Response surface methodology as an efficient tool for optimizing the Fischer–Tropsch process over a novel Fe–Mn nano catalyst

Abstract: A novel Fe–Mn–resol/SiO2 nano-catalyst with improved surface area and porosity was prepared and used in the Fischer–Tropsch process.

“…Also for the catalysis of gas reactions, for example, degradation of ozone, this material showed interesting properties . Furthermore, Fe/Mn systems have proven activity for the catalysis of the Fischer–Tropsch process. , …”

“…164 Furthermore, Fe/Mn systems have proven activity for the catalysis of the Fischer−Tropsch process. 165,166 Exploitation of Steel in Electrocatalysis for Full Water Splitting. Three recently published reports deal with the exploitation of surface-modified steels for usage as both OER and HER electrodes.…”

Steel: The Resurrection of a Forgotten Water-Splitting Catalyst

“…Also for the catalysis of gas reactions, for example, degradation of ozone, this material showed interesting properties . Furthermore, Fe/Mn systems have proven activity for the catalysis of the Fischer–Tropsch process. , …”

“…164 Furthermore, Fe/Mn systems have proven activity for the catalysis of the Fischer−Tropsch process. 165,166 Exploitation of Steel in Electrocatalysis for Full Water Splitting. Three recently published reports deal with the exploitation of surface-modified steels for usage as both OER and HER electrodes.…”

Steel: The Resurrection of a Forgotten Water-Splitting Catalyst

Effect of preparation method on physicochemical properties of a novel Co–Fe nano catalyst

Modeling and optimization of Fischer-Tropsch synthesis over Co-Mn-Ce/SiO 2 catalyst using hybrid RSM/LHHW approaches