As people's living standards become higher and higher, the requirements for computer technology are becoming more and stricter, including the storage performance of computers is particularly demanding. However, there is currently no suitable method for effectively analyzing the storage performance of a computer. In order to carry out in-depth and effective research on the charge storage performance of the memory, based on the working principle of electric field force microscopy, a detailed analysis of the organic small molecule material, polyvinylpyrrolidone (PVP), was carried out by constructing a molecular dynamics model. It turns out that PVP exhibits different characteristics at different temperatures. We can think that the extremely low temperature rise is beneficial to improve the storage performance of storage components, but it cannot exceed 360K. The paper also analyzes the aging properties of the charge. It is found that the stored charge in the device has good time-lasting performance. At the same time, the capacitance value of the film changes with time and has very small fluctuations, showing a very stable property. This shows that the loss of charge is very small and has good charge aging properties.

Wenjie Jiao, Xu Wang. Storage Characteristics and Mechanism of Organic Small Molecule Charge-Capturing Materials Based on Electric Field Force Microscopy. Academic Journal of Materials & Chemistry (2023) Vol. 4, Issue 5: 61-70. https://doi.org/10.25236/AJMC.2023.040509.

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