Chemistry, Physics and Technology of Surface

ISSN 2518-1238 (Online), ISSN 2079-1704 (Print)

For various adsorbents, especially nanoporous, there is an applicability problem of the Brunauer-Emmett-Teller (BET) method using nitrogen as a probe adsorbate. Therefore, the nitrogen adsorption (a(p/p₀)) isotherms in several pressure ranges of the BET method at p/p₀ = 0.05–0.3, 0.06–0.22, and narrower are analyzed for a large set (about 200 samples) of essentially different adsorbents such as fumed oxides (individual, binary and ternary, initial and modified), porous silicas, activated carbons and porous polymers. Graphitized carbon black ENVI–Carb composed of nonporous nanoparticles aggregated into microparticles is used as a standard adsorbent characterized by the standard area occupied by nitrogen molecule σ_m(N₂) = 0.162 nm². For initial nanooxides composed of nonporous nanoparticles, the standard value of σ_m = 0.162 nm² results in the overestimation of the S_BET values by ca. 10 % because of non-parallel-to-surface orientation of slightly polarized N₂ molecules interacting with polar surface functionalities (e.g., various hydroxyls). For nanooxides modified by low- and high-molecular (linear, 2D and 3D polymers and proteins) compounds, the overestimation of S_BET at σ_m = 0.162 nm² could reach 30 %, as well as for some activated carbons. For adsorbents possessing nanopores (at half-width x or radius R < 1 nm) and narrow mesopores (1 nm < R < 3 nm), an overlap of monolayer and multilayer sorption (giving apparent underestimation of S_BET at σ_m = 0.162 nm²) and non-parallel-to-surface orientation of the N₂ molecules (causing σ_m lower than 0.162 nm²) could lead to various location of the normalized nitrogen adsorption isotherms (in the BET range) with respect to that for ENVI–Carb. It could be characterized by positive or negative values of the BET constant c_BET. Two main criteria showing the inapplicability or applicability of the BET method (with nitrogen as a probe) related to the c_BET values and a course of reduced adsorption a´(1- p/p₀) vs. p/p₀ in the BET range could not be in agreement for adsorbents, which are not pure nanoporous, but they are in agreement for pure nanoporous or meso/macroporous adsorbents

nitrogen adsorption isotherms; Brunauer-Emmett-Teller method restrictions; nanooxides; porous silicas; carbons; porous polymers

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