Publications
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21
Wen Y., Zhang T., Wang Y., et al, “Amorphous (lysine)2PbI2 layer enhanced perovskite photovoltaics“, Nature Communications, 15, 1, 7085 (2024).
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20
Wu C., Olivati A., Petrozza A., et al, “Thin Film Stoichiometry and Defects Management for Low Threshold and Air Stable Near‐Infrared Perovskite Laser“, Advanced Materials, 2407652 (2024).
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19
Rojas-Gatjens E., Tiede D. O., Kandada A. R. S., et al, “Exciton-carrier coupling in a metal halide perovskite nanocrystal assembly probed by two-dimensional coherent spectroscopy“, Journal of Physics: Materials, 7 025002 (2024).
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18
Justin I. A. K., Tiede D. O., Bolink H. J., et al, “Strong Grain Boundary Passivation Effect of Coevaporated Dopants Enhances the Photoemission of Lead Halide Perovskites“, ACS Applied Materials & Interfaces, 16, 44, 61305–61313 (2024).
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17
Morán-Pedroso M., Tiede D. O., Romero-Pérez C., et al, “Interplay between connectivity and passivating agents in perovskite quantum dot networks“, Journal of Materials Chemistry C, 41 (2024).
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16
Tiede D. O., Koch K. A., Kandada A. R. S., et al, “Role of Inter‐Particle Connectivity in the Photo‐Carrier Cooling Dynamics in Perovskite Quantum Dot Solids“, Advanced Optical Materials, 12, 31 2401483 (2024).
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15
Bujalance C., Caliò L., Dirin D. N., Tiede D. O., et al, “Strong Light–Matter Coupling in Lead Halide Perovskite Quantum Dot Solids“, ACS Nano, 18, 6, 4922–4931 (2024).
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14
Tiede D. O., Romero-Pérez c., Koch K. A., et al, “Effect of Connectivity on the Carrier Transport and Recombination Dynamics of Perovskite Quantum-Dot Networks“, ACS Nano, 18, 3, 2325–2334 (2024).
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13
Yuan F., Petrozza A., et al, “Bright and stable near-infrared lead-free perovskite light-emitting diodes“, Nature Photonics, 18, 170–176 (2024).
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12
Oddi V., Zhu C., Becker M. A., et al, “Circularly Polarized Luminescence Without External Magnetic Fields from Individual CsPbBr“, ACS Nano, 18, 26, 17218–17227 (2024).
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11
Fan X., Wang Y., Shen X., et al, “Phosphine oxide modulator-ameliorated hole injection for blue perovskite light-emitting diodes“, Journal of Materials Chemistry A, 11, 20808-20815 (2023).
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10
Mihalyi-Koch W., Folpini G., Roy C. R., Kaiser W., Wu C., et al, “Tuning Structure and Excitonic Properties of 2D Ruddlesden–Popper Germanium, Tin, and Lead Iodide Perovskites via Interplay between Cations“, Journal of the American Chemical Society, 145, 51, 28111–28123 (2023).
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9
Aktas E., Poli I., Ponti C., Olivati A., et al, “One-Step Solution Deposition of Tin-Perovskite onto a Self-Assembled Monolayer with a DMSO-Free Solvent System“, ACS Energy Letters, 8, 12, 5170–5174 (2023).
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8
Liu A., Zhu H., Bai S., Reo Y., Caironi M., Petrozza A., et al, “High-performance metal halide perovskite transistors“, Nature Electronics, 6, 559–571 (2023).
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7
Berger F. J., Poli I., Aktas E., et al, “How Halide Alloying Influences the Optoelectronic Quality in Tin-Halide Perovskite Solar Absorbers“, ACS Energy Letters, 8, 9, 3876–3882 (2023).
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6
Jiménez‐López J., Cortecchia D., et al, “Carrier Trapping Deactivation by Halide Alloying in Formamidinium‐Based Lead Iodide Perovskites“, Advanced Functional Materials, 34, 50 2308545 (2023).
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5
Martani S., Zhou Y., Aktas E., et al, “Defect Engineering to Achieve Photostable Wide Bandgap Metal Halide Perovskites“, ACS Energy Letters, 8, 6, 2801–2808 (2023).
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4
Ye K., Klaver Y., Jimenez Gordillo O. A. et al, “Brillouin and Kerr nonlinearities of a low-index silicon oxynitride platform“, APL Photonics, 8, 051302 (2023).
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3
Soci C., Adamo G., Cortecchia D., et al, “Roadmap on perovskite nanophotonics“, Optical Materials: X, (2022).
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2
Aktas E., Rajamanickam, N. et al “Challenges and strategies toward long-term stability of lead-free tin-based perovskite solar cells“ , Communications Materials, 3, Article number: 104, 2662-4443 (2022).
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1
Girolamo D. di, Aktas E. et al, “Enabling water-free PEDOT as hole selective layer in lead-free tin perovskite solar cells“ , The Royal Society of Chemistry - Mater. Adv. 3, 9083-9089 (2022).