How Reproducible Are Surface Areas Calculated from the BET Equation?

Abstract: Porosity and surface area analysis play a prominent role in modern materials science, where their determination spans the fields of natural sciences, engineering, geology and medical research. At the heart of this sits the Brunauer-Emmett-Teller (BET) theory,[1] which has been a remarkably successful contribution to the field of materials science. The BET method was developed in the 1930s for open surfaces but is now the most widely used metric for the estimation of surface areas of micro- and mesoporous mater… Show more

“…Biofuel cells that exploit enzymes or microbes as biocatalysts to generate electrical energy offer an eco-friendly energy solution for powering electronic devices [28,29] . Enzymatic biofuel cells are promising for low-power applications such as portable medical devices [30] while microbial biofuel [2] 2450 m 2 g −1 [27] Tris, Phos [15] MAF-7 NU-1006 1730 m 2 g −1 [68] 1440 m 2 g −1 [40] Tris, HEPES [19] UiO-66 ZIF-8 1710 m 2 g −1 [27] 1150 m 2 g −1 [27] Tris [15] MIL-100 (Cr) MIL-53 (Al) 1140 m 2 g −1 [25] 2200 m 2 g −1 [27] Phos [15] HEPES [24] BTP [26] Cr Pore size maximum 3.4 nm [23] 1.1 nm [40] 1.16 nm [17] 2.9 nm [15] Pore size maximum ca. 1.36 nm [2] 6.2 nm [69] 1.2 nm [20] ca.…”

“…Such MOFs may be considered generally appropriate for bioelectrochemical applications although stability is best evaluated on a case-by-case basis. MOF stability should be evaluated based on powder x-ray diffraction (PXRD) and electron microscopy data as well as, where possible, ligands/metal ion leaching and porosity and gas adsorption experiments [27] .…”

Metal Organic Frameworks for Bioelectrochemical Applications

“…Biofuel cells that exploit enzymes or microbes as biocatalysts to generate electrical energy offer an eco-friendly energy solution for powering electronic devices [28,29] . Enzymatic biofuel cells are promising for low-power applications such as portable medical devices [30] while microbial biofuel [2] 2450 m 2 g −1 [27] Tris, Phos [15] MAF-7 NU-1006 1730 m 2 g −1 [68] 1440 m 2 g −1 [40] Tris, HEPES [19] UiO-66 ZIF-8 1710 m 2 g −1 [27] 1150 m 2 g −1 [27] Tris [15] MIL-100 (Cr) MIL-53 (Al) 1140 m 2 g −1 [25] 2200 m 2 g −1 [27] Phos [15] HEPES [24] BTP [26] Cr Pore size maximum 3.4 nm [23] 1.1 nm [40] 1.16 nm [17] 2.9 nm [15] Pore size maximum ca. 1.36 nm [2] 6.2 nm [69] 1.2 nm [20] ca.…”

“…Such MOFs may be considered generally appropriate for bioelectrochemical applications although stability is best evaluated on a case-by-case basis. MOF stability should be evaluated based on powder x-ray diffraction (PXRD) and electron microscopy data as well as, where possible, ligands/metal ion leaching and porosity and gas adsorption experiments [27] .…”

Metal Organic Frameworks for Bioelectrochemical Applications