Search

Your search keyword '"Hupp, Joseph T."' showing total 2,060 results
Start Over Author "Hupp, Joseph T."
2,060 results on '"Hupp, Joseph T."'

6. Computational Screening of Nanoporous Materials for Hexane and Heptane Isomer Separation

Author

Chung, Yongchul G, Bai, Peng, Haranczyk, Maciej, Leperi, Karson T, Li, Peng, Zhang, Hongda, Wang, Timothy C, Duerinck, Tim, You, Fengqi, Hupp, Joseph T, Farha, Omar K, Siepmann, J Ilja, and Snurr, Randall Q

Subjects
Inorganic Chemistry, Engineering, Chemical Sciences, Materials, Chemical sciences
Abstract

Computational high-throughput screening was carried out to assess a large number of experimentally reported metal-organic frameworks (MOFs) and zeolites for their utility in hexane isomer separation. Through the work, we identified many MOFs and zeolites with high selectivity (SL+M > 10) for the group of n-hexane, 2-methylpentane, and 3-methylpentane (linear and monobranched isomers) versus 2,2-dimethylbutane and 2,3-dimethylbutane (dibranched isomers). This group of selective sorbents includes VICDOC (Fe2(BDP)3), a MOF with triangular pores that is known to exhibit high isomer selectivity and capacity. For three of these structures, the adsorption isotherms for a 10-component mixture of hexane and heptane isomers were calculated. Subsequent simulations of column breakthrough curves showed that the DEYVUA MOF exhibits a longer process cycle time than VICDOC MOF or MRE zeolite, which are previously reported, high-performing materials, illustrating the importance of capacity in designing MOFs for practical applications. Among the identified candidates, we synthesized and characterized a MOF in a new copper form with high predicted adsorbent capacity (qL+M > 1.2 mol/L) and moderately high selectivity (SL+M ≈ 10). Finally, we examined the role of pore shape in hexane isomer separations, especially of triangular-shaped pores. We show through the potential energy surface and three-dimensional siting analyses that linear alkanes do not populate the corners of narrow triangular channels and that structures with nontriangular pores can efficiently separate hexane isomers. Detailed thermodynamic analysis illustrates how differences in the free energy of adsorption contribute to shape-selective separation in nanoporous materials.

Published
2017

7. Nitrogen-enriched flexible metal–organic framework for CO2 adsorption.

Author

Lancheros, Andrés, Goswami, Subhadip, Zarate, Ximena, Schott, Eduardo, and Hupp, Joseph T.

Subjects
METAL-organic frameworks, X-ray powder diffraction, SCANNING electron microscopy, ADSORPTION isotherms, ADSORPTION capacity
Abstract

A novel MOF named [Zn2(L)(DMF)] was synthesized using solvothermal methods from the reaction of the new linker (4,4′,4′′-(4,4′,4′′-(benzene-1,3,5-triyltris(methylene))tris(3,5-dimethyl-1H-pyrazole-4,1-diyl))tribenzoic acid) and Zn(NO3)2·6H2O. This new MOF was characterized by means of different techniques: powder X-ray diffraction, N2 adsorption and desorption isotherms, thermogravimetric analysis, and scanning electron microscopy. Furthermore, suitable crystals were obtained, which allowed us to perform the X-Ray structure determination of this MOF. The capability of these new MOF to adsorb CO2 at different temperatures was measured and its isosteric enthalpy of adsorption was calculated. The novel MOF shows an uncommon node composed of a Zn3(–COO)6(DMF)2, and the asymmetric unit contains one crystallographically independent linker, one DMF molecule, and two Zn atoms. The [Zn2(L)(DMF)] MOF is a microporous material with high crystallinity and stability up to 250 °C. The multiple nitrogenated pyrazole linkers in its framework enhance its CO2 adsorption capabilities. This material exhibits a low CO2 isosteric enthalpy of adsorption (Hads), comparable to previously reported values for similar nitrogenated materials. All the observed CO2 adsorption capacities were further supported by DFT calculations. [ABSTRACT FROM AUTHOR]

Published
2024
Full Text
View/download PDF

11. Tuning the Surface Chemistry of Metal Organic Framework Nodes: Proton Topology of the Metal-Oxide-Like Zr6 Nodes of UiO-66 and NU-1000.

Author

Yang, Dong, Bernales, Varinia, Islamoglu, Timur, Farha, Omar K, Hupp, Joseph T, Cramer, Christopher J, Gagliardi, Laura, and Gates, Bruce C

Subjects
General Chemistry, Chemical Sciences
Abstract

Some metal organic frameworks (MOFs) incorporate nodes that are nanoscale metal oxides, and the hydroxy-containing functional groups on them provide opportunities for introducing catalytic sites with precisely defined structures. Investigations have been done to understand the structures of these groups on nodes and node vacancies, because, in prospect, atomic-scale modulation of the composition, areal density, and/or siting of the groups would open up possibilities for exquisite tuning of the siting and performance of subsequently anchored catalytic units (e.g., single metal ions, pairs of metal ions, or well-defined metal-ion-containing clusters). We have combined infrared (IR) spectroscopy and density functional theory (DFT) to demonstrate tuning of these sites, namely, hydrogen-bonded OH/OH2 groups on the Zr6 nodes of the MOFs UiO-66 and NU-1000 via the intermediacy of node methoxy (or ethoxy) groups formed from methanol (or ethanol). Methoxy (or ethoxy) groups on node vacancy sites are converted to a structure incorporating one vacant Zr site and one terminal OH group per face by reaction with water. Our results highlight how the combination of DFT and IR spectroscopy facilitates the determination of the identity and chemistry of the functional groups on MOF node vacancies and defect sites.

Published
2016

12. Tuning Zr6 Metal–Organic Framework (MOF) Nodes as Catalyst Supports: Site Densities and Electron-Donor Properties Influence Molecular Iridium Complexes as Ethylene Conversion Catalysts

Author

Yang, Dong, Odoh, Samuel O, Borycz, Joshua, Wang, Timothy C, Farha, Omar K, Hupp, Joseph T, Cramer, Christopher J, Gagliardi, Laura, and Gates, Bruce C

Subjects
metal-organic framework nodes, catalyst supports, iridium ethylene complexes, iridium carbonyl complexes, ethylene hydrogenation, ethylene dimerization, Inorganic Chemistry, Organic Chemistry, Chemical Engineering
Abstract

The Zr6 nodes of the metal-organic frameworks (MOFs) UiO-66 and UiO-67 are metal oxide clusters of atomic precision and can be used as catalyst supports. The bonding sites on these nodes - that is, hydrogen-bonded H2O/OH groups on UiO-67 and non-hydrogen-bonded terminal OH groups on UiO-66 - were regulated by modulation of the MOF syntheses. Ir(C2H4)2(C5H7O2) complexes reacted with these sites to give site-isolated Ir(C2H4)2 complexes, each anchored to the node by two Ir-Onode bonds. The supported iridium complexes on these sites have been characterized by infrared (IR) and extended X-ray absorption fine structure (EXAFS) spectroscopies and density functional theory calculations. The ethylene ligands on iridium are readily replaced by CO, and the νCO frequencies of the resultant complexes and those of comparable complexes reported elsewhere show that the support electron-donor tendencies increase in the order HY zeolite 蠐 UiO-66 < UiO-67 (= NU-1000) < ZrO2 < MgO. The sharpness of the IR νCO bands shows that the degree of uniformity of the support bonding sites decreases in the order ZrO2 ≈ UiO-67 ≈ NU-1000 < MgO < UiO-66 蠐 HY zeolite. The reactivity of supported Ir(CO)2 complexes with C2H4 to form Ir(C2H4)(CO) and Ir(C2H4)2(CO) is influenced by the support electron-donor properties, with the reactivity increasing in the order MgO = ZrO2 = NU-1000 (not reactive) < UiO-66 < UiO-67 蠐 HY zeolite. Density functional theory calculations characterizing the complexes supported on NU-1000, UiO-66/67, and HY zeolite concur with the use of the calculated νCO bands as indicators of electron-donor properties of the supported metal catalysts. Our calculations also show that the reactivity of the supported Ir(CO)2 complexes with C2H4 is correlated with the electron-donor properties of the iridium center. The supported Ir(C2H4)2 samples are precatalysts for ethylene hydrogenation and ethylene dimerization, with the activity for each reaction increasing with increasing electron-withdrawing strength of the support.

Published
2016

13. Metal–Organic Framework Nodes as Nearly Ideal Supports for Molecular Catalysts: NU-1000- and UiO-66-Supported Iridium Complexes

Author

Yang, Dong, Odoh, Samuel O, Wang, Timothy C, Farha, Omar K, Hupp, Joseph T, Cramer, Christopher J, Gagliardi, Laura, and Gates, Bruce C

Subjects
Chemical Sciences, General Chemistry
Abstract

Metal-organic frameworks with Zr6 nodes, UiO-66 and NU-1000, were investigated as supports for Ir(CO)2 and Ir(C2H4)2 complexes. A single bonding site for the iridium is identified on the nodes of NU-1000, whereas two sites are identified on UiO-66, although at low iridium loadings only one site is occupied. Density functional theory calculations provide structural results that are in good agreement with infrared and X-ray absorption fine-structure spectra. The reactivity of node-supported Ir(CO)2 with C2H4 and the catalytic activity and selectivity of the species initially present as Ir(C2H4)2 for ethylene hydrogenation and dimerization were investigated both experimentally and computationally and shown to be strongly influenced by the node.

Published
2015

16. Versatile sulfidation of a metal-organic framework via heterolytic splitting of organo sulfides at distorted Zr-nodes

Author

Wang, Qining, primary, Vornholt, Simon M., additional, Melix, Patrick, additional, Formalik, Filip, additional, Chen, Zhihengyu, additional, Tufaro, Luke M., additional, Liu, Jian, additional, Kramar, Boris V., additional, Wang, Zhiwei, additional, Chen, Lin X., additional, Snurr, Randall Q., additional, Chapman, Karena W., additional, Notestein, Justin M., additional, and Hupp, Joseph T., additional

Published
2023
Full Text
View/download PDF

25. CO2 Capture and Conversion to C1 Chemicals with Mixed-Metal Copper/Nickel Bis(amino)bipyrazolate Metal–Organic Frameworks

Author

Campitelli, Patrizio, primary, Tombesi, Alessia, additional, Di Nicola, Corrado, additional, Pettinari, Claudio, additional, Mauri, Anna, additional, Galli, Simona, additional, Yan, Tongan, additional, Liu, Dahuan, additional, Duan, Jiaxin Dawn, additional, Goswami, Subhadip, additional, Tuci, Giulia, additional, Giambastiani, Giuliano, additional, Hupp, Joseph T., additional, and Rossin, Andrea, additional

Published
2023
Full Text
View/download PDF

26. Reconstructing Oxygen‐Deficient Zirconia with Ruthenium Catalyst on Atomic‐Scale Interfaces toward Hydrogen Production (Adv. Funct. Mater. 29/2023)

Author

Kim, Mansu, primary, Kim, Seung‐hoon, additional, Park, Jonghwan, additional, Lee, Seongsoo, additional, Jang, Injoon, additional, Kim, Sohui, additional, Lee, Chang Yeon, additional, Kwon, Oh Joong, additional, Ham, Hyung Chul, additional, Hupp, Joseph T., additional, Jung, Namgee, additional, Yoo, Sung Jong, additional, and Whang, Dongmok, additional

Published
2023
Full Text
View/download PDF

27. Chemically Reversible CO2Uptake by Dendrimer-Impregnated Metal–Organic Frameworks

Author

Goncalves, Rebecca B., Collados, Carlos Cuadrado, Malliakas, Christos D., Wang, Zhiwei, Thommes, Matthias, Snurr, Randall Q., and Hupp, Joseph T.

Abstract

Industrialization over the past two centuries has resulted in a continuous rise in global CO2emissions. These emissions are changing ecosystems and livelihoods. Therefore, methods are needed to capture these emissions from point sources and possibly from our atmosphere. Though the amount of CO2is rising, it is challenging to capture directly from air because its concentration in air is extremely low, 0.04%. In this study, amines installed inside metal–organic frameworks (MOFs) are investigated for the adsorption of CO2, including at low concentrations. The amines used are polyamidoamine dendrimers that contain many primary amines. Chemically reversible adsorption of CO2via carbamate formation was observed, as was enhanced uptake of carbon dioxide, likely via dendrimer-amide-based physisorption. Limiting factors in this initial study are comparatively low dendrimer loadings and slow kinetics for carbon dioxide uptake and release, even at 80 °C.

Published
2024
Full Text
View/download PDF

32. Photoreactive Carbon Dioxide Capture by a Zirconium–Nanographene Metal–Organic Framework

Author

Zheng, Xin, primary, Drummer, Matthew C., additional, He, Haiying, additional, Rayder, Thomas M., additional, Niklas, Jens, additional, Weingartz, Nicholas P., additional, Bolotin, Igor L., additional, Singh, Varun, additional, Kramar, Boris V., additional, Chen, Lin X., additional, Hupp, Joseph T., additional, Poluektov, Oleg G., additional, Farha, Omar K., additional, Zapol, Peter, additional, and Glusac, Ksenija D., additional

Published
2023
Full Text
View/download PDF

35. Synthetic Access to a Framework-Stabilized and Fully Sulfided Analogue of an Anderson Polyoxometalate that is Catalytically Competent for Reduction Reactions

Author

Duan, Jiaxin, primary, Shabbir, Hafeera, additional, Chen, Zhihengyu, additional, Bi, Wentuan, additional, Liu, Qin, additional, Sui, Jingyi, additional, Đorđević, Luka, additional, Stupp, Samuel I., additional, Chapman, Karena W., additional, Martinson, Alex B. F., additional, Li, Alice, additional, Schaller, Richard D., additional, Goswami, Subhadip, additional, Getman, Rachel B., additional, and Hupp, Joseph T., additional

Published
2023
Full Text
View/download PDF

38. Photoreactive CO2 Capture by a Zr-Nanographene MOF

Author

Zheng, Xin, primary, Drummer, Matthew C., additional, He, Haiying, additional, Saffar Avval, Shirin, additional, Rayder, Thomas M., additional, Niklas, Jens, additional, Weingartz, Nicholas P., additional, Singh, Varun, additional, Kramar, Boris V., additional, Chen, Lin X., additional, Hupp, Joseph T., additional, Poluektov, Oleg G., additional, Farha, Omar K., additional, Chaplin, Brian P., additional, Zapol, Peter, additional, and Glusac, Ksenija D., additional

Published
2022
Full Text
View/download PDF

40. Synthetic access to a framework-stabilized and fully sulfided analogue of an Anderson polyoxometalate that is catalytically competent for reduction reactions

Author

Duan, Jiaxin, primary, Shabbir, Hafeera, additional, Chen, Zhihengyu, additional, Bi, Wentuan, additional, Liu, Qin, additional, Sui, Jingyi, additional, Dordević, Luka, additional, Stupp, Samuel I., additional, Chapman, Karena, additional, Martinson, Alex B. F., additional, Li, Alice, additional, Goswami, Subhadip, additional, Schaller, Richard D., additional, Getman, Rachel, additional, and Hupp, Joseph T., additional

Published
2022
Full Text
View/download PDF

44. Toward Ideal Metal–Organic Framework Thin-Film Growth via Automated Layer-by-Layer Deposition: Examples Based on Perylene Diimide Linkers

Author

Goswami, Subhadip, primary, Rimoldi, Martino, additional, Anderson, Ryther, additional, Lee, Changmin, additional, Li, Xinlin, additional, Li, Alice, additional, Deria, Pravas, additional, Chen, Lin X., additional, Schaller, Richard D., additional, Gómez-Gualdrón, Diego A., additional, Farha, Omar K., additional, and Hupp, Joseph T., additional

Published
2022
Full Text
View/download PDF

46. Structural reversibility of Cu doped NU-1000 MOFs under hydrogenation conditions.

Author

Halder, Avik, Lee, Sungsik, Yang, Bing, Pellin, Michael J., Vajda, Stefan, Li, Zhanyong, Yang, Ying, Farha, Omar K., and Hupp, Joseph T.

Subjects
ATOMIC layer deposition, HYDROGENATION, HETEROGENEOUS catalysis, HYDROGEN storage, CHEMICAL yield, WATER clusters
Abstract

The metal–organic framework (MOF), NU-1000, and its metalated counterparts have found proof-of-concept application in heterogeneous catalysis and hydrogen storage among others. A vapor-phase technique, akin to atomic layer deposition (ALD), is used to selectively deposit divalent Cu ions on oxo, hydroxo-bridged hexa-zirconium(IV) nodes capped with terminal –OH and –OH2 ligands. The subsequent reaction with steam yields node-anchored, CuII-oxo, hydroxo clusters. We find that cluster installation via AIM (ALD in MOFs) is accompanied by an expansion of the MOF mesopore (channel) diameter. We investigated the behavior of the cluster-modified material, termed Cu-AIM-NU-1000, to heat treatment up to 325 °C at atmospheric pressure with a low flow of H2 into the reaction cell. The response under these conditions revealed two important results: (1) Above 200 °C, the initially installed few-metal-ion clusters reduce to neutral Cu atoms. The neutral atoms migrate from the nodes and aggregate into Cu nanoparticles. While the size of particles formed in the MOF interior is constrained by the width of mesopores (∼3 nm), the size of those formed on the exterior surface of the MOF can grow as large as ∼8 nm. (2) Reduction and release of Cu atoms from the MOFs nodes is accompanied by the dynamic structural transformation of NU-1000 as it reverts back to its original dimension following the release. These results show that while the MOF framework itself remains intact at 325 °C in an H2 atmosphere, the small, AIM-installed CuII-oxo, hydroxo clusters are stable with respect to reduction and conversion to metallic nanoparticles only up to ∼200 °C. [ABSTRACT FROM AUTHOR]

Published
2020
Full Text
View/download PDF

Catalog

Books, media, physical & digital resources
See catalog results