Publicaciones en las que colabora con MICHELE SESSOLO - (27)

2023

  1. Chalcohalide Antiperovskite Thin Films with Visible Light Absorption and High Charge-Carrier Mobility Processed by Solvent-Free and Low-Temperature Methods

    Chemistry of Materials, Vol. 35, Núm. 16, pp. 6482-6490

  2. Implementing Mesoporosity in Zeolitic Imidazolate Frameworks through Clip-Off Chemistry in Heterometallic Iron-Zinc ZIF-8

    Journal of the American Chemical Society, Vol. 145, Núm. 42, pp. 23249-23256

2021

  1. Tuning the Optical Absorption of Sn-, Ge-, and Zn-Substituted Cs2AgBiBr6Double Perovskites: Structural and Electronic Effects

    Chemistry of Materials, Vol. 33, Núm. 20, pp. 8028-8035

2020

  1. Remote Modification of Bidentate Phosphane Ligands Controlling the Photonic Properties in Their Complexes: Enhanced Performance of [Cu(RN-xantphos)(N^N)][PF6] in Light-Emitting Electrochemical Cells

    Advanced Optical Materials, Vol. 8, Núm. 10

  2. The shiny side of copper: Bringing copper(i) light-emitting electrochemical cells closer to application

    RSC Advances, Vol. 10, Núm. 38, pp. 22631-22644

2019

  1. Phosphane tuning in heteroleptic [Cu(N^N)(P^P)] + complexes for light-emitting electrochemical cells

    Dalton Transactions, Vol. 48, Núm. 2, pp. 446-460

  2. Phosphomolybdic acid as an efficient hole injection material in perovskite optoelectronic devices

    Dalton Transactions, Vol. 48, Núm. 1, pp. 30-34

2018

  1. Exploring the effect of the cyclometallating ligand in 2-(pyridine-2-yl)benzo[: D] thiazole-containing iridium(iii) complexes for stable light-emitting electrochemical cells

    Journal of Materials Chemistry C, Vol. 6, Núm. 46, pp. 12679-12688

  2. Fully Vacuum-Processed Wide Band Gap Mixed-Halide Perovskite Solar Cells

    ACS Energy Letters, Vol. 3, Núm. 1, pp. 214-219

  3. High voltage vacuum-deposited CH3NH3PbI3-CH3NH3PbI3 tandem solar cells

    Energy and Environmental Science, Vol. 11, Núm. 11, pp. 3292-3297

  4. Luminescent copper(i) complexes with bisphosphane and halogen-substituted 2,2′-bipyridine ligands

    Dalton Transactions, Vol. 47, Núm. 40, pp. 14263-14276

  5. Vacuum Deposited Triple-Cation Mixed-Halide Perovskite Solar Cells

    Advanced Energy Materials, Vol. 8, Núm. 14

  6. [Cu(P^P)(N^N)][PF6] compounds with bis(phosphane) and 6-alkoxy, 6-alkylthio, 6-phenyloxy and 6-phenylthio-substituted 2,2′-bipyridine ligands for light-emitting electrochemical cells

    Journal of Materials Chemistry C, Vol. 6, Núm. 31, pp. 8460-8471

2017

  1. Efficient Monolithic Perovskite/Perovskite Tandem Solar Cells

    Advanced Energy Materials, Vol. 7, Núm. 8

  2. Efficient wide band gap double cation-double halide perovskite solar cells

    Journal of Materials Chemistry A, Vol. 5, Núm. 7, pp. 3203-3207

  3. Recombination in Perovskite Solar Cells: Significance of Grain Boundaries, Interface Traps, and Defect Ions

    ACS Energy Letters, Vol. 2, Núm. 5, pp. 1214-1222

  4. Removing Leakage and Surface Recombination in Planar Perovskite Solar Cells

    ACS Energy Letters, Vol. 2, Núm. 2, pp. 424-430

  5. Vacuum deposited perovskite solar cells employing dopant-free triazatruxene as the hole transport material

    Solar Energy Materials and Solar Cells, Vol. 163, pp. 237-241

  6. Vapor-Deposited Perovskites: The Route to High-Performance Solar Cell Production?

    Joule, Vol. 1, Núm. 3, pp. 431-442

2016

  1. Efficient vacuum deposited p-i-n and n-i-p perovskite solar cells employing doped charge transport layers

    Energy and Environmental Science, Vol. 9, Núm. 11, pp. 3456-3463