Thermo, Vol. 5, Pages 34: From Thermal Conversion to Cathode Performance: Acid-Activated Walnut Shell Biochar in Li–S Batteries and Its Impact on Air Quality

Thermo doi: 10.3390/thermo5030034

Authors:
Fabricio Aguirre
Guillermina Luque
Gabriel Imwinkelried
Fernando Cometto
Clara Saux
Mariano Teruel
María Belén Blanco

The thermal processing of walnut shells was investigated through pyrolysis within the range of 100–650 °C, highlighting the influence of thermal engineering parameters on biomass conversion. The resulting biochar was subjected to chemical activation with phosphoric acid, and its physicochemical properties were evaluated to determine how thermal processing enhances its performance as a cathode material for lithium–sulfur (Li–S) batteries. This approach underscores the role of thermal engineering in bridging biomass valorization with energy storage technologies. In parallel, the gaseous fraction generated during walnut shell fast pyrolysis was collected, and for the first time, volatile organic compounds (VOCs) under atmospheric conditions were identified using solid-phase microextraction (SPME) coupled with gas chromatography–mass spectrometry (GC–MS). The composition of the VOCs was characterized, quantifying aromatic compounds, hydrocarbons, furans, and oxygenated species. This study further linked the thermal decomposition pathways of these compounds to their atmospheric implications by estimating tropospheric lifetimes and evaluating their potential contributions to air quality degradation at the local, regional, and global scales.

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Fabricio Aguirre www.mdpi.com