Piezoelectric materials are capable of converting between mechanical and electrical energy,and are suitable for sensing,actuating and energy harvesting.While most conventional piezoelectric materials are brittle solid...Piezoelectric materials are capable of converting between mechanical and electrical energy,and are suitable for sensing,actuating and energy harvesting.While most conventional piezoelectric materials are brittle solids,flexible piezoelectric materials(FPM)retain functionality even under bending and stretching conditions.This characteristic has garnered increasing attention in recent years,particularly for wearable devices,where the ability to adapt to dynamic human movements is essential.In addition,wearable devices also demand excellent conformability,durability,and adaptability to miniaturization.FPM emerge as a promising solution that meet all these requirements.This review thus aims to offer a comprehensive summary of recent advances in the field of FPM,including piezoelectric polymers,composites,and inorganic flexible films.We introduce and categorize the specific features of these materials and highlight their emerging applications in electronic devices,and comment on the prospect of FPM as well as their potential challenges.展开更多
In the mountain area of inland Heihe River Basin at Hexi Corridor of northwest China during the vegetation growing season from May to September, the Simultaneous Heat and Water (SHAW) model of Soil-Vegetation-Atmosphe...In the mountain area of inland Heihe River Basin at Hexi Corridor of northwest China during the vegetation growing season from May to September, the Simultaneous Heat and Water (SHAW) model of Soil-Vegetation-Atmosphere Transfer (SVAT) system is applied to simulating and studying energy and water balance of the soil-residue-plant canopy layers in the Picea crassifolia forest and the grassland by the forest at the shaded slope and the grassland at the sun-facing slope. The simulation of energy balance indicates that net radiation of the grass- land at the sun-facing slope is more than that of the Picea crassifolia forest and the grassland by the forest at the shaded slope. The energy outgoing components are the first latent heat and next sensible heat from the grassland both at the shaded slope and the sun-facing slope, but those at the former are less. The energy outgoing components are the first sensible heat and next latent heat from the Picea crassifolia forest. The composition and distribution of energy in the soil-residue-plant canopy layers in the Picea crassifolia forest and the grassland by the forest at the shaded slope make the soil layer receive less energy, which therefore, especially the forest possesses the energy conditions for soil water conservation. The simulation of water balance indicates that the water loss of the grassland at the sun-facing slope is mainly caused by soil evaporation, while evapotranspiration of the Picea crassifolia forest and the grassland by the forest at the shaded slope is less than that of the grassland at the sun-facing slope. Half of the evapotranspiration of the Picea crassifolia forest and the grassland by the forest at the shaded slope is consumed by transpiration. After precipitation, the soil water storage is increased much more for the Picea crassifolia forest and also more for the grassland by the forest at the shaded slope. Therefore the shaded slope vegetation, especially the forest is favorable for soil water storage.展开更多
基金supported by National Natural Science Foundation of China(No.12474213,52032005,82225012,52325204,and U22A20254)National Key Research and Development Program of China(No.2024YFF1400700)supported by Wuzhen Laboratory,and Deutsche Forschungsgemeinschaft(No.414311761).
文摘Piezoelectric materials are capable of converting between mechanical and electrical energy,and are suitable for sensing,actuating and energy harvesting.While most conventional piezoelectric materials are brittle solids,flexible piezoelectric materials(FPM)retain functionality even under bending and stretching conditions.This characteristic has garnered increasing attention in recent years,particularly for wearable devices,where the ability to adapt to dynamic human movements is essential.In addition,wearable devices also demand excellent conformability,durability,and adaptability to miniaturization.FPM emerge as a promising solution that meet all these requirements.This review thus aims to offer a comprehensive summary of recent advances in the field of FPM,including piezoelectric polymers,composites,and inorganic flexible films.We introduce and categorize the specific features of these materials and highlight their emerging applications in electronic devices,and comment on the prospect of FPM as well as their potential challenges.
基金supported by the Chinese Academy of Sciences(Grant Nos.KZCX1-10-03-01 and KZCX3-SW-329)the National Natural Science Foun dati on ofChina(Grant No.49731030)AIACC-AS25,UNEP.
文摘In the mountain area of inland Heihe River Basin at Hexi Corridor of northwest China during the vegetation growing season from May to September, the Simultaneous Heat and Water (SHAW) model of Soil-Vegetation-Atmosphere Transfer (SVAT) system is applied to simulating and studying energy and water balance of the soil-residue-plant canopy layers in the Picea crassifolia forest and the grassland by the forest at the shaded slope and the grassland at the sun-facing slope. The simulation of energy balance indicates that net radiation of the grass- land at the sun-facing slope is more than that of the Picea crassifolia forest and the grassland by the forest at the shaded slope. The energy outgoing components are the first latent heat and next sensible heat from the grassland both at the shaded slope and the sun-facing slope, but those at the former are less. The energy outgoing components are the first sensible heat and next latent heat from the Picea crassifolia forest. The composition and distribution of energy in the soil-residue-plant canopy layers in the Picea crassifolia forest and the grassland by the forest at the shaded slope make the soil layer receive less energy, which therefore, especially the forest possesses the energy conditions for soil water conservation. The simulation of water balance indicates that the water loss of the grassland at the sun-facing slope is mainly caused by soil evaporation, while evapotranspiration of the Picea crassifolia forest and the grassland by the forest at the shaded slope is less than that of the grassland at the sun-facing slope. Half of the evapotranspiration of the Picea crassifolia forest and the grassland by the forest at the shaded slope is consumed by transpiration. After precipitation, the soil water storage is increased much more for the Picea crassifolia forest and also more for the grassland by the forest at the shaded slope. Therefore the shaded slope vegetation, especially the forest is favorable for soil water storage.
