about
Tin-containing zeolites are highly active catalysts for the isomerization of glucose in water.Metalloenzyme-like catalyzed isomerizations of sugars by Lewis acid zeolitesSynthesis of an extra-large molecular sieve using proton sponges as organic structure-directing agents.State of the art of Lewis acid-containing zeolites: lessons from fine chemistry to new biomass transformation processes.Multipore zeolites: synthesis and catalytic applications.Design of a full-profile-matching solution for high-throughput analysis of multiphase samples through powder X-ray diffraction.Zeolite synthesis modelling with support vector machines: a combinatorial approach.Reversible Transformation of Pt Nanoparticles into Single Atoms inside High-Silica Chabazite Zeolite.Fe-Containing Zeolites for NH3 -SCR of NOx : Effect of Structure, Synthesis Procedure, and Chemical Composition on Catalytic Performance and Stability."Ab initio" synthesis of zeolites for preestablished catalytic reactions.Towards the rational design of efficient organic structure-directing agents for zeolite synthesis.Synthesis of highly stable metal-containing extra-large-pore molecular sieves.Supra-molecular assembly of aromatic proton sponges to direct the crystallization of extra-large-pore zeotypes.The ITQ-37 mesoporous chiral zeolite.Nanocrystalline SSZ-39 zeolite as an efficient catalyst for the methanol-to-olefin (MTO) process.High-silica nanocrystalline Beta zeolites: efficient synthesis and catalytic application.Simple organic structure directing agents for synthesizing nanocrystalline zeolites.High-throughput synthesis and catalytic properties of a molecular sieve with 18- and 10-member ringsTrapping of Metal Atoms and Metal Clusters by Chabazite under Severe Redox StressIron-Containing SSZ-39 (AEI) Zeolite: An Active and Stable High-Temperature NH3 -SCR CatalystZeolite structure determination using electron crystallographyA Machine Learning Approach to Zeolite Synthesis Enabled by Automatic Literature Data ExtractionFrom metal-supported oxides to well-defined metal site zeolites: the next generation of passive NOx adsorbers for low-temperature control of emissions from diesel enginesSynthesis of reaction‐adapted zeolites as methanol-to-olefins catalysts with mimics of reaction intermediates as organic structure‐directing agentsOptimal Operating Conditions of Coupled Sequential NOx Storage/Reduction and Cu/CHA Selective Catalytic Reduction MonolithsCu-zeolite catalysts for NO x removal by selective catalytic reduction with NH 3 and coupled to NO storage/reduction monolith in diesel engine exhaust aftertreatment systemsITQ-39 zeolite, an efficient catalyst for the conversion of low value naphtha fractions into diesel fuel: The role of pore size on molecular diffusion and reactivityImproving the catalytic performance of SAPO-18 for the methanol-to-olefins (MTO) reaction by controlling the Si distribution and crystal sizeSynthesis of Al-MTW with low Si/Al ratios by combining organic and inorganic structure directing agentsEfficient synthesis of the Cu-SSZ-39 catalyst for DeNOx applicationsHigh yield synthesis of high-silica chabazite by combining the role of zeolite precursors and tetraethylammonium: SCR of NOxRigid/Flexible Organic Structure Directing Agents for Directing the Synthesis of Multipore Zeolites: A Computational ApproachSelf-Assembled Aromatic Molecules as Efficient Organic Structure Directing Agents to Synthesize the Silicoaluminophosphate SAPO-42 with Isolated Si SpeciesAdvances in the synthesis of titanosilicates: From the medium pore TS-1 zeolite to highly-accessible ordered materialsDirect synthesis design of Cu-SAPO-18, a very efficient catalyst for the SCR of NOxExperimental energetics of large and extra-large pore zeolites: Pure silica beta polymorph C (BEC) and Ge-containing ITQ-33Synthesis of the Small Pore Silicoaluminophosphate STA-6 by Using Supramolecular Self-Assembled Organic Structure Directing AgentsSynthesis Strategies for Preparing Useful Small Pore Zeolites and Zeotypes for Gas Separations and CatalysisSynthesis, characterization and reactivity of high hydrothermally stable Cu-SAPO-34 materials prepared by “one-pot” processesEfficient One-Pot Preparation of Cu-SSZ-13 Materials using Cooperative OSDAs for their Catalytic Application in the SCR of NOx
P50
Q33779013-CC8484ED-FDF5-4241-98A2-5D7F6C2A6747Q36056410-5E1F6936-21BB-49D8-91AD-15FCF43B87DCQ36673059-6AEFFF9C-DB08-49F7-AFB5-2F1FD4CF9A3FQ38154167-7BCEAE81-400C-4D35-9ED2-81320FFE4E8DQ38349016-085C4E50-5674-4279-B0FE-D3A1F336A7AEQ42615540-0C093C17-BA96-49CE-8EDF-F5C35A8FF2F0Q45965546-36FB062B-44F5-4B40-A66B-1435AAA9EA65Q46448499-CF427259-D5E0-4A7E-B1AA-9B09F0382D97Q48125673-FD6D7F84-E91A-46A7-897B-54F82968BC7AQ48143121-96CBDD18-A8B2-43A9-A732-D66C6A95AD7DQ50471137-B1104B71-3A1A-4A8D-A182-F8065028BBDAQ50736888-09D37F0B-5B80-486B-B6E3-911E52B10E10Q51080601-6BD21285-6FEC-4A90-A9E1-22ABF7D27DEBQ51834728-29EC8DB5-2B14-4481-B6FB-D27E681921EEQ53155598-8317824A-8978-4F46-B7E5-86E9746603EBQ55284876-A97EAA38-21D2-49B2-9346-2A4D95BF11F0Q55312981-73DEE1BC-50C0-4370-8B8B-F875248B0C2FQ59079098-98B09885-4737-4E39-AA66-907702DBDDFDQ59245320-7E5C1BD8-6218-445A-A5F2-CC33D3A85707Q59245406-171C989D-EAD5-4050-94B8-2F346154D45EQ60315252-FB36F81E-58D3-4084-89B4-C42A8E2F7C56Q63886865-B0D81F0F-82F7-4C2A-8470-D8C1CC84746EQ63886873-B253F32B-E1A9-4A9A-8B8A-20B720870304Q63886903-A090AD98-CEFD-43BF-9E10-B86C9C3243BEQ63886919-2FF08F53-8600-477E-AED6-4FADDDD4D125Q63886933-846CDD69-152D-4239-93F9-F012D52BD6E5Q63886939-B83849E8-F5ED-448B-9824-A15EC9DC9785Q63886940-9571335C-0351-4283-A7AB-E79AD0A94A1CQ63886961-C711390E-AD7F-484B-A410-97F4A3C92B0CQ63886982-557399BD-1A79-4ACF-9AC6-47A38F5E6275Q63886986-B246E587-1719-4F86-B4BF-18C9F2C2D184Q63886993-FC7878E4-DF43-4102-9403-1570342BB4B9Q63886995-EF53CE1D-73E1-42E8-86EF-A3869E59849AQ63887013-A3DF7621-6CA7-443B-81AB-4B5298F6E2C0Q63887027-964FED40-3F5A-4333-BD98-00C8EE32DB76Q63887030-2C93B68E-A65E-496B-986E-54DEBB00859CQ63887068-4C27D18D-8914-4920-AC21-AC9701D47E7EQ63887071-BC48D185-2689-47D2-BF43-B6575C4E50EBQ63887072-17D5EC97-36E1-4874-9A1C-14BBAA3943DCQ63887080-8AAB0D4E-01D0-4281-8559-9C7792BBFA0E
P50
description
onderzoeker
@nl
researcher
@en
հետազոտող
@hy
name
Manuel Moliner
@ast
Manuel Moliner
@en
Manuel Moliner
@es
Manuel Moliner
@nl
type
label
Manuel Moliner
@ast
Manuel Moliner
@en
Manuel Moliner
@es
Manuel Moliner
@nl
prefLabel
Manuel Moliner
@ast
Manuel Moliner
@en
Manuel Moliner
@es
Manuel Moliner
@nl
P106
P1153
22835346300
P21
P31
P496
0000-0002-5440-716X