Supercapacitors have the advantages of rapid charging/discharging, high power density and long life time, applicable to the fields of mobile communications, vehicle transportation and smart grid. Most current fabrication techniques of supercapacitor utilize planar metal electrodes, appended 3D porous carbon structures such as carbon sponge, carbon aerogel or electrospun carbon fiber. By increasing the specific surface area of the carbon active materials, the power density of the supercapacitor can be improved. However, these planar metal/porous carbon structures will produce serious delamination or collapse failure under large stress, high-speed impact and vibration, making it cannot be applied to the fields which demands load-bearing and anti-shock, like defense industry, aerospace technology, and electric vehicles. Therefore, this study will use three process to make silicon-based electrodes. The first process only uses the PAECE process, in the case of 10 wt% HF, 1 wt% surfactant alcohol, 3.5 V bias voltage, and 8 hr etching time, a random silicon hole structure with a depth of about 222 μm can be obtained; the second process is to use lithography process and RIE technology, after defining the etching window of the array pattern, it is made by PAECE technology, in the case of 2.5 wt% HF, 1 wt% surfactant DC, 3 V bias voltage, and 2 hr etching time, a silicon structure with a depth of about 162 μm can be obtained; the third process is to first use ICP-RIE technology to make a marcoporous array structure, and then use PAECE technology to roughen the inner wall of the hole structure. The parameters are 2.5 wt% HF, 5 wt% surfactant DC, 1 V bias voltage, and 2 hr etching time. After the three porous silicon structures are completed, structure surface will then be deposited a carbon film by CVD for increasing its chemical stability and conductivity. The electrolyte will be formed by using polymer materials as substrate, mixed with graphene flakes, further doped with transition metal oxide (RuO2). Coated on the structure surface, placed the specimen in a vacuum chamber, and the polymer electrolyte is infiltrated into the porous silicon structures by means of vacuum suction, and then the solid electrolyte can be formed to achieve the development of high load-bearing and anti-shock supercapacitor, and then measure C-V curve and Galvanostatic charge/discharge curve by potentiostat. Since the silicon-based electrode using the second process encounters the problem of excessive ridgeline etching during the mass production of the structure, it is not suitable for the production of supercapacitors. The third process encounters a linear relationship between voltage and current in C-V curve after the assembly test. The GCD curve shows the phenomenon that the current cannot be discharged after charging, which means that the internal resistance of the capacitor is too high. From these two points, it is speculated that the selected chip resistance is too high and the capacitor cannot operate normally. Therefore, this research focuses on the first process using pure PAECE to make silicon-based electrodes. The capacitance of 5 wt% graphene and 5 wt% RuO2 is 1.5 F/g at 0.127 A/g. And 88% of the capacitance retention rate is still maintained at 50th cycle, and 95% of the capacitance retention rate is still maintained under the acceleration of 30 g. The capacitor load will not be damaged until it exceeds 24.5 kPa, and the capacitance value still retains 55% of the original performance.