide materials have a layered structure with

83 ce of cost-effective and reusable mesoporous manganese oxide materials.

84 As strong naturally occurring adsorbents, manganese oxides may significantly influence the fate an

85 is catalyzed by a Li ion promoted mesoporous manganese oxide (meso-Mn(2)O(3)) under mild conditions w

86 Manganese oxide minerals can become enriched in a variet

87 Manganese oxide minerals have been used for thousands of

88 ple their growth to the reduction of iron or manganese oxide minerals located extracellularly.

89 Manganese-oxide minerals (MnOx) are widely distributed o

90 Here we show that manganese oxide (Mn oxide) in a water treatment works fi

91 cceptor, including ferric iron [Fe(III)] and manganese oxide [Mn(IV)].

92 Among a variety of manganese oxides, Mn2O3 is considered to be the most fav

93 An electrochemical biosensor based on manganese oxide (Mn3O4) and chitosan (Cn) nanocomposite

94 all significantly lower than those of binary manganese oxides (Mn3O4, Mn2O3, and MnO2), consistent wi

95 better water oxidation catalysts than binary manganese oxides (Mn3O4, Mn2O3, and MnO2).

96 th quartz particles coated with a mixture of manganese oxide (MnO(2)) and goethite (alpha-FeOOH) unde

97 enation with those from abiotic oxidation by manganese oxide (MnO(2)) suggest that the oxidation of a

98 id medium: MnO(2) and Mn(2) O(3) , mycogenic manganese oxide (MnO(x) ) and birnessite [(Na(0.3) Ca(0.

99 The oxidation of dissolved Ce(III) by manganese oxides (MnO(2)) and the resulting Ce anomaly i

100 by coating reduced graphene oxide (rGO) and manganese oxide (MnO2) composite on the carbon felt (CF)

101 n rust (GR(SO4)), magnetite (Fe(3)O(4)), and manganese oxide (MnO2).

102 m in situ XAS measurements on a bifunctional manganese oxide (MnOx) catalyst with high electrochemica

103 ehensive electrochemical characterization of manganese oxide (MnOx) over a wide pH range, and establi

104 The Earth-abundant and inexpensive manganese oxides (MnOx) have emerged as an intriguing ty

105 We investigated the reaction of manganese oxide [MnOx(s)] with phenol, aniline, and tric

106 trode materials such as carbon nanotubes and manganese oxides (MnxOy) [3, 5-14].

107 3 mm) is generated in monolithic ultraporous manganese oxide nanoarchitectures upon exposure to gas-p

108 ally compared the laccase-like reactivity of manganese oxide nanomaterials of different crystallinity

109 ing the laccase-like reactivity of different manganese oxides nanomaterials, and provide a basis for

110 Low-dimensional cobalt oxide codoped manganese oxide nanoparticles (CMO NPs; dia.

111 ard to the colloidal stability of engineered manganese oxide nanoparticles (Mn(x)O(y) NPs).

112 Manganese oxide nanoparticles (NPs) are shown to catalyz

113 Previous measurements show that calcium manganese oxide nanoparticles are better water oxidation

114 face between cobalt oxide surface layers and manganese oxide nanoparticles by using X-ray absorption

115 covery of a hybrid oxide catalyst comprising manganese oxide nanoparticles supported on mesoporous sp

116 is enabled by the in situ growth of hydrous manganese oxide nanoparticles throughout a cation exchan

117 On incorporating the hydrous manganese oxide nanoparticles, the membrane's phosphate

118 d-graphene nanofibres (LSGNF) decorated with manganese oxide nanoparticles.

119 ter followed by down-sizing of protein-bound manganese-oxide nanoparticles to finally yield today's c

120 nce of five compositionally distinct layered manganese oxide nanostructures.

121 erate the breakdown of ternary nickel cobalt manganese oxide (NCM) cathode materials at a significant

122 Manganese oxide NS were synthesized via the exfoliation

123 Manganese oxides occur naturally as minerals in at least

124 Cryptomelane-type manganese oxide octahedral molecular (OMS) sieve three-d

125 This study examines the effects of manganese oxide octahedral molecular sieve chitosan micr

126 Manganese oxides of various structures (alpha-, beta-, a

127 Films of polyions and octahedral layered manganese oxide (OL-1) nanoparticles on carbon electrode

128 Cryptomelane-type manganese oxide (OMS-2) has been widely used to explore

129 Iron and manganese oxides or oxyhydroxides are abundant transitio

130 the ability of photosystems to form extended manganese oxide particles.

131 pectroscopy data indicated that the reactive manganese oxide phases present in virgin geomedia and ge

132 e report a class of Bi-birnessite (a layered manganese oxide polymorph mixed with bismuth oxide (Bi2O

133 Mixed-valence manganese oxides present striking properties like the co

134 ose an evolutionary scenario, which involves manganese-oxide production by ancestral photosystems, la

135 The results imply that manganese oxide reactivity depends on both oxidation sta

136 se experiments suggest that Mn(II) catalyzes manganese oxide recrystallization and illustrate a new p

137 oxidation of the mobilized ferrous iron with manganese oxides results in a large stock of iron-oxide-

138 stration of the magnetic interactions in the manganese oxide slab.

139 sed of alternating perovskite-type strontium manganese oxide slabs separated by anti-fluorite-type co

140 articulate organic carbon (OC), and iron and manganese oxide solid phases.

141 Layered lithium manganese oxides suffer from irreversible phase transiti

142 )(18) (R = CH(2)CH(2)Ph) nanoclusters onto a manganese oxide support (Au(25)/MnO(2)), resulting in a

143 misorption of water onto anhydrous nanophase manganese oxide surfaces promotes rapidly reversible red

144 nter (OEC) in photosystem II, nanostructured manganese oxide surfaces were investigated for these rea

145 his study investigated the use of iron-doped manganese oxide, synthesized via air oxidation under str

146 that, for elements with greater affinity for manganese oxide than biogenic particles, scavenging is a

147 Here, we demonstrate a layered lithium manganese oxide that can be charged and discharged witho

148 the selective synthesis of different yttrium manganese oxides through assisted metathesis reactions b

149 intercalated between two nanosheets (NS) of manganese oxide to form a bilayer structure.

150 Manganese oxides typically exist as mixtures with other

151 an accurate assessment of the reactivity of manganese oxides used as engineered geomedia for quinolo

152 Manganese oxide was effective at both hydrolytic and oxi

153 ive study of gold nanoparticles on different manganese oxides, we developed a gold catalyst on MnO2 n

154 Thin films of nanostructured manganese oxide were found to be active for both oxygen

155 Manganese oxides were of low toxicity and A. niger and S

156 d the crystal structures and morphologies of manganese oxides, which undergo redox reactions coupled

157 partially cation-disordered lithium niobium manganese oxide with a zigzag structure, filling the kno

158 n, we report a structural-engineered lithium manganese oxide with spinel-layered heterostructures (de

159 sulted in the generation of small nodules of manganese oxide with which the cells associated.

160 investigation of electrodeposited amorphous manganese oxides with different catalytic activities tow

161 Manganese oxides with layer and tunnel structures occur

162 environmental processes involving insoluble manganese oxides, with practical relevance to chemoorgan

163 all methane removed is oxidized by iron and manganese oxides, with the remainder accounted for by ox