How Reproducible Are Surface Areas Calculated from the BET Equation?

Osterrieth, Johannes; Rampersad, James; Madden, David G.; Rampal, Nakul; Skorić, Luka; Connolly, Bethany M.; Allendorf, Mark D.; Stavila, Vitalie; SNIDER, JONATHAN; Ameloot, Rob; Marreiros, João; Ania, Conchi O.; Azevedo, Diana Cristina Silva de; Vilarrasa-García, Enrique; Santos, Bianca F; Bu, Xian‐He; Zang, Xe; Bunzen, Hana; Champness, Neil R.; Griffin, Sarah L.; Chen, Banglin; Lin, Rui‐Biao; Coasne, Benoît; Cohen, Seth M.; Moreton, Jessica C.; Colón, Yamil J.; Chen, Linjiang; Clowes, Rob; Coudert, François‐Xavier; Cui, Yong; Hou, Bang; D’Alessandro, Deanna; Doheny, Patrick W.; Dincă, Mircea; Sun, Chenyue; Doonan, Christian J.; Huxley, Michael; Evans, Jack D.; Falcaro, Paolo; Riccò, Raffaele; Farha, Omar K.; Idrees, Karam B.; İslamoğlu, Timur; Feng, Pingyun; Yang, Hexiong; Forgan, Ross S.; Bara, Dominic; Furukawa, Shuhei; Sánchez, Elisabeth; Gascón, Jorge; Telalović, Selvedin; Ghosha, Sujit K.; MUKHERJEE, SOUMYA; Hill, M. E.; Sadiq, Muhammad Munir; Horcajada, Patricia; Salcedo‐Abraira, Pablo; Kaneko, Katsumi; Kukobat, Radovan; Kenvin, Jeffrey; Keskın, Seda; Kitagawa, Susumu; Otake, Ken‐ichi; Lively, Ryan P.; DeWitt, Stephen J. A.; Llewellyn, Philip; Lotsch, Bettina V.; Emmerling, Sebastian T.; Pütz, Alexander; Martí‐Gastaldo, Carlos; Muñoz, Natalia; García‐Martínez, Javier; Linares, Noemi; Maspoch, Daniel; Suárez, José Antonio; Moghadam, Peyman; Oktavian, Rama; Morris, Russell E.; Wheatley, Paul; Navarro, Jorge; Petit, Camille; Danaci, David; Rosseinsky, Matthew J.; Katsoulidis, Alexandros; Schröder, Martin; Han, Xue; Yang, Sihai; Serre, Christian; Mouchaham, Georges; Sholl, David S.; Thyagarajan, Raghuram; Siderius, Daniel W.; Snurr, Randall Q.; Goncalves, Rebecca B.; Telfer, Shane G.; Lee, Seok J.; Ting, Valeska P.; Rowlandson, Jemma; Uemura, Tetsuya; Iiyuka, Tomoya; Veen, Monique A. van der; Rega, Davide; Vanspeybroeck, Veronique; Lamaire, Aran; Rogge, Sven; Walton, Krista S.; Bingel, Lukas W.; Wuttke, Stefan; Andreo, Jacopo; Yaghi, Omar M.; Zhang, Bing; Yavuz, Cafer T.; Nguyen, Thien; Zamora, Félix; Montoro, Carmen; Zhou, Hong‐Cai; Angelo, Kirchon; Fairen‐Jimenez, David

doi:10.26434/chemrxiv.14291644

Cited by 8 publications

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“…58 In another case, the experimental value of 0.978 cm 3 g −1 slightly exceeds the geometric pore volume of CuBTC, and the manuscript also reports a very high BET surface area of 2327 m 2 g −1 , the largest ever reported to our knowledge. 59 While we are not able to determine in retrospect what led to this large valuefor example, the calibration of the instrument, a material with large defects, or an imprecise BET calculation 60 our analysis points at potential benefits from checking the geometric pore volume of the sample before moving on to measure the adsorption of other gases. 61 Since the indicators of popularity included the number of reports in the NIST-ISODB, their list of the six most studied MOFs, unsurprisingly, contains four of the MOFs listed in Table 1 (UIO-66, CuBTC, ZIF-8, and IRMOF-1).…”

Section: ■ Results and Discussionmentioning

confidence: 99%

Data-Driven Matching of Experimental Crystal Structures and Gas Adsorption Isotherms of Metal–Organic Frameworks

et al. 2022

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Porous metal–organic frameworks are a class of materials with great promise in gas separation and gas storage applications. Due to the high dimensional space of materials science and engineering, computational screening techniques have long been an important part of the scientific toolbox. However, a broad validation of molecular simulations in these materials is impeded by the lack of a connection between databases of gas adsorption experiments and databases of the atomic crystal structure of corresponding materials. This work aims to connect the gas adsorption isotherms of metal–organic frameworks collected in the NIST/ARPA-E Database of Novel and Emerging Adsorbent Materials to the corresponding crystal structures in the Cambridge Structural Database. With tens of thousands of isotherms and crystal structures reported to date, an automatic approach is needed to establish this link, which we describe in this paper. As a first application and consistency check, we compare the pore volume measured from low-temperature argon or nitrogen isotherms to the geometrical pore volume computed from the crystal structure. Overall, 545 argon or nitrogen isotherms could be matched to a corresponding crystal structure. We find that the pore volume computed via the two complementary methods shows acceptable agreement only in about 35% of these cases. We provide the subset of isotherms measured on these materials as a seed for a future and more complete reference data set for computational studies.

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Section: ■ Results and Discussionmentioning

confidence: 99%

Data-Driven Matching of Experimental Crystal Structures and Gas Adsorption Isotherms of Metal–Organic Frameworks

et al. 2022

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“…48 We next conducted N 2 adsorption experiments at 77 K to investigate the potential impact of incorporating mPEG−PO 3 into the internal porosity of PCN-222. As shown in Figure 2c, PCN-222 and PCN-222@PEG−PO 3 adsorb 526 and 129 cm 3 g −1 N 2 at P/P 0 = 0.8, respectively, with Brunauer−Emmett− Teller (BET) areas, analyzed using BETSI, 49 decreasing from 1151 to 265 m 2 g −1 (see Supporting Information, Section S4). However, the pure mPEG−PO 3 adsorbs a nearly negligible amount of N 2 (Figure S33).…”

Section: ■ Introductionmentioning

confidence: 98%

Formulation of Metal–Organic Framework-Based Drug Carriers by Controlled Coordination of Methoxy PEG Phosphate: Boosting Colloidal Stability and Redispersibility

et al. 2021

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Metal−organic framework nanoparticles (nanoMOFs) have been widely studied in biomedical applications. Although substantial efforts have been devoted to the development of biocompatible approaches, the requirement of tedious synthetic steps, toxic reagents, and limitations on the shelf life of nanoparticles in solution are still significant barriers to their translation to clinical use. In this work, we propose a new postsynthetic modification of nanoMOFs with phosphate-functionalized methoxy polyethylene glycol (mPEG− PO 3 ) groups which, when combined with lyophilization, leads to the formation of redispersible solid materials. This approach can serve as a facile and general formulation method for the storage of bare or drugloaded nanoMOFs. The obtained PEGylated nanoMOFs show stable hydrodynamic diameters, improved colloidal stability, and delayed drug-release kinetics compared to their parent nanoMOFs. Ex situ characterization and computational studies reveal that PEGylation of PCN-222 proceeds in a two-step fashion. Most importantly, the lyophilized, PEGylated nanoMOFs can be completely redispersed in water, avoiding common aggregation issues that have limited the use of MOFs in the biomedical field to the wet forma critical limitation for their translation to clinical use as these materials can now be stored as dried samples. The in vitro performance of the addition of mPEG−PO 3 was confirmed by the improved intracellular stability and delayed drug-release capability, including lower cytotoxicity compared with that of the bare nanoMOFs. Furthermore, z-stack confocal microscopy images reveal the colocalization of bare and PEGylated nanoMOFs. This research highlights a facile PEGylation method with mPEG−PO 3 , providing new insights into the design of promising nanocarriers for drug delivery.

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“…Analysis of the nitrogen adsorption isotherms (Figures 3A and S3) collected for these pellets, however, revealed a striking trend. Whereas we observed a monotonic increase in Brunauer-Emmett-Teller (BET) area-calculated by BET surface identification (BETSI) 22 -for pellets synthesized in solvent systems containing acetonitrile fractions ranging from 0.000 to 0.750 (v/v), we observed a sharp decrease in BET area to 4 m 2 g À1 for samples prepared at higher acetonitrile fractions (Figure 3C). As a result, the highest BET area that could be obtained for TPB-DMTP-COF with methanol as the activation solvent was 1,122 m 2 g À1 , suggesting the presence of a lower limit in intercrystallite pore size beyond which pore disruption takes place.…”

Section: Sol-gel Processing Of Cofsmentioning

confidence: 85%

Sol-gel processing of a covalent organic framework for the generation of hierarchically porous monolithic adsorbents

Carrington¹,

Rampal²,

Madden³

et al. 2022

Chem

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How Reproducible Are Surface Areas Calculated from the BET Equation?

Cited by 8 publications

References 0 publications

Data-Driven Matching of Experimental Crystal Structures and Gas Adsorption Isotherms of Metal–Organic Frameworks

Data-Driven Matching of Experimental Crystal Structures and Gas Adsorption Isotherms of Metal–Organic Frameworks

Formulation of Metal–Organic Framework-Based Drug Carriers by Controlled Coordination of Methoxy PEG Phosphate: Boosting Colloidal Stability and Redispersibility

Sol-gel processing of a covalent organic framework for the generation of hierarchically porous monolithic adsorbents

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