The mixed teaching mode plays an increasingly important role in stimulating students’interest and autonomy in learning,and strengthening students’learning ability.The full integration of mixed teaching mode and micr...The mixed teaching mode plays an increasingly important role in stimulating students’interest and autonomy in learning,and strengthening students’learning ability.The full integration of mixed teaching mode and microelectronics teaching can not only achieve the teaching objectives smoothly,but also enable students to deepen their understanding and memory of relevant knowledge with the help of diversified and interesting teaching methods.Therefore,this paper takes the microelectronics course as an example to practice and explore the effective ways to carry out the mixed teaching mode.Teachers should not make full use of online and offline teaching resources,but also actively improve the traditional assessment systems.Through the continuous improvement of the practicality of online and offline teaching content,an easy-to-complex teaching method with a coherent content structure can be adopted to stimulate students’learning motivation,improve their enthusiasm for participation,and lay a solid foundation for further improvements in the teaching of microelectronics technology.展开更多
We report a simple method for fabricating all-solid-state micro-supercapacitors, utilizing laser writing technology. Porous graphene films with three-dimensional networks induced by laser from commercial polymer was a...We report a simple method for fabricating all-solid-state micro-supercapacitors, utilizing laser writing technology. Porous graphene films with three-dimensional networks induced by laser from commercial polymer was acted as scaffold for loading MnO2, a typical pseudocapacitive materials. Using gel electrolyte, all-solid-state pseudocapacitive micro-supercapacitors were fabricated. Compare to traditional printing and lithography techniques produced micro-supercapacitors, the as-fabricated devices demonstrate high volumetric capacitances, good stability and low leakage current, indicating a scalable and facile approach for future energy storage devices in portable microelectronics.展开更多
文摘The mixed teaching mode plays an increasingly important role in stimulating students’interest and autonomy in learning,and strengthening students’learning ability.The full integration of mixed teaching mode and microelectronics teaching can not only achieve the teaching objectives smoothly,but also enable students to deepen their understanding and memory of relevant knowledge with the help of diversified and interesting teaching methods.Therefore,this paper takes the microelectronics course as an example to practice and explore the effective ways to carry out the mixed teaching mode.Teachers should not make full use of online and offline teaching resources,but also actively improve the traditional assessment systems.Through the continuous improvement of the practicality of online and offline teaching content,an easy-to-complex teaching method with a coherent content structure can be adopted to stimulate students’learning motivation,improve their enthusiasm for participation,and lay a solid foundation for further improvements in the teaching of microelectronics technology.
基金financially supported by the National Natural Science Foundation of China(Nos.51706016,51506014)the China Postdoctoral Science Foundation(No.2017T100677)
文摘We report a simple method for fabricating all-solid-state micro-supercapacitors, utilizing laser writing technology. Porous graphene films with three-dimensional networks induced by laser from commercial polymer was acted as scaffold for loading MnO2, a typical pseudocapacitive materials. Using gel electrolyte, all-solid-state pseudocapacitive micro-supercapacitors were fabricated. Compare to traditional printing and lithography techniques produced micro-supercapacitors, the as-fabricated devices demonstrate high volumetric capacitances, good stability and low leakage current, indicating a scalable and facile approach for future energy storage devices in portable microelectronics.
