In article number https://doi.org/10.1002/bmm2.12020, Changyong Wang, Xu Li, Jin Zhou and their co‐workers have systematically summarized the recent advances on cardiac electronic devices (CEDs) based on triboelectric nanogenerators (TENGs) and piezoelectric nanogenerators (PENGs). They have described the type and function of TENGs and PENGs for preventing and treating heart diseases. In addition, they have also discussed remaining challenges, and future development trends of NG‐based CEDs.
Heart diseases pose a serious threat to human health, and their incidence has been increasing in recent years. In past decades, many strategies have been developed to decrease the mortality and morbidity of heart diseases, among them, strategies involving cardiac electronic devices (CEDs) have been effective in treating and preventing heart diseases. To allow the CEDs to work continuously without the need to replace batteries and to meet the requirements of convenience and comfort in the process of use, nanogenerator (NG)-based CEDs were proposed, widely studied, continuously optimized in recent years owing to their advantages of small dimensions, self-powering ability, and good biocompatibility. In this review, recent improvements of NG-based CEDs of two typical types (i.e., triboelectric nanogenerator [TENG] and piezoelectric nanogenerator [PENG]) and their structures and functions are summarized and discussed. The demands, remaining challenges, and future development trends of NG-based CEDs are also discussed.
Mica, a commonly occurring mineral, has significant potential for various applications due to its unique structure and properties. However, due to its non-Van Der Waals bonded structure, it is difficult to exfoliate mica into ultrathin nanosheets. In this work, we report a rapid solvothermal microwave synthesis of 2D mica with short reaction time and energy conservation. The resulting exfoliated 2D mica nanosheets (eMica nanosheets) were characterized by various techniques, and their ability to capture CO2 was tested by thermogravimetric analysis (TGA). Our results showed an 87% increase in CO2 adsorption capacity with eMica nanosheets compared to conventional mica. Further characterization by Fourier-transform infrared spectroscopy (FTIR) and X-ray photoelectron spectroscopy (XPS), as well as first-principles calculations, showed that the high specific surface area and deposited K2CO3 layer contribute to the increased CO2 adsorption on the mica nanosheets. These results speak to the potential of high-quality eMica nanosheets and efficient synthesis processes to open new avenues for new physical properties of 2D materials and the development of CO2 capture technologies.
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