Adsorption of methane by modified-biochar aiming to improve the gaseous fuels storage/transport capacity: process evaluation and modeling.
Ederson F KlitzkeFelipe KetzerManuelle O P AlmeidaJean F F CalistoJoão H C WancuraClovis A RodriguesJosé Vladimir de OliveiraJacir Dal MagroPublished in: Environmental science and pollution research international (2024)
The CH 4 storage by adsorption on activated carbons for natural gas handling has gained interest due to the appearance of lightweight materials with large surface areas and pore volumes. Consequently, kinetic parameters estimation of the adsorptive process can play a crucial role in understanding and scaling up the system. Concerning its versatility, banana peel (BP) is a biomass with potential for obtaining different products, such as biochar, a solid residue from the biomass' thermal decomposition of difficult disposal, where through an activation process, the material porous features are taken advantage to application as adsorbent of gaseous substances. This research reported data for the CH 4 adsorption kinetic modeling by biochar from BP pyrolysis. The activated biochar textural characterization showed particles with fine mesoporous structure (pore diameter ranging between 29.39 and 55.62 Å). Adsorption kinetic analysis indicated that a modified pseudo-first-order model was the most suitable to represent the experimental data, with equilibrium adsorption of 28 mg g -1 for the samples activated with 20.0% vol wt. -1 of H 3 PO 4 and pyrolysis at 500 °C. The equilibrium constant was consistent with the Freundlich isotherm model, suggesting a physisorption mechanism, and led to a non-ideal, reversible, and not limited to monolayer CH 4 adsorption.
Keyphrases
- aqueous solution
- anaerobic digestion
- sewage sludge
- heavy metals
- municipal solid waste
- room temperature
- molecular dynamics
- electronic health record
- molecular dynamics simulations
- organic matter
- big data
- wastewater treatment
- plant growth
- air pollution
- drinking water
- data analysis
- highly efficient
- carbon dioxide
- tandem mass spectrometry
- solid phase extraction
- tissue engineering