Metal halide perovskites exhibit excellent absorption properties,high carrier mobility,and remarkable charge transfer ability,showcasing significant potential as light harvesters in new-generation photovoltaic and opt...Metal halide perovskites exhibit excellent absorption properties,high carrier mobility,and remarkable charge transfer ability,showcasing significant potential as light harvesters in new-generation photovoltaic and optoelectronic technologies.Their development has seen unprecedented growth since their discovery.Similar to metal halide perovskite developments,perovskite quantum dots(PQDs)have demonstrated significant versatility in terms of shape,dimension,bandgap,and optical properties,making them suitable for the development of optoelectronic devices.This review discusses various fabrication methods of PQDs,delves into their degradation mechanisms,and explores strategies for enhancing their performance with their applications in a variety of technological fields.Their elevated surface-to-volume ratio highlights their importance in increasing solar cell efficiency.PQDs are also essential for increasing the performance of perovskite solar cells,photodetectors,and lightemitting diodes,which makes them indispensable for solid-state lighting applications.PQDs'unique optoelectronic characteristics make them suitable for sophisticated sensing applications,giving them greater capabilities in this field.Furthermore,PQDs'resistive switching behavior makes them a good fit for applications in memory devices.PQDs'vast potential also encompasses the fields of quantum optics and communication,especially for uses like nanolasers and polarized light detectors.Even though stability and environmental concerns remain major obstacles,research efforts are being made to actively address these issues,enabling PQDs to obtain their full potential in device applications.Simply put,understanding PQDs'real potential lies in overcoming obstacles and utilizing their inherent qualities.展开更多
Triboelectric nanogenerators(TENGs)have emerged as a promising technology to harvest electrical energy from natural motions such as human movement,wind,and water flow.Although TENGs show significant potential in small...Triboelectric nanogenerators(TENGs)have emerged as a promising technology to harvest electrical energy from natural motions such as human movement,wind,and water flow.Although TENGs show significant potential in small-scale applications,developing large-scale TENGs capable of generating high power remains a significant challenge.Several factors that can affect the performance of large-scale TENGs are being investigated to overcome this challenge,including the size and configuration of dielectric materials.This study optimizes dielectrics regarding surface area,thickness,and multicell configuration to improve harvested electrical power density in large-scale TENGs.In the studies,glass fiber was used as the positive dielectric,and multipurpose white silicone was used as the negative dielectric because of their high tribo-potential,durability,and easy accessibility.In the size optimization phase,dielectric thicknesses and surface areas that provide the maximum power density were determined.Subsequently,horizontal and vertical multicell configurations were examined to efficiently integrate size-optimized dielectrics.The results reveal that large-scale TENGs with vertical multicell configurations can achieve high and usable energy density for electronics.The findings provide valuable insight into the development of large-scale TENGs with advanced power generation capabilities.展开更多
基金supported by the National Research Foundation of Korea(NRF)grant funded by the Korean government(MSIT)(no.RS-2022-00165798)。
文摘Metal halide perovskites exhibit excellent absorption properties,high carrier mobility,and remarkable charge transfer ability,showcasing significant potential as light harvesters in new-generation photovoltaic and optoelectronic technologies.Their development has seen unprecedented growth since their discovery.Similar to metal halide perovskite developments,perovskite quantum dots(PQDs)have demonstrated significant versatility in terms of shape,dimension,bandgap,and optical properties,making them suitable for the development of optoelectronic devices.This review discusses various fabrication methods of PQDs,delves into their degradation mechanisms,and explores strategies for enhancing their performance with their applications in a variety of technological fields.Their elevated surface-to-volume ratio highlights their importance in increasing solar cell efficiency.PQDs are also essential for increasing the performance of perovskite solar cells,photodetectors,and lightemitting diodes,which makes them indispensable for solid-state lighting applications.PQDs'unique optoelectronic characteristics make them suitable for sophisticated sensing applications,giving them greater capabilities in this field.Furthermore,PQDs'resistive switching behavior makes them a good fit for applications in memory devices.PQDs'vast potential also encompasses the fields of quantum optics and communication,especially for uses like nanolasers and polarized light detectors.Even though stability and environmental concerns remain major obstacles,research efforts are being made to actively address these issues,enabling PQDs to obtain their full potential in device applications.Simply put,understanding PQDs'real potential lies in overcoming obstacles and utilizing their inherent qualities.
基金supported by the Scientific and Technological Research Council of Turkey(TUBITAK)under project number 121M608.
文摘Triboelectric nanogenerators(TENGs)have emerged as a promising technology to harvest electrical energy from natural motions such as human movement,wind,and water flow.Although TENGs show significant potential in small-scale applications,developing large-scale TENGs capable of generating high power remains a significant challenge.Several factors that can affect the performance of large-scale TENGs are being investigated to overcome this challenge,including the size and configuration of dielectric materials.This study optimizes dielectrics regarding surface area,thickness,and multicell configuration to improve harvested electrical power density in large-scale TENGs.In the studies,glass fiber was used as the positive dielectric,and multipurpose white silicone was used as the negative dielectric because of their high tribo-potential,durability,and easy accessibility.In the size optimization phase,dielectric thicknesses and surface areas that provide the maximum power density were determined.Subsequently,horizontal and vertical multicell configurations were examined to efficiently integrate size-optimized dielectrics.The results reveal that large-scale TENGs with vertical multicell configurations can achieve high and usable energy density for electronics.The findings provide valuable insight into the development of large-scale TENGs with advanced power generation capabilities.
