Triboelectric nanogenerator(TENG)is regarded as an effective strategy to convert environment mechanical energy into electricity to meet the distributed energy demand of large number of sensors in the Internet of Thing...Triboelectric nanogenerator(TENG)is regarded as an effective strategy to convert environment mechanical energy into electricity to meet the distributed energy demand of large number of sensors in the Internet of Things(IoTs).Although TENG based on the coupling of triboelectrification and air-breakdown achieves a large direct current(DC)output,material abrasion is a bottleneck for its applications.Here,inspired by primary cell and its DC signal output characteristics,we propose a novel primary cell structure TENG(PC-TENG)based on contact electrification and electrostatic induction,which has multiple working modes,including contact separation mode,freestanding mode and rotation mode.The PC-TENG produces DC output and operates at low surface contact force.It has an ideal effective charge density(1.02 m Cm^(-2)).Meanwhile,the PC-TENG shows a superior durability with 99% initial output after 100,000 operating cycles.Due to its excellent output performance and durability,a variety of commercial electronic devices are powered by PC-TENG via harvesting wind energy.This work offers a facile and ideal scheme for enhancing the electrical output performance of DC-TENG at low surface contact force and shows a great potential for the energy harvesting applications in IoTs.展开更多
Direct current triboelectric nanogenerators(DC-TENGs)are a groundbreaking technology to capture micromechanical energy from the natural environment,which is crucial for directly powering sensor networks.However,the re...Direct current triboelectric nanogenerators(DC-TENGs)are a groundbreaking technology to capture micromechanical energy from the natural environment,which is crucial for directly powering sensor networks.However,the research bottleneck in enhancing the triboelectric electrification capability and charge storage capability of dielectrics has hindered the overall performance breakthroughs of the DC-TENG.Here,a field emission model-based DC-TENG(FEM-TENG)is proposed,inspired by lightning rods.The enhanced local electric field between dielectric materials and electrodes induces strong electron tunneling,which improves charge neutralization on the surface of materials and their internal charge storage space,thereby utilizing the dielectric volume effect effectively and strengthening triboelectricity.Guided by the field emission model,the FEM-TENG with a historic crest factor of 1.00375 achieves a groundbreaking record of an average power density of 16.061 W m^(-2)Hz^(-1)(1,591 W m^(-3)Hz^(-1)),which is 5.36-fold of the latest DC-TENG.In particular,the FEM-TENG with high durability(100%)truly realizes the collection of breeze energy and continuously drives 50 thermohygrometers.Four additional applications exemplify the FEM-TENG,enabling comprehensive sensing of land,water,and air.This work proposes a paradigm strategy for the in-depth utilization of dielectric films,aiming to enhance the output power of DC-TENGs.展开更多
Triboelectric nanogenerator(TENG)is a new cost-effective blue energy harvesting technology for its great performance in low frequency.However,many related energy harvesters operate on water surface,ignoring the ocean...Triboelectric nanogenerator(TENG)is a new cost-effective blue energy harvesting technology for its great performance in low frequency.However,many related energy harvesters operate on water surface,ignoring the ocean’s depth.Herein,a chainflipped plate TENG(CFP-TENG),consisting of longitudinally arranged repeating units,is proposed to collect wave energy.The chain structure design allows the surface wave energy to act effectively on the underwater generator.The maximum output power per unit ocean area reaches 1.5 W·m^(-2) at a loading resistance of 30 MΩ.Optimization of device parameters and application demonstrations are explored.Compared with previous works,the utilization rate of wave energy has been significantly improved.This work not only provides a new method to optimize the output of TENG but also makes a crucial step in promoting practical applications of TENG in renewable blue energy.展开更多
Triboelectric nanogenerator (TENG) is a promising strategy for harvesting low frequency mechanical energy. However, the bottlenecks of limited electric output by air/dielectric breakdown and poor durability by materia...Triboelectric nanogenerator (TENG) is a promising strategy for harvesting low frequency mechanical energy. However, the bottlenecks of limited electric output by air/dielectric breakdown and poor durability by material abrasion seriously restrict its further improvement. Herein, we propose a liquid lubrication promoted sliding mode TENG to address both issues. Liquid lubrication greatly reduces interface material abrasion, and its high breakdown strength and charge transmission effect further enhance device charge density. Besides, the potential decentralization design by the voltage balance bar effectively suppresses the dielectric breakdown. In this way, the average power density up to 87.26 W·m^(-2)·Hz^(-1), energy conversion efficiency of 48%, and retention output of 90% after 500,000 operation cycles are achieved, which is the highest average power density and durability currently. Finally, a cell phone is charged to turn on by a palm-sized TENG device at 2 Hz within 25 s. This work has a significance for the commercialization of TENG-based self-powered systems.展开更多
基金financially suppor ted by the National Key Research and Development Program(2018YFB2100100)the NSFC(U21A20147,52073037,62004017)。
文摘Triboelectric nanogenerator(TENG)is regarded as an effective strategy to convert environment mechanical energy into electricity to meet the distributed energy demand of large number of sensors in the Internet of Things(IoTs).Although TENG based on the coupling of triboelectrification and air-breakdown achieves a large direct current(DC)output,material abrasion is a bottleneck for its applications.Here,inspired by primary cell and its DC signal output characteristics,we propose a novel primary cell structure TENG(PC-TENG)based on contact electrification and electrostatic induction,which has multiple working modes,including contact separation mode,freestanding mode and rotation mode.The PC-TENG produces DC output and operates at low surface contact force.It has an ideal effective charge density(1.02 m Cm^(-2)).Meanwhile,the PC-TENG shows a superior durability with 99% initial output after 100,000 operating cycles.Due to its excellent output performance and durability,a variety of commercial electronic devices are powered by PC-TENG via harvesting wind energy.This work offers a facile and ideal scheme for enhancing the electrical output performance of DC-TENG at low surface contact force and shows a great potential for the energy harvesting applications in IoTs.
基金supported by the National Natural Science Foundation ofChina(NSFC)(52272191)the National Key R&D Project from Minister of Science and Technology(2021YFA1201602)the Fundamental Research Funds for the Central Universities(grantno.2021CDJQY-005,2022CCJJCLK001).
文摘Direct current triboelectric nanogenerators(DC-TENGs)are a groundbreaking technology to capture micromechanical energy from the natural environment,which is crucial for directly powering sensor networks.However,the research bottleneck in enhancing the triboelectric electrification capability and charge storage capability of dielectrics has hindered the overall performance breakthroughs of the DC-TENG.Here,a field emission model-based DC-TENG(FEM-TENG)is proposed,inspired by lightning rods.The enhanced local electric field between dielectric materials and electrodes induces strong electron tunneling,which improves charge neutralization on the surface of materials and their internal charge storage space,thereby utilizing the dielectric volume effect effectively and strengthening triboelectricity.Guided by the field emission model,the FEM-TENG with a historic crest factor of 1.00375 achieves a groundbreaking record of an average power density of 16.061 W m^(-2)Hz^(-1)(1,591 W m^(-3)Hz^(-1)),which is 5.36-fold of the latest DC-TENG.In particular,the FEM-TENG with high durability(100%)truly realizes the collection of breeze energy and continuously drives 50 thermohygrometers.Four additional applications exemplify the FEM-TENG,enabling comprehensive sensing of land,water,and air.This work proposes a paradigm strategy for the in-depth utilization of dielectric films,aiming to enhance the output power of DC-TENGs.
基金supported by the National Key Research and Development Program from Minister of Science and Technology(No.2021YFA1201602)the National Natural Science Foundation of China(Nos.U21A20147 and 52073037).
文摘Triboelectric nanogenerator(TENG)is a new cost-effective blue energy harvesting technology for its great performance in low frequency.However,many related energy harvesters operate on water surface,ignoring the ocean’s depth.Herein,a chainflipped plate TENG(CFP-TENG),consisting of longitudinally arranged repeating units,is proposed to collect wave energy.The chain structure design allows the surface wave energy to act effectively on the underwater generator.The maximum output power per unit ocean area reaches 1.5 W·m^(-2) at a loading resistance of 30 MΩ.Optimization of device parameters and application demonstrations are explored.Compared with previous works,the utilization rate of wave energy has been significantly improved.This work not only provides a new method to optimize the output of TENG but also makes a crucial step in promoting practical applications of TENG in renewable blue energy.
基金This work is financially supported by the National Key Research and Development Program of China(2021YFA1201602)the National Natural Science Foundation of China(U21A20147,62071074,and 52073037)the Fundamental Research Funds for the Central Universities(2021CDJQY-019).
文摘Triboelectric nanogenerator (TENG) is a promising strategy for harvesting low frequency mechanical energy. However, the bottlenecks of limited electric output by air/dielectric breakdown and poor durability by material abrasion seriously restrict its further improvement. Herein, we propose a liquid lubrication promoted sliding mode TENG to address both issues. Liquid lubrication greatly reduces interface material abrasion, and its high breakdown strength and charge transmission effect further enhance device charge density. Besides, the potential decentralization design by the voltage balance bar effectively suppresses the dielectric breakdown. In this way, the average power density up to 87.26 W·m^(-2)·Hz^(-1), energy conversion efficiency of 48%, and retention output of 90% after 500,000 operation cycles are achieved, which is the highest average power density and durability currently. Finally, a cell phone is charged to turn on by a palm-sized TENG device at 2 Hz within 25 s. This work has a significance for the commercialization of TENG-based self-powered systems.
