Publicaciones (69) Publicaciones de CRISTINA ROLDAN CARMONA

2024

  1. Close-Space Sublimation as a Scalable Method for Perovskite Solar Cells

    ACS Energy Letters, Vol. 9, Núm. 3, pp. 927-933

  2. Stabilizing Single-Source Evaporated Perovskites with Organic Interlayers for Amplified Spontaneous Emission

    Advanced Optical Materials, Vol. 12, Núm. 13

  3. Vacuum-Deposited Bifacial Perovskite Solar Cells

    ACS Energy Letters, Vol. 9, Núm. 9, pp. 4587-4595

  4. When JV Curves Conceal Material Improvements: The Relevance of Photoluminescence Measurements in the Optimization of Perovskite Solar Cells

    Advanced Optical Materials, Vol. 12, Núm. 8

2023

  1. Fast Coevaporation of 1 μm Thick Perovskite Solar Cells

    ACS Energy Letters, Vol. 8, Núm. 11, pp. 4711-4713

  2. Fully vacuum-deposited perovskite solar cells in substrate configuration

    Matter, Vol. 6, Núm. 10, pp. 3499-3508

  3. Multimodal photodetectors with vacuum deposited perovskite bilayers

    Journal of Materials Chemistry C, Vol. 11, Núm. 4, pp. 1258-1264

  4. Pure Iodide Multication Wide Bandgap Perovskites by Vacuum Deposition

    ACS Materials Letters, Vol. 5, Núm. 12, pp. 3299-3305

  5. Tunable p- and n-Type Tellurium-Free Mg3Bi2 Thermoelectric Thin Films by Thermal Coevaporation

    ACS Applied Energy Materials, Vol. 6, Núm. 20, pp. 10327-10332

2022

  1. C60 Thin Films in Perovskite Solar Cells: Efficient or Limiting Charge Transport Layer?

    ACS Applied Energy Materials, Vol. 5, Núm. 2, pp. 1646-1655

  2. Efficient Semitransparent Perovskite Solar Cells Based on Thin Compact Vacuum Deposited CH3NH3PbI3 Films

    Advanced Materials Interfaces, Vol. 9, Núm. 29

  3. Perovskite/Perovskite Tandem Solar Cells in the Substrate Configuration with Potential for Bifacial Operation

    ACS Materials Letters, Vol. 4, Núm. 12, pp. 2638-2644

2021

  1. Cation optimization forburn-in loss-freeperovskite solar devices

    Journal of Materials Chemistry A, Vol. 9, Núm. 9, pp. 5374-5380

  2. Crystallographically Oriented Hybrid Perovskites via Thermal Vacuum Codeposition

    Solar RRL, Vol. 5, Núm. 8

  3. Erratum: Cation optimization for: Burn-in loss-free perovskite solar devices: (J. Mater. Chem. A (2021) 9 (5374-5380) DOI: 10.1039/D1TA00472G)

    Journal of Materials Chemistry A

  4. Interfacial passivation of wide-bandgap perovskite solar cells and tandem solar cells

    Journal of Materials Chemistry A, Vol. 9, Núm. 38, pp. 21939-21947

  5. Mechanistic Insights into the Role of the Bis(trifluoromethanesulfonyl)imide Ion in Coevaporated p-i-n Perovskite Solar Cells

    ACS Applied Materials and Interfaces, Vol. 13, Núm. 44, pp. 52450-52460

2020

  1. An Efficient Approach to Fabricate Air-Stable Perovskite Solar Cells via Addition of a Self-Polymerizing Ionic Liquid

    Advanced Materials, Vol. 32, Núm. 40

  2. Applications of Self-Assembled Monolayers for Perovskite Solar Cells Interface Engineering to Address Efficiency and Stability

    Advanced Energy Materials, Vol. 10, Núm. 48

  3. Azatruxene-Based, Dumbbell-Shaped, Donor–π-Bridge–Donor Hole-Transporting Materials for Perovskite Solar Cells

    Chemistry - A European Journal, Vol. 26, Núm. 48, pp. 11039-11047