Life Cycle Analysis and Operating Cost Assessment of a Carbon Negative Catalytic Pyrolysis Technique Using a Spent Aluminum Hydroxide Nanoparticle Adsorbent-Derived Catalyst: Insights into Coproduct Utilization and Sustainability

Abstract: The current research is intended toward the life cycle analysis (LCA) and operating cost assessment of catalytic and noncatalytic pyrolysis. The study assessed the impact of waste material-based catalysts (spent aluminum hydroxide nanoparticle (AHNP) adsorbent-derived catalysts) on the process’ overall environmental load and operating cost. Incorporating the utilization of process coproducts through recycling both noncondensable gases (NCGs) and biochar in the pyrolysis process, as well as exporting biochar as… Show more

“…, into the environment. 292–294 The highest abundance of pollution belongs to CO 2 , which results in greenhouse gas emission. Vienescu et al 295 conducted LCA analysis of corn stover pyrolysis.…”

A review on thermochemical based biorefinery catalyst development progress

“…, into the environment. 292–294 The highest abundance of pollution belongs to CO 2 , which results in greenhouse gas emission. Vienescu et al 295 conducted LCA analysis of corn stover pyrolysis.…”

A review on thermochemical based biorefinery catalyst development progress

Life cycle analysis and economic evaluation of adsorptive removal of arsenic from groundwater using GAC and GAC-Fe adsorbents

A comprehensive review of advances in nanoparticle catalysts for biodiesel production