With the extensive industrial growth driven by the Fourth Industrial Revolution and the excessive use of fossil fuels, greenhouse gas emissions have accelerated global warming. Energy harvesting technologies have garnered significant attention as a potential solution to this issue. Among them, triboelectric nanogenerators (TENGs) have emerged as promising candidates for energy collection and conversion. However, TENGs typically face limitations in providing an efficient energy supply due to their high output voltage and low output current. To overcome these challenges, numerous studies have explored various methods to enhance the output performance by increasing the surface area of the triboelectric materials. Herein, we report a high-output TENG fabricated through a simple scratch process. By utilizing sandpaper, typically used for abrasion or polishing, the surface roughness of the triboelectric material PFA was increased through surface scratching. The surface-engineered TENG, prepared through this simple and rapid process, demonstrated enhanced output characteristics with a voltage of 276 V and a current of 72 μA, showing a 21% increase in voltage and a 41% increase in current compared to the non-engineered counterpart, providing sufficient energy to power an LED. These results indicate that the scratch-based surface modification process using sandpaper offers an effective solution for improving triboelectric output performance, establishing TENGs as a key contributor to sustainable energy supply.
The characteristics of write discharge were investigated when the conventional driving method with the unipolar sustain voltages, and the single sustain driving method applying the bipolar sustain voltage were applied in an AC plasma display. In the case of having a single sustain waveform, the strength of the write discharge is weakened compared to the conventional driving method during the address period, because the wall charge inside the panel is more dissipated by the lower scanning voltage. In the driving method with a single sustain waveform, the bias voltage of the other electrodes was changed to improve the write discharge characteristics. As a result, the intensity of the discharge was enhanced by 32% and the delay time was shortened by 60 μs.
In this paper, We studied the change of surface and variation of elements on both electrodes of hydrogen generator of alkaline electrolysis in use of FE-SEM and SIMS. We used the stainless steel 316(6(X) p m) as electrode in condition of 25%KOH, 60℃ Temperature. The results show that the intensity of elements (C, Si, P. S. Ti, Cr, Mn, Fe, Ni, Mo) of Positive Electrode are decreased as much as about 101 than the original electrode. Thickness of Positive Electrode is decreased about 40 pin after chemical reaction. The negative electrode, however, shows a slight variation in the intensity of elements (C, Si, P. Fe, Ni, Mn, Mo) but Change of thickness and surface` shape of electrode show nothing after chemical reaction. The change in thickness and variation of Stainless Steel 316 cause the lifetime of electrode to be shorted. We also observed hydrogen. oxygen, potassium in both electrodes. Especially, The potassium is increased in proportional with depth of positive electrode. this means the concentration of alkali solutions is changed. and so we have to supply alkaline solution to generator in order to produce same quantity of hydrogen gas continuously, we hope that this study gives a foundation to develop the electrode for hydrogen generator of alkaline electrolysis.