Transformation behavior and shape memory characteristics of a temperature gradient annealing(TGA)treated Ti-50.5Ni(at%)alloy have been investigated by means of differential scanning calorimetry(DSC)and thermal cycling...Transformation behavior and shape memory characteristics of a temperature gradient annealing(TGA)treated Ti-50.5Ni(at%)alloy have been investigated by means of differential scanning calorimetry(DSC)and thermal cycling tests under constant load.By annealing the specimen under the temperature gradient from 823 K to 658 K after solution treatment,the B19' martensitic transformation start temperature changed by 60 K along the length of sample(150mm).Temperature dependence of transformation elongation(dε/dT)of the TGA treated wire was found to be 0.16 %/K.By annealing the specimen under the temperature gradient from 823 K to 658 K after 47 % cold working without solution treatment,the B19' martensitic transformation start temperature changed by 61K along the length of sample(150mm).Temperature dependence of transformation elongation(dε/dT)of the TGA treated wire was found to be 0.04 %/K.The large decrease in dε/dT by cold working effect suggested that an introduction of dislocation was more effective than precipitates for lowering dε/dT.展开更多
Stretchable elastomer-based electrodes are considered promising energy storage electrodes for next-generation wearable/flexible electronics requiring various shape designs.However,these elastomeric electrodes suffer f...Stretchable elastomer-based electrodes are considered promising energy storage electrodes for next-generation wearable/flexible electronics requiring various shape designs.However,these elastomeric electrodes suffer from the limited electrical conductivity of current collectors,low charge storage capacities,poor interfacial interactions between elastomers and conductive/active materials,and lack of shape controllability.In this study,we report hierarchically micro/nano-wrinkle-structured elastomeric electrodes with notably high energy storage performance and good mechanical/electrochemical stabilities,simultaneously allowing various form factors.For this study,a swelling/deswelling-involved metal nanoparticle(NP)assembly is first performed on thiol-functionalized polydimethylsiloxane(PDMS)elastomers,generating a micro-wrinkled structure and a conductive seed layer for subsequent electrodeposition.After the assembly of metal NPs,the conformal electrodeposition of Ni and NiCo layered double hydroxides layers with a homogeneous nanostructure on the micro-wrinkled PDMS induces the formation of a micro/nano-wrinkled surface morphology with a large active surface area and high electrical conductivity.Based on this unique approach,the formed elastomeric electrodes show higher areal capacity and superior rate capability than conventional elastomeric electrodes while maintaining their electrical/electrochemical properties under external mechanical deformation.This notable mechanical/electrochemical performance can be further enhanced by using spiral-structured PDMS(stretchability of~500%)and porous-structured PDMS(areal capacity of~280μAh cm^(-2)).展开更多
文摘Transformation behavior and shape memory characteristics of a temperature gradient annealing(TGA)treated Ti-50.5Ni(at%)alloy have been investigated by means of differential scanning calorimetry(DSC)and thermal cycling tests under constant load.By annealing the specimen under the temperature gradient from 823 K to 658 K after solution treatment,the B19' martensitic transformation start temperature changed by 60 K along the length of sample(150mm).Temperature dependence of transformation elongation(dε/dT)of the TGA treated wire was found to be 0.16 %/K.By annealing the specimen under the temperature gradient from 823 K to 658 K after 47 % cold working without solution treatment,the B19' martensitic transformation start temperature changed by 61K along the length of sample(150mm).Temperature dependence of transformation elongation(dε/dT)of the TGA treated wire was found to be 0.04 %/K.The large decrease in dε/dT by cold working effect suggested that an introduction of dislocation was more effective than precipitates for lowering dε/dT.
基金the National Research Foundation of Korea(NRF)grant funded by the Korean government(MSIT,Ministry of Science and ICT)(NRF-2021R1A2C3004151)Ministry of Education(NRF-2022R1A6A3A01086019)the KU-KIST School Program.
文摘Stretchable elastomer-based electrodes are considered promising energy storage electrodes for next-generation wearable/flexible electronics requiring various shape designs.However,these elastomeric electrodes suffer from the limited electrical conductivity of current collectors,low charge storage capacities,poor interfacial interactions between elastomers and conductive/active materials,and lack of shape controllability.In this study,we report hierarchically micro/nano-wrinkle-structured elastomeric electrodes with notably high energy storage performance and good mechanical/electrochemical stabilities,simultaneously allowing various form factors.For this study,a swelling/deswelling-involved metal nanoparticle(NP)assembly is first performed on thiol-functionalized polydimethylsiloxane(PDMS)elastomers,generating a micro-wrinkled structure and a conductive seed layer for subsequent electrodeposition.After the assembly of metal NPs,the conformal electrodeposition of Ni and NiCo layered double hydroxides layers with a homogeneous nanostructure on the micro-wrinkled PDMS induces the formation of a micro/nano-wrinkled surface morphology with a large active surface area and high electrical conductivity.Based on this unique approach,the formed elastomeric electrodes show higher areal capacity and superior rate capability than conventional elastomeric electrodes while maintaining their electrical/electrochemical properties under external mechanical deformation.This notable mechanical/electrochemical performance can be further enhanced by using spiral-structured PDMS(stretchability of~500%)and porous-structured PDMS(areal capacity of~280μAh cm^(-2)).
