about
Yolk-Shell-Structured Aluminum Phenylphosphonate Microspheres with Anionic Core and Cationic ShellOrigin of the electrocatalytic oxygen reduction activity of graphene-based catalysts: a roadmap to achieve the best performance.Toward design of synergistically active carbon-based catalysts for electrocatalytic hydrogen evolutionEngineering surface atomic structure of single-crystal cobalt (II) oxide nanorods for superior electrocatalysisHierarchically macro-mesoporous Pt/γ-Al2O3 composite microspheres for efficient formaldehyde oxidation at room temperature.Earth-abundant cocatalysts for semiconductor-based photocatalytic water splitting.All-solid-state Z-scheme photocatalytic systems.Design of electrocatalysts for oxygen- and hydrogen-involving energy conversion reactions.Polymeric photocatalysts based on graphitic carbon nitride.Molecular-based design and emerging applications of nanoporous carbon spheres.Solution combustion synthesis of metal oxide nanomaterials for energy storage and conversion.Heterojunction Photocatalysts.One-Pot Synthesis of Mesoporous Ni-Ti-Al Ternary Oxides: Highly Active and Selective Catalysts for Steam Reforming of Ethanol.Hierarchical photocatalysts.Synthesis and applications of porous non-silica metal oxide submicrospheres.Hydrogen evolution by a metal-free electrocatalyst.Gas adsorption properties of graphene-based materials.Biocompatible D-Penicillamine Conjugated Au Nanoparticles: Targeting Intracellular Free Copper Ions for Detoxification.A Highly Efficient and Extremely Selective Intracellular Copper Detoxifying Agent Based on Nanoparticles of ZnMoS4.Activated carbon spheres for CO2 adsorption.Activating cobalt(II) oxide nanorods for efficient electrocatalysis by strain engineering.Three-dimensional N-doped graphene hydrogel/NiCo double hydroxide electrocatalysts for highly efficient oxygen evolution.Engineering High-Energy Interfacial Structures for High-Performance Oxygen-Involving Electrocatalysis.Facile synthesis of polymer and carbon spheres decorated with highly dispersed metal nanoparticles.Enhanced performance of NaOH-modified Pt/TiO2 toward room temperature selective oxidation of formaldehyde.Mesoporous organosilica with amidoxime groups for CO2 sorption.Cocatalysts in Semiconductor-based Photocatalytic CO2 Reduction: Achievements, Challenges, and Opportunities.Molecular Scaffolding Strategy with Synergistic Active Centers To Facilitate Electrocatalytic CO2 Reduction to Hydrocarbon/Alcohol.Gas adsorption properties of hybrid graphene-MOF materials.Interacting Carbon Nitride and Titanium Carbide Nanosheets for High-Performance Oxygen Evolution.Na2 Ti3 O7 @N-Doped Carbon Hollow Spheres for Sodium-Ion Batteries with Excellent Rate Performance.Self-Templating Synthesis of Hollow Co3 O4 Microtube Arrays for Highly Efficient Water Electrolysis.Facile formation of metallic bismuth/bismuth oxide heterojunction on porous carbon with enhanced photocatalytic activity.Application of novel hierarchical niobium-containing zeolites for synthesis of alkyl lactate and lactic acid.Significant Enhancement of Water Splitting Activity of N-Carbon Electrocatalyst by Trace Level Co Doping.Adsorption of Lead Ions from Aqueous Phase on Mesoporous Silica with P-Containing Pendant Groups.High Electrocatalytic Hydrogen Evolution Activity of an Anomalous Ruthenium Catalyst.Atomically and Electronically Coupled Pt and CoO Hybrid Nanocatalysts for Enhanced Electrocatalytic Performance.Hollow Carbon Nanospheres with Tunable Hierarchical Pores for Drug, Gene, and Photothermal Synergistic Treatment.Revisiting the Stӧber method: Design of nitrogen-doped porous carbon spheres from molecular precursors of different chemical structures.
P50
Q28821712-99663236-E082-4776-9DB0-C8B9CE100C36Q30576036-2A0CAB71-756D-481E-95F2-9941AE53F212Q33716006-CD422D9B-B240-4006-AAD8-35917041936EQ37281814-D9F15AA8-16FA-4E4B-9565-64737D330951Q37307229-5B54EB03-273E-4722-9AB6-6FAAB13C860BQ38178816-5DD20CA5-4C05-4EC9-98E9-B8254136FFD6Q38216858-9F4E17C0-2B96-4F18-874C-8D98CE824E28Q38351958-B4711807-25C2-4324-8247-3F4640C67359Q38364051-32CE6CCB-406C-4870-AFBB-F3A6F606B353Q38552256-86D660CB-3762-4418-9354-FD311C23C12CQ38604824-DE282B62-D59C-49F3-9A9B-A06C5D447D2FQ38755061-1D1CB8BB-D0A2-486C-B6E5-DD8CFB261382Q38766461-F52FD8D7-F31F-4911-9DDA-67CB659FA550Q38768662-BAAA3EE4-8639-43AE-A172-FB3DB5B70CD8Q38976874-4A86806E-D180-4206-8627-2E1BEC7C1B43Q39202913-232BA19F-CB1C-4BC5-B395-2A83ED247A6FQ39202931-87D81A60-FE6A-467A-8D44-721BC9C842B9Q42233172-DD3DAD64-08F7-4B09-A502-81A1F3925715Q43201965-2A1A8B78-C863-493F-B51A-12108F8D8C60Q43417202-BD499B85-9399-477A-B629-D82835EA328FQ44454811-11F059B3-33D9-462E-B26D-AC20C1D1697BQ45910164-31E9E64B-A666-4350-BB5C-AFA90DAED7D9Q46397741-D5017B39-EA0B-493E-814C-0E0FA8D901B7Q46843954-402000CB-01ED-4AF8-B1E3-035D966F6FBEQ46852308-E3A96EFD-F6D5-4726-9659-14A6EC546C88Q46870892-E1C0CFFD-BC65-48BB-A111-105E84209EEDQ47176580-6085C1F6-63A5-464A-8086-80B4EFD0F8B3Q47335798-E6CDD514-570F-4458-9A6D-D57DFC10C1B4Q47776750-373E8790-1E0C-4FBB-9177-488FA4FF137DQ48044840-4771E08F-FCBF-43FF-921E-43C378091CC2Q48063518-64C88D9D-6851-4896-8427-DE1DC97DE1BCQ48188828-0831AA87-BCEB-41E0-9726-9C63FDBC2CD9Q50046940-271F7E1F-7B16-4ED1-9B19-5029211D2F71Q50058713-3E702EDD-9CB1-4BE1-A0CE-101F49321580Q50635452-4B2436E9-B1E8-4E64-8BC8-35D2B86B9DCFQ50929879-83AC151F-D6D3-41B9-AB61-3A38821C2BA0Q51014049-C86225B5-EFF6-4D13-9DE1-429B7FAE8498Q51065897-919F26F3-1393-4314-A893-91B8AE7BAC43Q51098199-027BFAAD-731E-40D6-9613-74309615BE85Q51323431-D3192969-2412-449A-9528-8E5919488FC1
P50
description
researcher
@en
wetenschapper
@nl
հետազոտող
@hy
name
Mietek Jaroniec
@ast
Mietek Jaroniec
@en
Mietek Jaroniec
@es
Mietek Jaroniec
@nl
type
label
Mietek Jaroniec
@ast
Mietek Jaroniec
@en
Mietek Jaroniec
@es
Mietek Jaroniec
@nl
prefLabel
Mietek Jaroniec
@ast
Mietek Jaroniec
@en
Mietek Jaroniec
@es
Mietek Jaroniec
@nl
P106
P31
P496
0000-0002-1178-5611