Symmetric pseudocapacitors (SPCs) have the ability to provide an extended operating life-span with high power density; however, their energy density is not sufficient for various critically vital applications. To reduce the overall cost and complexity of fabrication of SPCs while simultaneously increasing their energy density, we present a "two birds with one stone" approach. Herein, to prove this idea, low-cost silicon (Si) embedded in metal-organic framework (MOF)-derived cobalt nano-sized particles/nitrogen-doped carbon (Si/Co-NC) was prepared as an integrated electrode material which works at positive and negative potential windows simultaneously. The optimized electrode with 30% Si content (Si/Co-NC1) achieved a remarkable capacitance of 845.41 F g(-1) at 1 A g(-1) in a broader potential window range (-1.0-0.4 V) and 97% of the capacitance was retained after 10 000 cycles. According to the charge storage analysis, the Si/Co-NC1 electrode works on the basis of a pseudocapacitive charge storage mechanism and possesses 79.8% capacitive contribution at 1 mV s(-1). Moreover, a symmetric pseudocapacitor, Si/Co-NC1||Si/Co-NC1-SPC, shows a broader operating potential window range (0.0-1.8 V), exhibits an excellent capacitance of 277 F g(-1) at 2 A g(-1), maintains a capacitance of 96.8% after 50 000 cycles and achieves similar to 100% coulombic efficiency. Additionally, the Si/Co-NC1||Si/Co-NC1-SPC provides an ultrahigh energy density of 125.43 W h kg(-1) at 1804.32 W kg(-1), which is the greatest energy density for symmetric SCs to date.

• 单位
  兰州大学