Your search keyword '"Oliver, Robert D. J."' showing total 14 results

1. Bandgap-universal passivation enables stable perovskite solar cells with low photovoltage loss.

Author

Lin YH, Vikram, Yang F, Cao XL, Dasgupta A, Oliver RDJ, Ulatowski AM, McCarthy MM, Shen X, Yuan Q, Christoforo MG, Yeung FSY, Johnston MB, Noel NK, Herz LM, Islam MS, and Snaith HJ

Abstract

The efficiency and longevity of metal-halide perovskite solar cells are typically dictated by nonradiative defect-mediated charge recombination. In this work, we demonstrate a vapor-based amino-silane passivation that reduces photovoltage deficits to around 100 millivolts (>90% of the thermodynamic limit) in perovskite solar cells of bandgaps between 1.6 and 1.8 electron volts, which is crucial for tandem applications. A primary-, secondary-, or tertiary-amino-silane alone negatively or barely affected perovskite crystallinity and charge transport, but amino-silanes that incorporate primary and secondary amines yield up to a 60-fold increase in photoluminescence quantum yield and preserve long-range conduction. Amino-silane-treated devices retained 95% power conversion efficiency for more than 1500 hours under full-spectrum sunlight at 85°C and open-circuit conditions in ambient air with a relative humidity of 50 to 60%.

Published

2024

2. Strong coupling in molecular systems: a simple predictor employing routine optical measurements.

Author

Rider MS, Johnson EC, Bates D, Wardley WP, Gordon RH, Oliver RDJ, Armes SP, Leggett GJ, and Barnes WL

Abstract

We provide a simple method that enables readily acquired experimental data to be used to predict whether or not a candidate molecular material may exhibit strong coupling. Specifically, we explore the relationship between the hybrid molecular/photonic (polaritonic) states and the bulk optical response of the molecular material. For a given material, this approach enables a prediction of the maximum extent of strong coupling (vacuum Rabi splitting), irrespective of the nature of the confined light field. We provide formulae for the upper limit of the splitting in terms of the molar absorption coefficient, the attenuation coefficient, the extinction coefficient (imaginary part of the refractive index) and the absorbance. To illustrate this approach, we provide a number of examples, and we also discuss some of the limitations of our approach., Competing Interests: Conflict of interest: Authors state no conflicts of interest., (© 2024 the author(s), published by De Gruyter, Berlin/Boston.)

Published

2024

3. Synergistic Surface Modification of Tin-Lead Perovskite Solar Cells.

Author

Hu S, Zhao P, Nakano K, Oliver RDJ, Pascual J, Smith JA, Yamada T, Truong MA, Murdey R, Shioya N, Hasegawa T, Ehara M, Johnston MB, Tajima K, Kanemitsu Y, Snaith HJ, and Wakamiya A

Abstract

Interfaces in thin-film photovoltaics play a pivotal role in determining device efficiency and longevity. In this work, the top surface treatment of mixed tin-lead (≈1.26 eV) halide perovskite films for p-i-n solar cells is studied. Charge extraction is promoted by treating the perovskite surface with piperazine. This compound reacts with the organic cations at the perovskite surface, modifying the surface structure and tuning the interfacial energy level alignment. In addition, the combined treatment with C 60 pyrrolidine tris-acid (CPTA) reduces hysteresis and leads to efficiencies up to 22.7%, with open-circuit voltage values reaching 0.90 V, ≈92% of the radiative limit for the bandgap of this material. The modified cells also show superior stability, with unencapsulated cells retaining 96% of their initial efficiency after >2000 h of storage in N 2 and encapsulated cells retaining 90% efficiency after >450 h of storage in air. Intriguingly, CPTA preferentially binds to Sn 2+ sites at film surface over Pb 2+ due to the energetically favored exposure of the former, according to first-principles calculations. This work provides new insights into the surface chemistry of perovskite films in terms of their structural, electronic, and defect characteristics and this knowledge is used to fabricate state-of-the-art solar cells., (© 2023 Wiley-VCH GmbH.)

Published

2023

4. Open-circuit and short-circuit loss management in wide-gap perovskite p-i-n solar cells.

Author

Caprioglio P, Smith JA, Oliver RDJ, Dasgupta A, Choudhary S, Farrar MD, Ramadan AJ, Lin YH, Christoforo MG, Ball JM, Diekmann J, Thiesbrummel J, Zaininger KA, Shen X, Johnston MB, Neher D, Stolterfoht M, and Snaith HJ

Abstract

In this work, we couple theoretical and experimental approaches to understand and reduce the losses of wide bandgap Br-rich perovskite pin devices at open-circuit voltage (V OC ) and short-circuit current (J SC ) conditions. A mismatch between the internal quasi-Fermi level splitting (QFLS) and the external V OC is detrimental for these devices. We demonstrate that modifying the perovskite top-surface with guanidinium-Br and imidazolium-Br forms a low-dimensional perovskite phase at the n-interface, suppressing the QFLS-V OC mismatch, and boosting the V OC . Concurrently, the use of an ionic interlayer or a self-assembled monolayer at the p-interface reduces the inferred field screening induced by mobile ions at J SC , promoting charge extraction and raising the J SC . The combination of the n- and p-type optimizations allows us to approach the thermodynamic potential of the perovskite absorber layer, resulting in 1 cm 2 devices with performance parameters of V OC s up to 1.29 V, fill factors above 80% and J SC s up to 17 mA/cm 2 , in addition to a thermal stability T 80  lifetime of more than 3500 h at 85 °C., (© 2023. The Author(s).)

Published

2023

5. A Universal Perovskite Nanocrystal Ink for High-Performance Optoelectronic Devices.

Author

Song H, Yang J, Jeong WH, Lee J, Lee TH, Yoon JW, Lee H, Ramadan AJ, Oliver RDJ, Cho SC, Lim SG, Jang JW, Yu Z, Oh JT, Jung ED, Song MH, Park SH, Durrant JR, Snaith HJ, Lee SU, Lee BR, and Choi H

Abstract

Semiconducting lead halide perovskite nanocrystals (PNCs) are regarded as promising candidates for next-generation optoelectronic devices due to their solution processability and outstanding optoelectronic properties. While the field of light-emitting diodes (LEDs) and photovoltaics (PVs), two prime examples of optoelectronic devices, has recently seen a multitude of efforts toward high-performance PNC-based devices, realizing both devices with high efficiencies and stabilities through a single PNC processing strategy has remained a challenge.  In this work, diphenylpropylammonium (DPAI) surface ligands, found through a judicious ab-initio-based ligand search, are shown to provide a solution to this problem. The universal PNC ink with DPAI ligands presented here, prepared through a solution-phase ligand-exchange process, simultaneously allows single-step processed LED and PV devices with peak electroluminescence external quantum efficiency of 17.00% and power conversion efficiency of 14.92% (stabilized output 14.00%), respectively. It is revealed that a careful design of the aromatic rings such as in DPAI is the decisive factor in bestowing such high performances, ease of solution processing, and improved phase stability up to 120 days. This work illustrates the power of ligand design in producing PNC ink formulations for high-throughput production of optoelectronic devices; it also paves a path for "dual-mode" devices with both PV and LED functionalities., (© 2022 Wiley-VCH GmbH.)

Published

2023

6. Thermally Stable Perovskite Solar Cells by All-Vacuum Deposition.

Author

Yuan Q, Lohmann KB, Oliver RDJ, Ramadan AJ, Yan S, Ball JM, Christoforo MG, Noel NK, Snaith HJ, Herz LM, and Johnston MB

Abstract

Vacuum deposition is a solvent-free method suitable for growing thin films of metal halide perovskite (MHP) semiconductors. However, most reports of high-efficiency solar cells based on such vacuum-deposited MHP films incorporate solution-processed hole transport layers (HTLs), thereby complicating prospects of industrial upscaling and potentially affecting the overall device stability. In this work, we investigate organometallic copper phthalocyanine (CuPc) and zinc phthalocyanine (ZnPc) as alternative, low-cost, and durable HTLs in all-vacuum-deposited solvent-free formamidinium-cesium lead triodide [CH(NH 2 ) 2 ] 0.83 Cs 0.17 PbI 3 (FACsPbI 3 ) perovskite solar cells. We elucidate that the CuPc HTL, when employed in an "inverted" p-i-n solar cell configuration, attains a solar-to-electrical power conversion efficiency of up to 13.9%. Importantly, unencapsulated devices as large as 1 cm 2 exhibited excellent long-term stability, demonstrating no observable degradation in efficiency after more than 5000 h in storage and 3700 h under 85 °C thermal stressing in N 2 atmosphere.

Published

2023

7. Solvent-Free Method for Defect Reduction and Improved Performance of p-i-n Vapor-Deposited Perovskite Solar Cells.

Author

Lohmann KB, Motti SG, Oliver RDJ, Ramadan AJ, Sansom HC, Yuan Q, Elmestekawy KA, Patel JB, Ball JM, Herz LM, Snaith HJ, and Johnston MB

Abstract

As perovskite-based photovoltaics near commercialization, it is imperative to develop industrial-scale defect-passivation techniques. Vapor deposition is a solvent-free fabrication technique that is widely implemented in industry and can be used to fabricate metal-halide perovskite thin films. We demonstrate markably improved growth and optoelectronic properties for vapor-deposited [CH(NH 2 ) 2 ] 0.83 Cs 0.17 PbI 3 perovskite solar cells by partially substituting PbI 2 for PbCl 2 as the inorganic precursor. We find the partial substitution of PbI 2 for PbCl 2 enhances photoluminescence lifetimes from 5.6 ns to over 100 ns, photoluminescence quantum yields by more than an order of magnitude, and charge-carrier mobility from 46 cm 2 /(V s) to 56 cm 2 /(V s). This results in improved solar-cell power conversion efficiency, from 16.4% to 19.3% for the devices employing perovskite films deposited with 20% substitution of PbI 2 for PbCl 2 . Our method presents a scalable, dry, and solvent-free route to reducing nonradiative recombination centers and hence improving the performance of vapor-deposited metal-halide perovskite solar cells., Competing Interests: The authors declare the following competing financial interest(s): H.J.S. is a cofounder and CSO of Oxford PV Ltd, a company commercializing perovskite PV technology., (© 2022 The Authors. Published by American Chemical Society.)

Published

2022

8. Scalable processing for realizing 21.7%-efficient all-perovskite tandem solar modules.

Author

Xiao K, Lin YH, Zhang M, Oliver RDJ, Wang X, Liu Z, Luo X, Li J, Lai D, Luo H, Lin R, Xu J, Hou Y, Snaith HJ, and Tan H

Abstract

Challenges in fabricating all-perovskite tandem solar cells as modules rather than as single-junction configurations include growing high-quality wide-bandgap perovskites and mitigating irreversible degradation caused by halide and metal interdiffusion at the interconnecting contacts. We demonstrate efficient all-perovskite tandem solar modules using scalable fabrication techniques. By systematically tuning the cesium ratio of a methylammonium-free 1.8-electron volt mixed-halide perovskite, we improve the homogeneity of crystallization for blade-coated films over large areas. An electrically conductive conformal "diffusion barrier" is introduced between interconnecting subcells to improve the power conversion efficiency (PCE) and stability of all-perovskite tandem solar modules. Our tandem modules achieve a certified PCE of 21.7% with an aperture area of 20 square centimeters and retain 75% of their initial efficiency after 500 hours of continuous operation under simulated 1-sun illumination.

Published

2022

9. Optoelectronic Properties of Mixed Iodide-Bromide Perovskites from First-Principles Computational Modeling and Experiment.

Author

Chen Y, Motti SG, Oliver RDJ, Wright AD, Snaith HJ, Johnston MB, Herz LM, and Filip MR

Abstract

Halogen mixing in lead-halide perovskites is an effective route for tuning the band gap in light emission and multijunction solar cell applications. Here we report the effect of halogen mixing on the optoelectronic properties of lead-halide perovskites from theory and experiment. We applied the virtual crystal approximation within density functional theory, the GW approximation, and the Bethe-Salpeter equation to calculate structural, vibrational, and optoelectronic properties for a series of mixed halide perovskites. We separately perform spectroscopic measurements of these properties and analyze the impact of halogen mixing on quasiparticle band gaps, effective masses, absorption coefficients, charge-carrier mobilities, and exciton binding energies. Our joint theoretical-experimental study demonstrates that iodide-bromide mixed-halide perovskites can be modeled as homovalent alloys, and local structural distortions do not play a significant role for the properties of these mixed species. Our study outlines a general theoretical-experimental framework for future investigations of novel chemically mixed systems.

Published

2022

10. Phase segregation in mixed-halide perovskites affects charge-carrier dynamics while preserving mobility.

Author

Motti SG, Patel JB, Oliver RDJ, Snaith HJ, Johnston MB, and Herz LM

Abstract

Mixed halide perovskites can provide optimal bandgaps for tandem solar cells which are key to improved cost-efficiencies, but can still suffer from detrimental illumination-induced phase segregation. Here we employ optical-pump terahertz-probe spectroscopy to investigate the impact of halide segregation on the charge-carrier dynamics and transport properties of mixed halide perovskite films. We reveal that, surprisingly, halide segregation results in negligible impact to the THz charge-carrier mobilities, and that charge carriers within the I-rich phase are not strongly localised. We further demonstrate enhanced lattice anharmonicity in the segregated I-rich domains, which is likely to support ionic migration. These phonon anharmonicity effects also serve as evidence of a remarkably fast, picosecond charge funnelling into the narrow-bandgap I-rich domains. Our analysis demonstrates how minimal structural transformations during phase segregation have a dramatic effect on the charge-carrier dynamics as a result of charge funnelling. We suggest that because such enhanced recombination is radiative, performance losses may be mitigated by deployment of careful light management strategies in solar cells., (© 2021. The Author(s).)

Published

2021

11. Halide Segregation in Mixed-Halide Perovskites: Influence of A-Site Cations.

Author

Knight AJ, Borchert J, Oliver RDJ, Patel JB, Radaelli PG, Snaith HJ, Johnston MB, and Herz LM

Abstract

Mixed-halide perovskites offer bandgap tunability essential for multijunction solar cells; however, a detrimental halide segregation under light is often observed. Here we combine simultaneous in situ photoluminescence and X-ray diffraction measurements to demonstrate clear differences in compositional and optoelectronic changes associated with halide segregation in MAPb(Br 0.5 I 0.5 ) 3 and FA 0.83 Cs 0.17 Pb(Br 0.4 I 0.6 ) 3 films. We report evidence for low-barrier ionic pathways in MAPb(Br 0.5 I 0.5 ) 3 , which allow for the rearrangement of halide ions in localized volumes of perovskite without significant compositional changes to the bulk material. In contrast, FA 0.83 Cs 0.17 Pb(Br 0.4 I 0.6 ) 3 lacks such low-barrier ionic pathways and is, consequently, more stable against halide segregation. However, under prolonged illumination, it exhibits a considerable ionic rearrangement throughout the bulk material, which may be triggered by an initial demixing of A-site cations, altering the composition of the bulk perovskite and reducing its stability against halide segregation. Our work elucidates links between composition, ionic pathways, and halide segregation, and it facilitates the future engineering of phase-stable mixed-halide perovskites., Competing Interests: The authors declare no competing financial interest., (© 2021 The Authors. Published by American Chemical Society.)

Published

2021

12. Revealing Factors Influencing the Operational Stability of Perovskite Light-Emitting Diodes.

Author

Warby JH, Wenger B, Ramadan AJ, Oliver RDJ, Sansom HC, Marshall AR, and Snaith HJ

Abstract

Light-emitting diodes (LEDs) made from metal halide perovskites have demonstrated external electroluminescent quantum efficiencies (EQE EL ) in excess of 20%. However, their poor operational stability, resulting in lifetimes of only tens to hundreds of hours, needs to be dramatically improved prior to commercial use. There is little consensus in the community upon which factors limit the stability of these devices. Here, we investigate the role played by ammonium cations on the operational stability. We vary the amount of phenylethylammonium bromide, a widely used alkylammonium salt, that we add to a precursor solution of CsPbBr 3 and track changes in stability and EQE EL . We find that while phenylethylammonium bromide is beneficial in achieving high efficiency, it is highly detrimental to operational stability. We investigate material properties and electronic characteristics before and after degradation and find that both a reduction in the radiative efficiency of the emitter and significant changes in current-voltage characteristics explain the orders of magnitude drop in the EQE EL , which we attribute to increased ionic mobility. Our results suggest that engineering new contacts and further investigation into materials with lower ionic mobility should yield much improved stability of perovskite LEDs.

Published

2020

13. A piperidinium salt stabilizes efficient metal-halide perovskite solar cells.

Author

Lin YH, Sakai N, Da P, Wu J, Sansom HC, Ramadan AJ, Mahesh S, Liu J, Oliver RDJ, Lim J, Aspitarte L, Sharma K, Madhu PK, Morales-Vilches AB, Nayak PK, Bai S, Gao F, Grovenor CRM, Johnston MB, Labram JG, Durrant JR, Ball JM, Wenger B, Stannowski B, and Snaith HJ

Abstract

Longevity has been a long-standing concern for hybrid perovskite photovoltaics. We demonstrate high-resilience positive-intrinsic-negative perovskite solar cells by incorporating a piperidinium-based ionic compound into the formamidinium-cesium lead-trihalide perovskite absorber. With the bandgap tuned to be well suited for perovskite-on-silicon tandem cells, this piperidinium additive enhances the open-circuit voltage and cell efficiency. This additive also retards compositional segregation into impurity phases and pinhole formation in the perovskite absorber layer during aggressive aging. Under full-spectrum simulated sunlight in ambient atmosphere, our unencapsulated and encapsulated cells retain 80 and 95% of their peak and post-burn-in efficiencies for 1010 and 1200 hours at 60° and 85°C, respectively. Our analysis reveals detailed degradation routes that contribute to the failure of aged cells., (Copyright © 2020, American Association for the Advancement of Science.)

Published

2020

14. Control over Crystal Size in Vapor Deposited Metal-Halide Perovskite Films.

Author

Lohmann KB, Patel JB, Rothmann MU, Xia CQ, Oliver RDJ, Herz LM, Snaith HJ, and Johnston MB

Abstract

Understanding and controlling grain growth in metal halide perovskite polycrystalline thin films is an important step in improving the performance of perovskite solar cells. We demonstrate accurate control of crystallite size in CH 3 NH 3 PbI 3 thin films by regulating substrate temperature during vacuum co-deposition of inorganic (PbI 2 ) and organic (CH 3 NH 3 I) precursors. Films co-deposited onto a cold (-2 °C) substrate exhibited large, micrometer-sized crystal grains, while films that formed at room temperature (23 °C) only produced grains of 100 nm extent. We isolated the effects of substrate temperature on crystal growth by developing a new method to control sublimation of the organic precursor, and CH 3 NH 3 PbI 3 solar cells deposited in this way yielded a power conversion efficiency of up to 18.2%. Furthermore, we found substrate temperature directly affects the adsorption rate of CH 3 NH 3 I, thus impacting crystal formation and hence solar cell device performance via changes to the conversion rate of PbI 2 to CH 3 NH 3 PbI 3 and stoichiometry. These findings offer new routes to developing efficient solar cells through reproducible control of crystal morphology and composition., Competing Interests: The authors declare the following competing financial interest(s): H.J.S. is the cofounder and CSO of Oxford PV Ltd, a company that is commercializing perovskite photovoltaic technologies., (Copyright © 2020 American Chemical Society.)

Published

2020