| Nome |
# |
|
H2 storage in isostructural UiO-67 and UiO-66 MOFs, file e27ce426-d41c-2581-e053-d805fe0acbaa
|
1.482
|
|
Functionalization of UiO-66 Metal-Organic Framework and Highly Cross-Linked Polystyrene with Cr(CO)(3): In Situ Formation, Stability, and Photoreactivity, file e27ce426-c1d0-2581-e053-d805fe0acbaa
|
800
|
|
Tuned to Perfection: Ironing Out the Defects in Metal-Organic Framework UiO-66, file e27ce42a-145d-2581-e053-d805fe0acbaa
|
541
|
|
Local structure of CPO-27-Ni metallorganic framework upon dehydration and coordination of NO, file e27ce426-b821-2581-e053-d805fe0acbaa
|
495
|
|
Structure and enhanced reactivity of chromocene carbonyl confined inside the cavities of NaY zeolite, file e27ce426-b6a8-2581-e053-d805fe0acbaa
|
421
|
|
CO2 Capture in Dry and Wet Conditions in UTSA-16 Metal−Organic Framework, file e27ce42b-4c8f-2581-e053-d805fe0acbaa
|
413
|
|
Carbon Dioxide Adsorption in Amine-Functionalized Mixed-Ligand Metal-Organic Frameworks of UiO-66 Topology, file e27ce427-01cd-2581-e053-d805fe0acbaa
|
383
|
|
Design and Characterization of MOFs (Metal-Organic Frameworks) for Innovative Applications, file e27ce42c-6ad6-2581-e053-d805fe0acbaa
|
355
|
|
Silica-supported Ti chloride tetrahydrofuranates, precursors of Ziegler–Natta catalysts, file e27ce426-f182-2581-e053-d805fe0acbaa
|
315
|
|
Fast carbon dioxide recycling by reaction with γ-Mg(BH4)2, file e27ce427-f9df-2581-e053-d805fe0acbaa
|
310
|
|
Effect of Pore Size, Solvation, and Defectivity on the Perturbation of Adsorbates in MOFs: The Paradigmatic Mg2(dobpdc) Case Study, file e27ce42c-11fa-2581-e053-d805fe0acbaa
|
300
|
|
Close-Packed Dye Molecules in Zeolite Channels Self-Assemble into Supramolecular Nanoladders, file e27ce427-aa98-2581-e053-d805fe0acbaa
|
298
|
|
Functionalizing the Defects: Postsynthetic Ligand Exchange in the Metal Organic Framework UiO-66, file e27ce42b-d48b-2581-e053-d805fe0acbaa
|
274
|
|
Solvent-Driven Gate Opening in MOF-76-Ce: Effect on CO2 Adsorption, file e27ce42b-34bf-2581-e053-d805fe0acbaa
|
271
|
|
Combined X-ray and Raman Studies on the Effect of Cobalt Additives on the Decomposition of Magnesium Borohydride, file e27ce427-4a62-2581-e053-d805fe0acbaa
|
253
|
|
Spectroscopic and adsorptive studies of a thermally robust pyrazolato-based PCP, file e27ce426-d551-2581-e053-d805fe0acbaa
|
239
|
|
Hydrogen storage of Mg–Zn mixed metal borohydrides, file e27ce428-fbf5-2581-e053-d805fe0acbaa
|
218
|
|
Design of high surface area poly(ionic liquid)s to convert carbon dioxide into ethylene carbonate, file e27ce427-b8dd-2581-e053-d805fe0acbaa
|
216
|
|
CO2 Capture in Dry and Wet Conditions in UTSA-16 Metal−Organic Framework, file e27ce42b-4c8e-2581-e053-d805fe0acbaa
|
157
|
|
Material properties and empirical rate equations for hydrogen sorption reactions in 2 LiNH2–1.1 MgH2–0.1 LiBH4–3 wt.% ZrCoH3, file e27ce429-af86-2581-e053-d805fe0acbaa
|
143
|
|
Hydride phase formation in carbon supported palladium hydride nanoparticles by in situ EXAFS and XRD, file e27ce42a-49aa-2581-e053-d805fe0acbaa
|
143
|
|
Understanding and Controlling the Dielectric Response of Metal–Organic Frameworks, file e27ce42d-db48-2581-e053-d805fe0acbaa
|
135
|
|
Tuned to Perfection: Ironing Out the Defects in Metal-Organic Framework UiO-66, file e27ce427-b3e1-2581-e053-d805fe0acbaa
|
119
|
|
Core-Shell Structure of Palladium Hydride Nanoparticles Revealed by Combined X-ray Absorption Spectroscopy and X-ray Diffraction, file e27ce42c-61ec-2581-e053-d805fe0acbaa
|
88
|
|
Structure-activity relationships of simple molecules adsorbed on CPO-27-Ni Metal-Organic Framework: in situ experiments vs. theory, file e27ce426-dbec-2581-e053-d805fe0acbaa
|
73
|
|
CO2 Adsorption Sites in UTSA-16: Multitechnique Approach, file e27ce42a-51ae-2581-e053-d805fe0acbaa
|
69
|
|
New insights into UTSA-16, file e27ce42a-51a9-2581-e053-d805fe0acbaa
|
67
|
|
Spectroscopic and Structural Characterization of Thermal Decomposition of γ-Mg(BH4)2: Dynamic Vacuum versus H2 Atmosphere, file e27ce427-fb97-2581-e053-d805fe0acbaa
|
59
|
|
Characterization and Modeling of Reversible CO2 Capture from Wet Streams by a MgO/Zeolite Y Nanocomposite, file e27ce42e-733b-2581-e053-d805fe0acbaa
|
59
|
|
Conductive ZSM-5-Based Adsorbent for CO2 Capture: Active Phase vs Monolith, file e27ce42c-b0dc-2581-e053-d805fe0acbaa
|
53
|
|
Structure and Host-Guest Interactions of Perylene-Diimide Dyes in Zeolite L Nanochannels, file e27ce42d-47d1-2581-e053-d805fe0acbaa
|
48
|
|
New insights into UTSA-16, file e27ce42a-83f6-2581-e053-d805fe0acbaa
|
42
|
|
Conductive ZSM-5-Based Adsorbent for CO2 Capture: Active Phase vs Monolith, file e27ce42c-8964-2581-e053-d805fe0acbaa
|
41
|
|
Evolution and Reversibility of Host/Guest Interactions with Temperature Changes in a Methyl Red@Palygorskite Polyfunctional Hybrid Nanocomposite, file e27ce429-8bc6-2581-e053-d805fe0acbaa
|
40
|
|
Soft synthesis of isocyanate-functionalised metal-organic frameworks., file e27ce42a-3d77-2581-e053-d805fe0acbaa
|
40
|
|
Functionalizing the Defects: Postsynthetic Ligand Exchange in the Metal Organic Framework UiO-66, file e27ce42b-b248-2581-e053-d805fe0acbaa
|
40
|
|
Soft synthesis of isocyanate-functionalised metal-organic frameworks., file e27ce42a-7c95-2581-e053-d805fe0acbaa
|
32
|
|
A multi-technique approach to disclose the reaction mechanism of dimethyl carbonate synthesis over amino-modified SBA-15 catalysts, file e27ce42c-1bea-2581-e053-d805fe0acbaa
|
32
|
|
Solvent-Driven Gate Opening in MOF-76-Ce: Effect on CO2 Adsorption, file e27ce431-68cc-2581-e053-d805fe0acbaa
|
32
|
|
Functionalization of CPO-27-Ni through metal hexacarbonyls: The role of open Ni2+ sites, file e27ce42a-1ceb-2581-e053-d805fe0acbaa
|
30
|
|
Low temperature activation and reactivity of CO2 over a Cr-II-based heterogeneous catalyst: a spectroscopic study, file e27ce426-e9f4-2581-e053-d805fe0acbaa
|
28
|
|
Understanding and Controlling the Dielectric Response of Metal–Organic Frameworks, file e27ce434-f996-2581-e053-d805fe0acbaa
|
23
|
|
Thionine Dye Confined in Zeolite L: Synthesis Location and Optical Properties, file e27ce42b-88ad-2581-e053-d805fe0acbaa
|
22
|
|
Direct evidence of adsorption induced CrII mobility on the SiO2 surface upon complexation by CO, file e27ce426-dc36-2581-e053-d805fe0acbaa
|
21
|
|
Temperature dependent adsorpion of CO on CrII/SiO2 system inducing Cr mobility on the surface, file e27ce426-dc38-2581-e053-d805fe0acbaa
|
18
|
|
Characterization and Modeling of Reversible CO2 Capture from Wet Streams by a MgO/Zeolite Y Nanocomposite, file e27ce42e-733c-2581-e053-d805fe0acbaa
|
13
|
|
CO2 Adsorption Sites in UTSA-16: Multitechnique Approach, file e27ce431-aca8-2581-e053-d805fe0acbaa
|
10
|
|
Conductive ZSM-5-Based Adsorbent for CO2 Capture: Active Phase vs Monolith, file e27ce42c-484d-2581-e053-d805fe0acbaa
|
6
|
|
Theoretical and experimental study on Mg(BH4) 2-Zn(BH4)2 mixed borohydrides, file e27ce427-d9ac-2581-e053-d805fe0acbaa
|
4
|
|
Theoretical and experimental study on Mg(BH4) 2-Zn(BH4)2 mixed borohydrides, file e27ce429-1d41-2581-e053-d805fe0acbaa
|
4
|
|
Cyclodextrin nanosponges as effective gas carriers, file e27ce426-ddde-2581-e053-d805fe0acbaa
|
3
|
|
Spectroscopic and Structural Characterization of Thermal Decomposition of γ-Mg(BH4)2: Dynamic Vacuum versus H2 Atmosphere, file e27ce427-fb8d-2581-e053-d805fe0acbaa
|
3
|
|
Solvent-Driven Gate Opening in MOF-76-Ce: Effect on CO2 Adsorption, file e27ce42a-ff0d-2581-e053-d805fe0acbaa
|
3
|
|
Conductive ZSM-5-Based Adsorbent for CO2 Capture: Active Phase vs Monolith, file e27ce42c-7f41-2581-e053-d805fe0acbaa
|
3
|
|
Characterization and Modeling of Reversible CO2 Capture from Wet Streams by a MgO/Zeolite Y Nanocomposite, file e27ce42e-74e0-2581-e053-d805fe0acbaa
|
3
|
|
Tailoring Metal-Organic Frameworks for CO(2) Capture: The Amino Effect, file e27ce426-d130-2581-e053-d805fe0acbaa
|
2
|
|
Functionalization of CPO-27-Ni through metal hexacarbonyls: The role of open Ni2+ sites, file e27ce426-e9f6-2581-e053-d805fe0acbaa
|
2
|
|
Functionalizing the Defects: Postsynthetic Ligand Exchange in the Metal Organic Framework UiO-66, file e27ce42b-6e02-2581-e053-d805fe0acbaa
|
2
|
|
Looking for the active hydrogen species in a 5 wt% Pt/C catalyst: A challenge for inelastic neutron scattering, file e27ce42d-a81e-2581-e053-d805fe0acbaa
|
2
|
|
Structure-activity relationships of simple molecules adsorbed on MOF materials: in situ experiments vs. theory, file e27ce426-d394-2581-e053-d805fe0acbaa
|
1
|
|
Low temperature activation and reactivity of CO2 over a Cr-II-based heterogeneous catalyst: a spectroscopic study, file e27ce426-e9f3-2581-e053-d805fe0acbaa
|
1
|
|
Carbon Dioxide Adsorption in Amine-Functionalized Mixed-Ligand Metal-Organic Frameworks of UiO-66 Topology, file e27ce427-01cf-2581-e053-d805fe0acbaa
|
1
|
|
Carbon Dioxide Adsorption in Amine-Functionalized Mixed-Ligand Metal-Organic Frameworks of UiO-66 Topology, file e27ce427-01d0-2581-e053-d805fe0acbaa
|
1
|
|
Evolution and Reversibility of Host/Guest Interactions with Temperature Changes in a Methyl Red@Palygorskite Polyfunctional Hybrid Nanocomposite, file e27ce427-09d8-2581-e053-d805fe0acbaa
|
1
|
|
Soft synthesis of isocyanate-functionalised metal-organic frameworks., file e27ce42a-3727-2581-e053-d805fe0acbaa
|
1
|
|
Core-Shell Structure of Palladium Hydride Nanoparticles Revealed by Combined X-ray Absorption Spectroscopy and X-ray Diffraction, file e27ce42c-b67c-2581-e053-d805fe0acbaa
|
1
|
|
Looking for the active hydrogen species in a 5 wt% Pt/C catalyst: A challenge for inelastic neutron scattering, file e27ce42d-a030-2581-e053-d805fe0acbaa
|
1
|
|
Understanding and Controlling the Dielectric Response of Metal–Organic Frameworks, file e27ce42d-db47-2581-e053-d805fe0acbaa
|
1
|
| Totale |
9.307 |