초록 ▼

Disclosed are electrode materials that exhibit very sharp pore size distribution within the range of mesopores and include pores having a pore diameter within a range of X±α nm (3.0≤X<10, α=1.0; range of pore size distribution) of which volume accounts for 15% or more of the total volume of mesopore

Disclosed are electrode materials that exhibit very sharp pore size distribution within the range of mesopores and include pores having a pore diameter within a range of X±α nm (3.0≤X<10, α=1.0; range of pore size distribution) of which volume accounts for 15% or more of the total volume of mesopores having a pore diameter within a range from 2.0 to 50 nm, and are suited for use in electric double layer capacitor, battery or the like of large capacitance and discharge of large current. These electrode materials are obtained by adding at least one transition metal or at least one transition metal compound to a carbon material or a carbon material precursor, and subjecting to a heat treatment at a temperature of 600° C. or higher.

대표청구항 ▼

1. An electrode material that includes pores having a pore diameter within a range of X±α nm (3.0≤X<10, α=1.0; range of pore size distribution) of which volume accounts for 15% or more of the total volume of mesopores having a pore diameter within a range from 2.0 to 50 nm. 2. An electrode material

1. An electrode material that includes pores having a pore diameter within a range of X±α nm (3.0≤X<10, α=1.0; range of pore size distribution) of which volume accounts for 15% or more of the total volume of mesopores having a pore diameter within a range from 2.0 to 50 nm. 2. An electrode material according to claim 1, that has a maximum value of pore size distribution within a pore diameter range of X±α nm (3.0≤X<10, α=1.0; range of pore size distribution). 3. An electrode material according to claim 1, that has a diffraction peak originated in a graphite crystal in X-ray diffraction. 4. An electrode material according to claim 1, that contains 0.01 to 50% by weight of a transition metal or a transition metal compound. 5. An electrode material according to claim 4, wherein said transition metal or transition metal compound is copper or a copper compound. 6. A method of producing the electrode material of claim 1, which comprises adding at least one transition metal or at least one transition metal compound to a carbon material or a carbon material precursor, and carbonating in a non-oxidizing atmosphere or activating in a slightly oxidizing atmosphere at a temperature of 600° C. or higher. 7. A method of producing the electrode material according to claim 6, wherein said carbon material is coconut shell charcoal, cokes, wooden charcoal, carbonized resin, bamboo charcoal, or a mixture thereof, and said carbon material precursor is coconut shell, coal, lumber, resin, bamboo, or a mixture thereof. 8. A method of producing the electrode material according to claim 7, wherein said carbonized resin is a carbonized ion exchange resin, or said resin is an ion exchange resin. 9. A method of producing the electrode material according to claim 7, wherein said carbonized resin is a carbonized phenolic resin, or said resin is a phenolic resin. 10. A method of producing the electrode material according to claim 6, wherein at least one transition metal or at least one transition metal compound is added in the amount of 0.01 to 100 parts by weight, in terms of transition metal, based on 100 parts by weight of said carbon material or carbon material precursor. 11. A method of producing the electrode material according to claim 6, wherein said transition metal or transition metal compound is metal powder, nitrate, acetate, sulfate, carbonate, phosphate, bromide, chloride, phosphide, oxide, or hydroxide. 12. A method of producing the electrode material according to claim 6, wherein said transition metal is copper, iron, cobalt, or nickel. 13. A battery comprising the electrode material of claim 1. 14. An electric double layer capacitor comprising the electrode material of claim 1.