M. Leon Hyatt scite author profile

energy supply are required. Hence, an efficient local energy storage/production system plays a vital role for such applications. [1] The supercapacitor is one of the efficient energy storage systems which can store energy via electric double layer and faradic reactions. [2,3] The electric double layer capacitor (EDLC) stores the charge over the active surface area of the material and shows very durable performance over long period. [3,4] Thus, creating carbon with a high surface area could be one of the ways to improve the performance of EDLC-based supercapacitor devices. There are several publications documenting the utilization of waste-derived carbon source such as seeds, seed shells, leaves, bagasse, waste paper, and tyre. [5][6][7][8][9][10][11][12] Waste tea is an additional exciting source for carbon. [13] Most of the time, an activation step is required to achieve the high surface area to enhance the performance of the carbon. Activation of waste-derived carbon can be done using various methods including chemical, steam, and CO 2 -based activation. [14][15][16][17] For example, steam activated carbon from fir wood showed an activated surface area of 1131 m 2 g −1 while, CO 2 activated empty fruit bunches of palm showed a surface area of 1704 m 2 g −1 . [12,13] KOH activation is the most popular way to create high surface area and Used tea leaves are utilized for preparation of carbon with high surface area and electrochemical properties. Surface area and pore size of tea leaves derived carbon are controlled by varying the amount of KOH as activating agent. The maximum surface area of 2532 m 2 g −1 is observed, which is much higher than unactivated tea leaves (3.6 m 2 g −1 ). It is observed that the size of the electrolyte ions has a profound effect on the energy storage capacity. The maximum specific capacitance of 292 F g −1 is observed in 3 m KOH electrolyte with outstanding cyclic stability, while the lowest specific capacitance of 246 F g −1 is obtained in 3 m LiOH electrolyte at 2 mV s −1 . The tea leaves derived electrode shows almost 100% capacitance retention up to 5000 cycles of study. The symmetrical supercapacitor device shows a maximum specific capacitance of 0.64 F cm −2 at 1 mA cm −2 and about 95% of specific capacitance is retained after increasing current density to 12 mA cm −2 , confirming the high rate stability of the device. An improvement over 35% in the charge storage capacity is seen when increasing device temperature from 10 to 80 °C. The study suggests that used tea leaves can be used for the fabrication of environment friendly high performance supercapacitor devices at a low cost.

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Electrochemical investigation of uncapped AgBiS₂ (schapbachite) synthesized using in situ melts of xanthate precursors

Khan

Aamir

Sohail³

et al. 2019

Dalton Trans.

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Nitrogen-doped flexible carbon cloth for durable metal free electrocatalyst for overall water splitting

Zhang

Bhoyate

Hyatt³

et al. 2018

Surface and Coatings Technology

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Subcritical Flow Over Highway Embankments

Skogerboe

Hyatt

1967

J. Hydr. Div.

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Rectangular Cutthroat Flow Measurement Flumes

Skogerboe

Hyatt

1967

J. Irrig. and Drain. Div.

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M. Leon Hyatt

Eco‐Friendly and High Performance Supercapacitors for Elevated Temperature Applications Using Recycled Tea Leaves

Electrochemical investigation of uncapped AgBiS₂ (schapbachite) synthesized using in situ melts of xanthate precursors

Nitrogen-doped flexible carbon cloth for durable metal free electrocatalyst for overall water splitting

Subcritical Flow Over Highway Embankments

Rectangular Cutthroat Flow Measurement Flumes

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Resources

About

M. Leon Hyatt

Eco‐Friendly and High Performance Supercapacitors for Elevated Temperature Applications Using Recycled Tea Leaves

Electrochemical investigation of uncapped AgBiS2 (schapbachite) synthesized using in situ melts of xanthate precursors

Nitrogen-doped flexible carbon cloth for durable metal free electrocatalyst for overall water splitting

Subcritical Flow Over Highway Embankments

Rectangular Cutthroat Flow Measurement Flumes

Contact Info

Product

Resources

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Electrochemical investigation of uncapped AgBiS₂ (schapbachite) synthesized using in situ melts of xanthate precursors