新型炭材料
新型炭材料
신형탄재료
NEW CARBON MATERIALS
2010年
5期
376-381
,共6页
模板法%沥青%中孔炭%双电层电容器%电化学性能
模闆法%瀝青%中孔炭%雙電層電容器%電化學性能
모판법%력청%중공탄%쌍전층전용기%전화학성능
Template%pitch%Mesoporous carbon%EDLC%Electrochemical properties
以乙酸镁和柠檬酸镁热解得到的MgO为模板,热塑性沥青为碳前驱体,采用程序升温一步炭化法(950℃,N2)制备了高比表面积中孔炭材料.尽管未进行活化,两种模板前驱体与沥青混合所制中孔炭材料均可获得非常高的比表面积.以这两种中孔炭作为双电层电容器的电极材料,在质量分数为30%的KOH电解液中测试其电化学性能.结果表明:这两种中孔炭电极均可得到较高的比电容量和理想的功率特性,尤其是柠檬酸镁作前驱体时,MgO与沥青质量比为4时得到的炭材料(MCP 8/2)在20mA·g-1 的电流密度下得到284F·g-1 的比电容量,且在1000mA·g-1时仍能得到236F·g-1 的比电容.交流阻抗测试表明:组装的双电层电容器的内部阻抗均小于3. 5Ω.
以乙痠鎂和檸檬痠鎂熱解得到的MgO為模闆,熱塑性瀝青為碳前驅體,採用程序升溫一步炭化法(950℃,N2)製備瞭高比錶麵積中孔炭材料.儘管未進行活化,兩種模闆前驅體與瀝青混閤所製中孔炭材料均可穫得非常高的比錶麵積.以這兩種中孔炭作為雙電層電容器的電極材料,在質量分數為30%的KOH電解液中測試其電化學性能.結果錶明:這兩種中孔炭電極均可得到較高的比電容量和理想的功率特性,尤其是檸檬痠鎂作前驅體時,MgO與瀝青質量比為4時得到的炭材料(MCP 8/2)在20mA·g-1 的電流密度下得到284F·g-1 的比電容量,且在1000mA·g-1時仍能得到236F·g-1 的比電容.交流阻抗測試錶明:組裝的雙電層電容器的內部阻抗均小于3. 5Ω.
이을산미화저몽산미열해득도적MgO위모판,열소성력청위탄전구체,채용정서승온일보탄화법(950℃,N2)제비료고비표면적중공탄재료.진관미진행활화,량충모판전구체여력청혼합소제중공탄재료균가획득비상고적비표면적.이저량충중공탄작위쌍전층전용기적전겁재료,재질량분수위30%적KOH전해액중측시기전화학성능.결과표명:저량충중공탄전겁균가득도교고적비전용량화이상적공솔특성,우기시저몽산미작전구체시,MgO여력청질량비위4시득도적탄재료(MCP 8/2)재20mA·g-1 적전류밀도하득도284F·g-1 적비전용량,차재1000mA·g-1시잉능득도236F·g-1 적비전용.교류조항측시표명:조장적쌍전층전용기적내부조항균소우3. 5Ω.
Templated mesoporous carbons with high surface area were successfully prepared by the carbonization of a mixture of thermoplastic precursor pitch with MgO precursors (magnesium acetate and citrate) at 950℃ in a N2 atmosphere. The BET surface area of the carbons obtained reached a very high value without any activation process. The carbons were rich in mesopores. The electrochemical performance of mesoporous carbons prepared as electrode materials for electric double layer capacitors were also investigated. Measurement of capacitance was carried out in a mass fraction 30% KOH electrolyte. Results showed that the mesoporous carbons had a high specific capacitance and perfect rate performance. In particular, the sample prepared with a mass ratio of MgO to pitch of 4 for the magnesium citrate template showed a fairly high capacitance, about 284F·g-1 at a current density of 20mA·g-1 and 236F·g-1 at 1000mA·g-1. The impedance of all the capacitors was smaller than 3.5Ω.
