November 22, 2024
Arash Khosravi

Arash Khosravi

Academic Rank: Assistant professor
Address: Faculty of Petroleum, Gas and Petrochemical Engineering, Persian Gulf University, Bushehr 75169, Iran
Degree: Ph.D in Chemical Engineering
Phone: 077-31222640
Faculty: Faculty of Petroleum, Gas and Petrochemical Engineering

Research

Title The Capacity of Alkali-Activated Industrial Wastes in Novel Sustainable Ceramic Membranes
Type Article
Keywords
Alkali-activated ceramic membranes, Alkali-activated materials, Aluminosilicate wastes, Geopolymers, Toxic immobilization
Journal ChemBioEng Reviews
DOI doi.org/10.1002/cben.202300041
Researchers sina shiva (First researcher) , Arash Khosravi (Second researcher) , farzaneh mohammadi (Third researcher) , Mohsen Abbasi (Fourth researcher) , Mika Silanpaa (Fifth researcher)

Abstract

Novel ceramic membranes present unquestionable potential in wastewater treatment among the emerging technologies, while a few challenges such as cost, energy consumption, durability, and resistance in harsh mediums still limit their commercialization. Here, we review the capability of available industrial aluminosilicate waste materials in the fabrication of novel ceramic membranes using green and economical alkali-activation synthesis method. The different sources of alkali-activated aluminosilicate wastes including ashes, mining wastes, glass and ceramic wastes, slags, construction wastes, industrial byproducts, and agricultural wastes are introduced and the chemistry of geopolymers is reviewed. In this review, the major points are the following. 1) The alkali-activated structures present reasonable chemical, frost, carbonation, and mechanical resistance as well as the ability to immobilize the toxic materials. 2) The synthesis aspects of porous and nonporous alkali-activated ceramic membranes are explored by characterization methods. Furthermore, the durability analysis in harsh environments reveals that alkali-activated ceramic membranes possess high resistance against acidic, alkaline, and other antifouling chemical washing methods. In summary, it is demonstrated that the studied membranes have an undeniable capability in the separation of organic solvents in the pervaporation process as well as toxic material removal from water with high ion-exchange capacity.