Two-dimensional BeP as a promising thermoelectric material and anode for Na/K-ion batteries

Incredibly effective and flexible energy conversion and storage systems hold great promise for portable self-powered electronic devices. Owing to their large surface area, exceptional atomic structures, superior electrical conductivity and good mechanical flexibility, two-dimensional (2D) materials...

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Veröffentlicht in:	Nanoscale 2024-08, Vol.16 (3), p.14418-14432
Hauptverfasser:	Verma, Nidhi, Chauhan, Poonam, Kumar, Ashok
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container_title	Nanoscale
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creator	Verma, Nidhi Chauhan, Poonam Kumar, Ashok
description	Incredibly effective and flexible energy conversion and storage systems hold great promise for portable self-powered electronic devices. Owing to their large surface area, exceptional atomic structures, superior electrical conductivity and good mechanical flexibility, two-dimensional (2D) materials are recognized as an attractive option for energy conversion and storage application. In this work, we examined the stability, electronic, thermoelectric and electrochemical aspects of a novel 2D Be 2 P 4 monolayer by adopting density functional theory (DFT). The Be 2 P 4 monolayer exhibits a direct semiconductor gap of 0.9 eV (HSE06), large Young's modulus (∼198 GPa), high carrier mobility (∼10 4 cm 2 V −1 s −1 ) and a low excitonic binding energy of 0.11 eV. Our calculated findings suggest that Be 2 P 4 shows a lattice thermal conductivity of 1.02 W m K −1 at 700 K, resulting in moderate thermoelectric performance ( ZT ∼ 0.7), encouraging its use in thermoelectric materials. In addition, a higher adsorption energy of −2.28 eV (−2.52 eV) and less diffusion barrier of 0.22 eV (0.17 eV) for Na(K)-ion batteries promote fast ion transport in the Be 2 P 4 monolayer. This material also shows a high specific capacity and superior energy density of 8460 W h kg −1 (8883 W h kg −1 ) for Na(K)-ion batteries. Thus, our results offer insightful information for investigating potential thermoelectric and flexible anode materials based on the Be 2 P 4 monolayer. Incredibly effective and flexible energy conversion and storage systems hold great promise for portable self-powered electronic devices.
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Owing to their large surface area, exceptional atomic structures, superior electrical conductivity and good mechanical flexibility, two-dimensional (2D) materials are recognized as an attractive option for energy conversion and storage application. In this work, we examined the stability, electronic, thermoelectric and electrochemical aspects of a novel 2D Be 2 P 4 monolayer by adopting density functional theory (DFT). The Be 2 P 4 monolayer exhibits a direct semiconductor gap of 0.9 eV (HSE06), large Young's modulus (∼198 GPa), high carrier mobility (∼10 4 cm 2 V −1 s −1 ) and a low excitonic binding energy of 0.11 eV. Our calculated findings suggest that Be 2 P 4 shows a lattice thermal conductivity of 1.02 W m K −1 at 700 K, resulting in moderate thermoelectric performance ( ZT ∼ 0.7), encouraging its use in thermoelectric materials. In addition, a higher adsorption energy of −2.28 eV (−2.52 eV) and less diffusion barrier of 0.22 eV (0.17 eV) for Na(K)-ion batteries promote fast ion transport in the Be 2 P 4 monolayer. This material also shows a high specific capacity and superior energy density of 8460 W h kg −1 (8883 W h kg −1 ) for Na(K)-ion batteries. Thus, our results offer insightful information for investigating potential thermoelectric and flexible anode materials based on the Be 2 P 4 monolayer. 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Owing to their large surface area, exceptional atomic structures, superior electrical conductivity and good mechanical flexibility, two-dimensional (2D) materials are recognized as an attractive option for energy conversion and storage application. In this work, we examined the stability, electronic, thermoelectric and electrochemical aspects of a novel 2D Be 2 P 4 monolayer by adopting density functional theory (DFT). The Be 2 P 4 monolayer exhibits a direct semiconductor gap of 0.9 eV (HSE06), large Young's modulus (∼198 GPa), high carrier mobility (∼10 4 cm 2 V −1 s −1 ) and a low excitonic binding energy of 0.11 eV. Our calculated findings suggest that Be 2 P 4 shows a lattice thermal conductivity of 1.02 W m K −1 at 700 K, resulting in moderate thermoelectric performance ( ZT ∼ 0.7), encouraging its use in thermoelectric materials. In addition, a higher adsorption energy of −2.28 eV (−2.52 eV) and less diffusion barrier of 0.22 eV (0.17 eV) for Na(K)-ion batteries promote fast ion transport in the Be 2 P 4 monolayer. This material also shows a high specific capacity and superior energy density of 8460 W h kg −1 (8883 W h kg −1 ) for Na(K)-ion batteries. Thus, our results offer insightful information for investigating potential thermoelectric and flexible anode materials based on the Be 2 P 4 monolayer. 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Owing to their large surface area, exceptional atomic structures, superior electrical conductivity and good mechanical flexibility, two-dimensional (2D) materials are recognized as an attractive option for energy conversion and storage application. In this work, we examined the stability, electronic, thermoelectric and electrochemical aspects of a novel 2D Be 2 P 4 monolayer by adopting density functional theory (DFT). The Be 2 P 4 monolayer exhibits a direct semiconductor gap of 0.9 eV (HSE06), large Young's modulus (∼198 GPa), high carrier mobility (∼10 4 cm 2 V −1 s −1 ) and a low excitonic binding energy of 0.11 eV. Our calculated findings suggest that Be 2 P 4 shows a lattice thermal conductivity of 1.02 W m K −1 at 700 K, resulting in moderate thermoelectric performance ( ZT ∼ 0.7), encouraging its use in thermoelectric materials. In addition, a higher adsorption energy of −2.28 eV (−2.52 eV) and less diffusion barrier of 0.22 eV (0.17 eV) for Na(K)-ion batteries promote fast ion transport in the Be 2 P 4 monolayer. This material also shows a high specific capacity and superior energy density of 8460 W h kg −1 (8883 W h kg −1 ) for Na(K)-ion batteries. Thus, our results offer insightful information for investigating potential thermoelectric and flexible anode materials based on the Be 2 P 4 monolayer. Incredibly effective and flexible energy conversion and storage systems hold great promise for portable self-powered electronic devices.</abstract><doi>10.1039/d4nr01132e</doi><tpages>15</tpages></addata></record>
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title	Two-dimensional BeP as a promising thermoelectric material and anode for Na/K-ion batteries
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