about
Hybrid solution-processed bulk heterojunction solar cells based on bismuth sulfide nanocrystals.Alkynyldiphenylphosphine d8 (Pt, Rh, Ir) complexes: contrasting behavior toward cis-[Pt(C6F5)2(THF)2].Dendrimer-encapsulated Pd nanoparticles versus palladium acetate as catalytic precursors in the stille reaction in water.Remote trap passivation in colloidal quantum dot bulk nano-heterojunctions and its effect in solution-processed solar cells.Octahedral Alkynylphosphine Ruthenium(II) Complexes: Synthesis, Structure, and ElectrochemistryResearch Update: Bismuth based materials for photovoltaicsSolution-processed solar cells based on environmentally friendly AgBiS2 nanocrystalsInterface Engineering in Hybrid Quantum Dot–2D PhototransistorsSize and bandgap tunability in Bi2S3 colloidal nanocrystals and its effect in solution processed solar cellsSolution Processed Bismuth Sulfide Nanowire Array Core/Silver Sulfide Shell Solar CellsTailoring the Electronic Properties of Colloidal Quantum Dots in Metal-Semiconductor Nanocomposites for High Performance PhotodetectorsDetermination of carrier lifetime and mobility in colloidal quantum dot films via impedance spectroscopyImproved electronic coupling in hybrid organic–inorganic nanocomposites employing thiol-functionalized P3HT and bismuth sulfide nanocrystalsCoupling Resonant Modes of Embedded Dielectric Microspheres in Solution-Processed Solar CellsMicroresonators: Coupling Resonant Modes of Embedded Dielectric Microspheres in Solution-Processed Solar Cells (Advanced Optical Materials 2/2013)Size- and Temperature-Dependent Carrier Dynamics in Oleic Acid Capped PbS Quantum DotsSpectroscopic evidence of resonance energy transfer mechanism from PbS QDs to bulk siliconElectrical effects of metal nanoparticles embedded in ultra-thin colloidal quantum dot filmsHybrid graphene–quantum dot phototransistors with ultrahigh gainPlasmonic light trapping leads to responsivity increase in colloidal quantum dot photodetectorsResonance energy transfer from PbS colloidal quantum dots to bulk silicon: the road to hybrid photovoltaicsSolution-processed inorganic bulk nano-heterojunctions and their application to solar cellsNear IR-Sensitive, Non-toxic, Polymer/Nanocrystal Solar Cells Employing Bi2S3 as the Electron AcceptorSolution-Processed Heterojunction Solar Cells Based on p-type PbS Quantum Dots and n-type Bi2S3 NanocrystalsSynthesis of Core−Shell PtRu Dendrimer-Encapsulated Nanoparticles. Relevance as Electrocatalysts for CO OxidationFacile Single or Double C−H Bond Activation on a Cp* Ligand Promoted by the Presence of Alkynylphosphine LigandsC–H and P–C(Ph) activation competitive processes caused by interaction with the solvate [cis-Pt(C6F5)2(thf)2]Rearrangement or C−H Activation Processes Promoted by Reaction with the Solvate [cis-Pt(C6F5)2(thf)2]Six-Coordinate Alkynyldiphenylphosphine Ruthenium(II) Complexes: Synthesis, Structure, and Catalytic Activity as ROMP InitiatorsFacile Single or Double C−H Bond Activation on η2-Platinum-Complexed Acetylenes by Interaction with [cis-PtR2S2] and [cis-PtR2(CO)S] (R = C6F5, S = Thf)(p-cymene)Ruthenium(II)(diphenylphosphino)alkyne Complexes: Preparation of (μ-Cl)(μ-PPh2C⋮CR)-Bridged Ru/Pt Heterobimetallic ComplexesDiphenyl(phenylethynyl)phosphine d6[Rh(III), Ir(III), Ru(II)] Complexes: Preparation of Homo (μ-Cl)2and Hetero (μ-Cl)(μ-PPh2C⋮CPh) Bridged d6−d8Compounds
P50
Q44601162-36DBC970-B346-4147-B8CE-F2491857D308Q45172882-170C2515-306B-493F-968C-CD808D4E13C3Q46058639-0D31F3B7-3DA9-4428-94E0-888A4A78B68FQ53277356-76C0FF26-31AF-48FB-A5F3-B88C8E0C69F3Q58795196-E1FE3CEA-00E0-487D-8D93-2A2E89D45030Q58832139-ACB441B2-B8E5-4755-BFF0-1AADC70A9F21Q58832140-849FBB2E-B5F1-4D42-B8B3-92B20F0A8AAFQ58832143-03A9BC56-1EB9-4385-9B9C-13534BB0440CQ58832147-4CEC1D84-C07B-4CBA-86E5-7EC65AF438BAQ58832150-C3EA6AEE-2497-4CBC-9F9C-40E0E0F2E90AQ58832153-12AADDF3-0E05-4AC4-9C67-9F725CCB5BF7Q58832155-95CB8996-72D1-4E0C-8912-AB3017FDD3B1Q58832157-8F965B69-A3B0-4025-9570-5E35AFDB2626Q58832159-684FC480-5EF4-400A-ACA6-0B71A3330D0BQ58832163-7494BC1B-F826-46E4-9DFE-11F09654A2EBQ58832165-DAA5544A-B43D-42ED-81C1-10B92E63BD68Q58832167-BD427B4C-D332-47DF-9A21-BA92BDFDF782Q58832169-E6DCE565-D48A-42B0-A5A4-A81F29BEFDB2Q58832171-0079364D-1B73-4D93-BDEA-4D28EAD58AE5Q58832173-BFAABC41-02CB-4B93-A1BA-E424F487FDE4Q58832174-E58A0837-EEF3-46FB-9902-47E8B37320FEQ58832176-A58640AF-751B-454B-9917-4B8DB89DF13CQ58832178-855BC402-B0EF-4961-B83C-C99CE4B3F324Q58832179-C12C56F6-E133-4EA9-9350-298CBE50FB4AQ58832181-DD8010C5-31DA-4B90-99C6-59597C6CE6F3Q58832185-517959A5-BFC8-4ABB-8532-93DFE6606C01Q58832187-195541F6-A6DC-4929-94DB-4A6A90DA02B3Q58832190-83ABC92D-F2BD-4EDD-9F0A-9245A894604BQ58832193-C9690294-B725-4E99-AC48-826822D63042Q58832195-01DD372E-E737-434D-B63A-82592E1E1AC9Q58832197-7A4C7D0E-DDAD-4CD2-9B75-5DA42B33D4B6Q58832202-E3808E83-AE72-408C-8BCC-BA73263F8487
P50
description
researcher ORCID ID = 0000-0003-2800-6845
@en
wetenschapper
@nl
name
Maria Bernechea
@ast
Maria Bernechea
@en
Maria Bernechea
@es
Maria Bernechea
@nl
type
label
Maria Bernechea
@ast
Maria Bernechea
@en
Maria Bernechea
@es
Maria Bernechea
@nl
altLabel
María Bernechea Navarro
@en
prefLabel
Maria Bernechea
@ast
Maria Bernechea
@en
Maria Bernechea
@es
Maria Bernechea
@nl
P1053
B-3916-2010
P106
P1153
6507183358
P21
P31
P3829
P3835
maria-bernechea
P496
0000-0003-2800-6845