Marine shrimp/tin waste as a negative electrode for rechargeable sodium-ion batteries

This work aims to valorize the shrimp wastes as a template for obtaining nanoparticulate tin battery electrodes. Using shrimp waste skins is possible to get a network material made of nanominerals (NMN) with elements such as Ca, Mg, Na, and Al and containing a rich source of nitrogen. Three differen...

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Veröffentlicht in:	Journal of cleaner production 2022-07, Vol.359, p.131994, Article 131994
Hauptverfasser:	Rubio, Saúl, Odoom-Wubah, Tareque, Li, Qun, Tirado, José L., Lavela, Pedro, Huang, Jiale, Ortiz, Gregorio F.
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Sprache:	eng
Schlagworte:	ambient temperature batteries Diglyme electrochemistry electrodes energy density Hard template Marine shrimp waste Na-ion batteries Nanominerals nitrogen particle size shrimp spectroscopy tin Tin nanoparticles
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creator	Rubio, Saúl Odoom-Wubah, Tareque Li, Qun Tirado, José L. Lavela, Pedro Huang, Jiale Ortiz, Gregorio F.
description	This work aims to valorize the shrimp wastes as a template for obtaining nanoparticulate tin battery electrodes. Using shrimp waste skins is possible to get a network material made of nanominerals (NMN) with elements such as Ca, Mg, Na, and Al and containing a rich source of nitrogen. Three different electrode materials prepared under different conditions validated this study. Shrimp wastes (SW), SW-tin prepared at room temperature (ST-RT) and SW-tin prepared by carbothermal reduction (ST-CT) are studied. 119Sn Mössbauer spectroscopy determined the atomic fraction is 59.5 and 40.5% of SnO2 and β-Sn co-existing in the ST-CT sample. SEM and TEM micrographs confirmed a particle size of 2–5 nm of tin-based materials homogeneously distributed on the NMN matrix. Electrochemical investigation in Na-half cells demonstrated superior electrochemical performance of ST-CT with 162 mA h g−1 reversible capacity which can be retained at 60% over 200 cycles under different rates (C/10 to 2 C). The SW and ST-RT displayed the worse reversible capacities. Eventually, a Na-ion full cell is assembled versus Na3V2(PO4)3 showing good properties in terms of energy density. [Display omitted] •We use shrimp/tin waste (STW) material, which has never been tested for energy storage.•Advanced storage properties in Na-ion full cells are proposed for first time using natural sources.•Na-half cells shows a 162 mA h g−1 of reversible capacity retained 60% over 200 cycles.•Combined with NVP cathode, it exhibits average cell potential of 2.5 V reaching 310 W h kg−1.
doi_str_mv	10.1016/j.jclepro.2022.131994
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Using shrimp waste skins is possible to get a network material made of nanominerals (NMN) with elements such as Ca, Mg, Na, and Al and containing a rich source of nitrogen. Three different electrode materials prepared under different conditions validated this study. Shrimp wastes (SW), SW-tin prepared at room temperature (ST-RT) and SW-tin prepared by carbothermal reduction (ST-CT) are studied. 119Sn Mössbauer spectroscopy determined the atomic fraction is 59.5 and 40.5% of SnO2 and β-Sn co-existing in the ST-CT sample. SEM and TEM micrographs confirmed a particle size of 2–5 nm of tin-based materials homogeneously distributed on the NMN matrix. Electrochemical investigation in Na-half cells demonstrated superior electrochemical performance of ST-CT with 162 mA h g−1 reversible capacity which can be retained at 60% over 200 cycles under different rates (C/10 to 2 C). The SW and ST-RT displayed the worse reversible capacities. Eventually, a Na-ion full cell is assembled versus Na3V2(PO4)3 showing good properties in terms of energy density. 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Using shrimp waste skins is possible to get a network material made of nanominerals (NMN) with elements such as Ca, Mg, Na, and Al and containing a rich source of nitrogen. Three different electrode materials prepared under different conditions validated this study. Shrimp wastes (SW), SW-tin prepared at room temperature (ST-RT) and SW-tin prepared by carbothermal reduction (ST-CT) are studied. 119Sn Mössbauer spectroscopy determined the atomic fraction is 59.5 and 40.5% of SnO2 and β-Sn co-existing in the ST-CT sample. SEM and TEM micrographs confirmed a particle size of 2–5 nm of tin-based materials homogeneously distributed on the NMN matrix. Electrochemical investigation in Na-half cells demonstrated superior electrochemical performance of ST-CT with 162 mA h g−1 reversible capacity which can be retained at 60% over 200 cycles under different rates (C/10 to 2 C). The SW and ST-RT displayed the worse reversible capacities. 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subjects	ambient temperature batteries Diglyme electrochemistry electrodes energy density Hard template Marine shrimp waste Na-ion batteries Nanominerals nitrogen particle size shrimp spectroscopy tin Tin nanoparticles
title	Marine shrimp/tin waste as a negative electrode for rechargeable sodium-ion batteries
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