The use of water resources for energy generation has become increasingly prevalent,encompassing the conversion of kinetic energy from streams,tides,and waves into renewable electrical power.Water energy sources offer ...The use of water resources for energy generation has become increasingly prevalent,encompassing the conversion of kinetic energy from streams,tides,and waves into renewable electrical power.Water energy sources offer numerous benefits,including widespread availability,stability,and the absence of carbon dioxide and other greenhouse gas emissions,making them a clean and environmentally friendly form of energy.In this work,we develop a droplet-based liquid-solid triboelectric nanogenerator(LS-TENG)using sophisticatedly designed inflatable columnar structures with inner and outer dual-electrodes.This device can be utilized to harvest both the internal droplet-rolling mechanical energy and the external droplet-falling mechanical energy,capable of being assembled into various structures for versatile applications.The design incorporates a combined structure of both internal and external TENG to optimize output performance via multiple energy harvesting strategies.The internal structure features a dual-electrode columnar-shaped LS-TENG,designed to harvest fluid kinetic energy from water droplets.By leveraging the back-and-forth motion of a small amount of water within the air column,mechanical energy can be readily collected,achieving a maximum mass power density of 9.02 W·Kg^(−1)and an energy conversion efficiency of 10.358%.The external component is a droplet-based LS-TENG,which utilizes a double-layer capacitor switch effect elucidated with an equivalent circuit model.Remarkably,without the need for pre-charging,a single droplet can generate over 140 V of high voltage,achieving a maximum power density of 7.35 W·m^(−2)and an energy conversion efficiency of 22.058%.The combined LS-TENG with a sophisticated inflatable columnar structure can simultaneously collect multiple types of energy with high efficacy,exhibiting great significance in potential applications such as TENG aeration rollers,inflatable lifejacket,wind energy harvesting,TENG tents,and green houses.展开更多
V/Ag multilayers with different periodic thicknesses were fabricated by magnetron sputtering deposition. The columnar structure and the orientation relationship of the multilayers were investigated by transmission ele...V/Ag multilayers with different periodic thicknesses were fabricated by magnetron sputtering deposition. The columnar structure and the orientation relationship of the multilayers were investigated by transmission electron microscopy, high resolution transmission electron microscopy, selected-area electron diffraction and X-ray diffraction. It was found that the multilayered structure became flatter as increasing individual layer thickness from 2 to 6 nm, and then became waved as the individual layer thickness increases to 8 nm. At the beginning of the growth, the morphology of the multilayers with small periodic thickness was influenced mainly by thermodynamic instabilities, and the morphology of the multilayers with larger periodic thickness was mainly influenced mainly by the columnar growth of V. When the waved interfaces were formed, the continuum growth of the multilayers was also influenced by the shadowing effect and the finite atomic size effect. All of these factors resulted in the columnar structure of the multilayers. Multilayers with small periodic thickness presented strong orientation relationship. Nano-hardness tests indicated that multilayers with flat sublayer morphology and clear interfaces exhibited larger hardness.展开更多
The microstructure and electrochemical characteristics of Ml(NiCoMnAl) 5 alloys prepared by both the melt spinning method and the conventional induction melting were investigated and compared. SEM and XRD studies sh...The microstructure and electrochemical characteristics of Ml(NiCoMnAl) 5 alloys prepared by both the melt spinning method and the conventional induction melting were investigated and compared. SEM and XRD studies show that the microstructure of melt spinning alloys is columnar structure. With increasing melt spinning rate, the crystal grains become finer and preferentially grow along (111)[111] direction. The melt spinning and cast alloys belong to CaCu 5 type hexagonal crystal structure. The electrochemical measurements show that the initial capacities of melt spinning alloy electrodes are all above 210 mAh·g -1 with good activation behavior, reaching their maximum capacities after two charge discharge cycles. The maximum capacity (294 mAh·g -1 ) of melt spinning (10 m·s -1 ) alloy electrodes is as the same as that of as cast alloy electrode, and stability of charge discharge cycles of all melt spinning alloy electrodes is better than that of the as cast alloy electrodes. When charged at 600 mA·g -1 , the capacity of melt spinning (10 m·s -1 ) alloy electrode could reach 65% of its maximum capacity about 45 min with high rate discharge capability; but with the cycle number increasing, the stability of its capacity is less than that electrodes of melt spinning rate.展开更多
基金supported by the National Key Research and Development Program of China(2023YFB3208102,2021YFB3200304)the National Natural Science Foundation of China(52073031)+2 种基金Beijing Nova Program(Z211100002121148)Fundamental Research Funds for the Central Universities(E0EG6801X2)the‘Hundred Talents Program’of the Chinese Academy of Sciences.
文摘The use of water resources for energy generation has become increasingly prevalent,encompassing the conversion of kinetic energy from streams,tides,and waves into renewable electrical power.Water energy sources offer numerous benefits,including widespread availability,stability,and the absence of carbon dioxide and other greenhouse gas emissions,making them a clean and environmentally friendly form of energy.In this work,we develop a droplet-based liquid-solid triboelectric nanogenerator(LS-TENG)using sophisticatedly designed inflatable columnar structures with inner and outer dual-electrodes.This device can be utilized to harvest both the internal droplet-rolling mechanical energy and the external droplet-falling mechanical energy,capable of being assembled into various structures for versatile applications.The design incorporates a combined structure of both internal and external TENG to optimize output performance via multiple energy harvesting strategies.The internal structure features a dual-electrode columnar-shaped LS-TENG,designed to harvest fluid kinetic energy from water droplets.By leveraging the back-and-forth motion of a small amount of water within the air column,mechanical energy can be readily collected,achieving a maximum mass power density of 9.02 W·Kg^(−1)and an energy conversion efficiency of 10.358%.The external component is a droplet-based LS-TENG,which utilizes a double-layer capacitor switch effect elucidated with an equivalent circuit model.Remarkably,without the need for pre-charging,a single droplet can generate over 140 V of high voltage,achieving a maximum power density of 7.35 W·m^(−2)and an energy conversion efficiency of 22.058%.The combined LS-TENG with a sophisticated inflatable columnar structure can simultaneously collect multiple types of energy with high efficacy,exhibiting great significance in potential applications such as TENG aeration rollers,inflatable lifejacket,wind energy harvesting,TENG tents,and green houses.
基金the National Natural Science Foundation of China(Nos.91026014 and 11175133)the Foundations from Chinese Ministry of Education(Nos.2011014113004 and NCET-13-0438)the Hubei Provincial Natural Science Foundation(No.2012FFA042) for financial support
文摘V/Ag multilayers with different periodic thicknesses were fabricated by magnetron sputtering deposition. The columnar structure and the orientation relationship of the multilayers were investigated by transmission electron microscopy, high resolution transmission electron microscopy, selected-area electron diffraction and X-ray diffraction. It was found that the multilayered structure became flatter as increasing individual layer thickness from 2 to 6 nm, and then became waved as the individual layer thickness increases to 8 nm. At the beginning of the growth, the morphology of the multilayers with small periodic thickness was influenced mainly by thermodynamic instabilities, and the morphology of the multilayers with larger periodic thickness was mainly influenced mainly by the columnar growth of V. When the waved interfaces were formed, the continuum growth of the multilayers was also influenced by the shadowing effect and the finite atomic size effect. All of these factors resulted in the columnar structure of the multilayers. Multilayers with small periodic thickness presented strong orientation relationship. Nano-hardness tests indicated that multilayers with flat sublayer morphology and clear interfaces exhibited larger hardness.
文摘The microstructure and electrochemical characteristics of Ml(NiCoMnAl) 5 alloys prepared by both the melt spinning method and the conventional induction melting were investigated and compared. SEM and XRD studies show that the microstructure of melt spinning alloys is columnar structure. With increasing melt spinning rate, the crystal grains become finer and preferentially grow along (111)[111] direction. The melt spinning and cast alloys belong to CaCu 5 type hexagonal crystal structure. The electrochemical measurements show that the initial capacities of melt spinning alloy electrodes are all above 210 mAh·g -1 with good activation behavior, reaching their maximum capacities after two charge discharge cycles. The maximum capacity (294 mAh·g -1 ) of melt spinning (10 m·s -1 ) alloy electrodes is as the same as that of as cast alloy electrode, and stability of charge discharge cycles of all melt spinning alloy electrodes is better than that of the as cast alloy electrodes. When charged at 600 mA·g -1 , the capacity of melt spinning (10 m·s -1 ) alloy electrode could reach 65% of its maximum capacity about 45 min with high rate discharge capability; but with the cycle number increasing, the stability of its capacity is less than that electrodes of melt spinning rate.
