Yong Hyup Kim scite author profile

The lithium-oxygen battery has the potential to deliver extremely high energy densities; however, the practical use of Li-O2 batteries has been restricted because of their poor cyclability and low energy efficiency. In this work, we report a novel Li-O2 battery with high reversibility and good energy efficiency using a soluble catalyst combined with a hierarchical nanoporous air electrode. Through the porous three-dimensional network of the air electrode, not only lithium ions and oxygen but also soluble catalysts can be rapidly transported, enabling ultra-efficient electrode reactions and significantly enhanced catalytic activity. The novel Li-O2 battery, combining an ideal air electrode and a soluble catalyst, can deliver a high reversible capacity (1000 mAh g(-1) ) up to 900 cycles with reduced polarization (about 0.25 V).

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High Power Density Electrochemical Thermocells for Inexpensively Harvesting Low‐Grade Thermal Energy

Zhang

et al. 2017

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Continuously operating thermo-electrochemical cells (thermocells) are of interest for harvesting low-grade waste thermal energy because of their potentially low cost compared with conventional thermoelectrics. Pt-free thermocells devised here provide an output power of 12 W m for an interelectrode temperature difference (ΔT) of 81 °C, which is sixfold higher power than previously reported for planar thermocells operating at ambient pressure.

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Electrical Power From Nanotube and Graphene Electrochemical Thermal Energy Harvesters

Kang

Fang

Kozlov

et al. 2011

Adv Funct Materials

200

193

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Nanocarbon‐based thermocells involving aqueous potassium ferro/ferricyanide electrolyte are investigated as an alternative to conventional thermoelectrics for thermal energy harvesting. The dependencies of power output on thermocell parameters, such as cell orientation, electrode size, electrode spacing, electrolyte concentration and temperature, are examined to provide practical design elements and principles. Observation of thermocell discharge behavior provides an understanding of the three primary internal resistances (i.e., activation, ohmic and mass transport overpotentials). The power output from nanocarbon thermocells is found to be mainly limited by the ohmic resistance of the electrolyte and restrictions on mass transport in the porous nanocarbon electrode due to pore tortuosity. Based on these fundamental studies, a comparison of power generation is conducted using various nanocarbon electrodes, including purified single‐walled and multi‐walled carbon nanotubes (P‐SWNTs and P‐MWNTs, respectively), unpurified SWNTs, reduced graphene oxide (RGO) and P‐SWNT/RGO composite. The P‐SWNT thermocell has the highest specific power generation per electrode weight (6.8 W/kg for a temperature difference of 20 °C), which is comparable to that for the P‐MWNT electrode. The RGO thermocell electrode provides a substantially lower specific power generation (3.9 W/kg).

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Enhanced Power and Rechargeability of a Li−O₂ Battery Based on a Hierarchical‐Fibril CNT Electrode

et al. 2012

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High-efficiency electrochemical thermal energy harvester using carbon nanotube aerogel sheet electrodes

et al. 2016

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Conversion of low-grade waste heat into electricity is an important energy harvesting strategy. However, abundant heat from these low-grade thermal streams cannot be harvested readily because of the absence of efficient, inexpensive devices that can convert the waste heat into electricity. Here we fabricate carbon nanotube aerogel-based thermo-electrochemical cells, which are potentially low-cost and relatively high-efficiency materials for this application. When normalized to the cell cross-sectional area, a maximum power output of 6.6 W m−2 is obtained for a 51 °C inter-electrode temperature difference, with a Carnot-relative efficiency of 3.95%. The importance of electrode purity, engineered porosity and catalytic surfaces in enhancing the thermocell performance is demonstrated.

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Yong Hyup Kim

Superior Rechargeability and Efficiency of Lithium–Oxygen Batteries: Hierarchical Air Electrode Architecture Combined with a Soluble Catalyst

High Power Density Electrochemical Thermocells for Inexpensively Harvesting Low‐Grade Thermal Energy

Electrical Power From Nanotube and Graphene Electrochemical Thermal Energy Harvesters

Enhanced Power and Rechargeability of a Li−O₂ Battery Based on a Hierarchical‐Fibril CNT Electrode

High-efficiency electrochemical thermal energy harvester using carbon nanotube aerogel sheet electrodes

Contact Info

Product

Resources

About

Yong Hyup Kim

Superior Rechargeability and Efficiency of Lithium–Oxygen Batteries: Hierarchical Air Electrode Architecture Combined with a Soluble Catalyst

High Power Density Electrochemical Thermocells for Inexpensively Harvesting Low‐Grade Thermal Energy

Electrical Power From Nanotube and Graphene Electrochemical Thermal Energy Harvesters

Enhanced Power and Rechargeability of a Li−O2 Battery Based on a Hierarchical‐Fibril CNT Electrode

High-efficiency electrochemical thermal energy harvester using carbon nanotube aerogel sheet electrodes

Contact Info

Product

Resources

About

Enhanced Power and Rechargeability of a Li−O₂ Battery Based on a Hierarchical‐Fibril CNT Electrode