Manganese oxide for water oxidation catalyst, manganese oxide/carbon mixture, manganese oxide composite electrode material, and their production methods

1 . A manganese oxide for an oxygen evolution anode catalyst in water electrolysis, which is a manganese oxide having a manganese metallic valence of higher than 3.0 and at most 4.0, having an average primary particle size of at most 80 nm and an average secondary particle size of at most 25 μm. 2 . The manganese oxide according to claim 1 , which has a BET specific surface area of at least 10 m 2 /g and at most 260 m 2 /g. 3 . The manganese oxide according to claim 1 , which has a crystal structure of γ manganese dioxide or a manganese dioxide. 4 . The manganese oxide according to claim 1 , wherein the potential (alkali potential) measured in a 40 wt % KOH solution based on a mercury/mercury oxide reference electrode is at least 200 mV and at most 320 mV. 5 . A manganese oxide/carbon mixture for an oxygen evolution anode catalyst in water electrolysis, which is a mixture of the manganese oxide as defined in claim 1 , and electrically conductive carbon, wherein the proportion of the manganese oxide to the total of the manganese oxide and the electrically conductive carbon is at least 0.5 wt % and at most 40 wt %. 6 . The manganese oxide/carbon mixture according to claim 5 , which has interplanar spacings of at least 0.355±0.01 nm, 0.265±0.01 nm, 0.250±0.05 nm, 0.240±0.004 nm, 0.219±0.004 nm, 0.208±0.004 nm, 0.167±0.002 and 0.143±0.002 nm. 7 . A manganese oxide composite electrode material which comprises an electrically conductive substrate constituted by fibers at least part of which are covered with the manganese oxide as defined in claim 1 . 8 . The manganese oxide composite electrode material according to claim 7 , wherein the manganese oxide covers the fibers in an amount per geometrical area of the electrically conductive substrate of at least 0.1 mg/cm 2 and at most 25 mg/cm 2 . 9 . The manganese oxide composite electrode material according to claim 7 , wherein the electrically conductive substrate is formed of carbon or titanium. 10 . The manganese oxide composite electrode material according to claim 7 , which has interplanar spacings of at least 0.405±0.01 nm, 0.34±0.01 nm, 0.306±0.005 nm, 0.244±0.004 nm, 0.213±0.004 nm, 0.169±0.002 nm, 0.164±0.002 nm and 0.139±0.002 nm. 11 . The manganese oxide composite electrode material according to claim 7 , which has interplanar spacings of at least 0.40±0.01 nm, 0.256±0.005 nm, 0.244±0.004 nm, 0.235±0.004 nm, 0.225±0.004 nm, 0.213±0.004 nm, 0.164±0.002 nm and 0.139±0.002 nm. 12 . A laminate comprising the manganese oxide composite electrode material as defined in claim 7 , and a polymer electrolyte membrane. 13 . A method for producing the manganese oxide as defined in claim 1 , which comprises subjecting a Mn oxide having low valence to disproportionation reaction with a high concentrated acid. 14 . The production method according to claim 13 , wherein the Mn oxide having low valence is trimanganese tetroxide (Mn 3 O 4 ). 15 . A method for producing the manganese oxide as defined in claim 1 , which comprises electrodepositing a manganese oxide by electrolysis of a sulfuric acid/manganese sulfate mixed solution, and grinding the electrodeposited manganese oxide. 16 . The production method according to claim 15 , wherein the sulfuric acid/manganese sulfate mixed solution has a sulfuric acid concentration of higher than 25 g/L and at most 65 g/L. 17 . The production method according to claim 15 , wherein the sulfuric acid concentration at the time of start of the electrolysis is lower than the sulfuric acid concentration at the time of completion of the electrolysis. 18 . A method for producing the manganese oxide/carbon mixture as defined in claim 5 , which comprises mixing a manganese oxide for an oxygen evolution anode catalyst in water electrolysis, which is a manganese oxide having a manganese metallic valence of higher than 3.0 and at most 4.0, having an average primary particle size of at most 80 nm and an average secondary particle size of at most 25 μm, and the electrically conductive carbon in a slurry state. 19 . A method for producing the manganese oxide composite electrode material as defined in claim 7 , which comprises electrodepositing a manganese oxide for an oxygen evolution anode catalyst in water electrolysis, which is a manganese oxide having a manganese metallic valence of higher than 3.0 and at most 4.0, having an average primary particle size of at most 80 nm and an average secondary particle size of at most 25 μm, by electrolysis of a sulfuric acid/manganese sulfate mixed solution on the fibers constituting the electrically conductive substrate. 20 . The production method according to claim 19 , which comprises electrodepositing a manganese oxide for an oxygen evolution anode catalyst in water electrolysis, which is a manganese oxide having a manganese metallic valence of higher than 3.0 and at most 4.0, having an average primary particle size of at most 80 nm and an average secondary particle size of at most 25 μm, in an amount per geometrical area of at least 0.1 mg/cm 2 and at most 25 mg/cm 2 . 21 . An oxygen evolution electrode active material in water electrolysis, which comprises the manganese oxide as defined in claim 1 . 22 . An oxygen evolution electrode, which comprises the oxygen evolution electrode active material as defined in claim 21 . 23 . A laminate comprising the oxygen evolution electrode as defined in claim 22 and a polymer electrolyte membrane. 24 . A water electrolysis apparatus, which comprises the manganese oxide composite electrode material as defined in claim 7 . 25 . A method for producing hydrogen, which comprises conducting water electrolysis using the manganese oxide composite electrode material as defined in claim 7 .