The effects of triboelectrification are usually regarded as the negative physical phenomenon in fabrication processes or experiments. In order to avoid the damage caused by the accumulation of triboelectric charge, it is necessary to increase energy costs because of the additive process of removing static electricity. However, a new type of energy technology called triboelectric nanogenerator was demonstrated by Prof. Zhong Lin Wang’s group in 2012, which is available to convert mechanical energy into electrical energy by triboelectric effect. The advantages of the triboelectric devices are not only allowing high selectivity of materials but also providing a new way to design sensors. Furthermore, electricity can also be used as a power supply in small electronic devices and has the opportunity to replace the external power supply in traditional sensors. The researches have also shown that technology provides a new perspective on the fields of small electronic products and sensors. In the first part of the thesis, we fabricated porous PDMS and systematically measured the performance of the porous dielectric material. The results showed that the porosity, working frequency, the methods of applying force and the rate of separation have a strong relationship with the formation of triboelectric charge density on the surface. Compared with pure PDMS, the porous PDMS has a maximum peak to peak output voltage of 18V, which gives 4.5-time enhancement when the operating frequency is 3 Hz and the applied pressure is 62.5 kPa. In addition, when the frequency is increased from 0.7 Hz to 3 Hz, there is a significant difference between the pure PDMS and the porous PDMS output voltage. The preparation of the porous PDMS in this study provides a low-cost, large-area manufacturing method compared to the chemical solvent dissolution method. Furthermore, we also attempt to provide optimum operating parameters of porous PDMS under the triboelectric device, which makes it useful for the applications of soft sensors in the robot industry and wearable devices. In the second part, we modified PDMS surfaces using plasma treatment. The results of the voltage of the porous PDMS was not obviously increased. However, it was found that if the surface was cleaned with 75% ethanol after the plasma treatment, the voltage signals gradually reversed which means the displacement current flows in the opposite direction between the upper and lower electrodes. The results suggest that the ions in the ethanol solution anchored on the reactive functional groups of the PDMS surface and changed the charge property. The modification of the surface can be applied to designing a surface charge pattern and electrostatic self-assembly of charged particles on the surface. Finally, we propose a new sensor based on the single electrode mode of triboelectric nanogenerator which can detect the direction due to the designable surface structure. The contact area is proportional to the voltage signal which can identify the moving direction of the finger on the structure. The design can also be extended to the applications of tactile sensors and electronic skin.