Hayoung Hwang scite author profile

Understanding the chemical-thermal-electrical energy conversion in micro/nanostructures is crucial for making breakthroughs in new fields related to energy research, as well as in improving the existing energy technologies. Thermopower wave utilizing this chemical-thermal-electrical energy conversion in hybrid structures of nanomaterials and combustible fuel has recently attracted much attention as an enhanced combustion wave with the concomitant voltage generation. In this study, we have explored thermopower waves in the hybrid composite of the chemical fuel and surface-oxidized copper submicroparticles (SCuMPs) films during combustion. Here, we have demonstrated that the manipulations of micro/nanostructures in SCuMPs films by annealing are capable of converting the energy released during chemical combustion to a significantly large amount of thermal and electrical energy (average combustion velocity 32.6 mm s À1 , output voltages up to 6.2 V; average 2.02 V) in comparison with the as-prepared SCuMPs films (19.2 mm s À1 , up to 1.0 V; average 0.75 V) from thermopower waves. Owing to the inter grain boundary fusions and inner/surface nanowire-bonding by annealing, the chemical combustion rate, the corresponding thermal transport, and the electrical energy generation were greatly enhanced in the micro/nanostructured films. This work can contribute to the enhanced combustion wave and voltage generation in thermopower waves as well as further understanding of the fundamental phenomena in chemical-thermal-electrical energy conversions using micro/nanostructured materials.

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Advanced Thermopower Wave in Novel ZnO Nanostructures/Fuel Composite

Lee

Hwang

Choi

2014

ACS Appl. Mater. Interfaces

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Thermopower wave is a new concept of energy conversion from chemical to thermal to electrical energy, produced from the chemical reaction in well-designed hybrid structures between nanomaterials and combustible fuels. The enhancement and optimization of energy generation is essential to make it useful for future applications. In this study, we demonstrate that simple solution-based synthesized zinc oxide (ZnO) nanostructures, such as nanorods and nanoparticles are capable of generating high output voltage from thermopower waves. In particular, an astonishing improvement in the output voltage (up to 3 V; average 2.3 V) was achieved in a ZnO nanorods-based composite film with a solid fuel (collodion, 5% nitrocellulose), which generated an exothermic chemical reaction. Detailed analyses of thermopower waves in ZnO nanorods- and cube-like nanoparticles-based hybrid composites have been reported in which nanostructures, output voltage profile, wave propagation velocities, and surface temperature have been characterized. The average combustion velocities for a ZnO nanorods/fuel and a ZnO cube-like nanoparticles/fuel composites were 40.3 and 30.0 mm/s, while the average output voltages for these composites were 2.3 and 1.73 V. The high output voltage was attributed to the amplified temperature in intermixed composite of ZnO nanostructures and fuel due to the confined diffusive heat transfer in nanostructures. Moreover, the extended interfacial areas between ZnO nanorods and fuel induced large amplification in the dynamic change of the chemical potential, and it resulted in the enhanced output voltage. The differences of reaction velocity and the output voltage between ZnO nanorods- and ZnO cube-like nanoparticles-based composites were attributed to variations in electron mobility and grain boundary, as well as thermal conductivities of ZnO nanorods and particles. Understanding this astonishing increase and the variation of the output voltage and reaction velocity, precise ZnO nanostructures, will help in formulating specific strategies for obtaining enhanced energy generation from thermopower waves.

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One-step transformation of MnO₂ into MnO_2−x@carbon nanostructures for high-performance supercapacitors using structure-guided combustion waves

Shin

Hwang

et al. 2017

J. Mater. Chem. A

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Flexible-detachable dual-output sensors of fluid temperature and dynamics based on structural design of thermoelectric materials

et al. 2018

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Effects of chemical fuel composition on energy generation from thermopower waves

et al. 2014

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Thermopower waves, which occur during combustion within hybrid structures formed from nanomaterials and chemical fuels, result in a self-propagating thermal reaction and concomitantly generate electrical energy from the acceleration of charge carriers along the nanostructures. The hybrid structures for thermopower waves are composed of two primary components: the core thermoelectric material and the combustible fuel. So far, most studies have focused on investigating various nanomaterials for improving energy generation. Herein, we report that the composition of the chemical fuel used has a significant effect on the power generated by thermopower waves. Hybrid nanostructures consisting of mixtures of picric acid and picramide with sodium azide were synthesized and used to generate thermopower waves. A maximum voltage of ∼2 V and an average peak specific power as high as 15 kW kg(-1) were obtained using the picric acid/sodium azide/multiwalled carbon nanotubes (MWCNTs) array composite. The average reaction velocity and the output voltage in the case of the picric acid/sodium azide were 25 cm s(-1) and 157 mV, while they were 2 cm s(-1) and 3 mV, in the case of the picramide/sodium azide. These marked differences are attributable to the chemical and structural differences of the mixtures. Mixing picric acid and sodium azide in deionized water resulted in the formation of 2,4,6-trinitro sodium phenoxide and hydrogen azide (H-N3), owing to the exchange of H(+) and Na(+) ions, as well as the formation of fiber-like structures, because of benzene π stacking. The negative enthalpy of formation of the new compounds and the fiber-like structures accelerate the reaction and increase the output voltage. Elucidating the effects of the composition of the chemical fuel used in the hybrid nanostructures will allow for the control of the combustion process and help optimize the energy generated from thermopower waves, furthering the development of thermopower waves as an energy source.

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Hayoung Hwang

Enhanced thermopower wave via nanowire bonding and grain boundary fusion in combustion of fuel/CuO–Cu₂O–Cu hybrid composites

Advanced Thermopower Wave in Novel ZnO Nanostructures/Fuel Composite

One-step transformation of MnO₂ into MnO_2−x@carbon nanostructures for high-performance supercapacitors using structure-guided combustion waves

Flexible-detachable dual-output sensors of fluid temperature and dynamics based on structural design of thermoelectric materials

Effects of chemical fuel composition on energy generation from thermopower waves

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Hayoung Hwang

Enhanced thermopower wave via nanowire bonding and grain boundary fusion in combustion of fuel/CuO–Cu2O–Cu hybrid composites

Advanced Thermopower Wave in Novel ZnO Nanostructures/Fuel Composite

One-step transformation of MnO2 into MnO2−x@carbon nanostructures for high-performance supercapacitors using structure-guided combustion waves

Flexible-detachable dual-output sensors of fluid temperature and dynamics based on structural design of thermoelectric materials

Effects of chemical fuel composition on energy generation from thermopower waves

Contact Info

Product

Resources

About

Enhanced thermopower wave via nanowire bonding and grain boundary fusion in combustion of fuel/CuO–Cu₂O–Cu hybrid composites

One-step transformation of MnO₂ into MnO_2−x@carbon nanostructures for high-performance supercapacitors using structure-guided combustion waves