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161. Retrograde Melting and Internal Liquid Gettering in Silicon

Author

Hudelson, Steve, primary, Newman, Bonna K., additional, Bernardis, Sarah, additional, Fenning, David P., additional, Bertoni, Mariana I., additional, Marcus, Matthew A., additional, Fakra, Sirine C., additional, Lai, Barry, additional, and Buonassisi, Tonio, additional

Published
2010
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162. Synchrotron-based microprobe investigation of impurities in raw quartz-bearing and carbon-bearing feedstock materials for photovoltaic applications.

Author

Bernardis, Sarah, Newman, Bonna K., Di Sabatino, Marisa, Fakra, Sirine C., Bertoni, Mariana I., Fenning, David P., Larsen, Rune B., and Buonassisi, Tonio

Abstract

ABSTRACT Using synchrotron-based analytical microprobe techniques, we determine micrometer-scale elemental composition, spatial distribution, and oxidation state of impurities in raw feedstock materials used in the photovoltaic industry. Investigated Si-bearing compounds are pegmatitic quartz, hydrothermal quartz, and quartzite. Micrometer-scale clusters containing Fe, Ti, and/or Ca are frequently observed at structural defects in oxidized states and in bulk concentrations equivalent to inductively coupled plasma mass spectroscopy measurements. Investigated C-bearing compounds are pine wood, pine charcoal, and eucalyptus charcoal. Clustered metals are observed only in the charcoal samples. Impurity clustering implies that industrial processing could be adapted to take advantage of this 'natural gettering' phenomenon, expanding the usable range of raw feedstock materials to dirtier, cheaper, and more abundant ones, currently underexploited for solar-grade silicon production. Copyright © 2011 John Wiley & Sons, Ltd. [ABSTRACT FROM AUTHOR]

Published
2012
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163. Low‐Temperature Synthesis of Stable CaZn2P2 Zintl Phosphide Thin Films as Candidate Top Absorbers.

Author

Quadir, Shaham, Yuan, Zhenkun, Esparza, Guillermo L., Dugu, Sita, Mangum, John S., Pike, Andrew, Hasan, Muhammad Rubaiat, Kassa, Gideon, Wang, Xiaoxin, Coban, Yagmur, Liu, Jifeng, Kovnir, Kirill, Fenning, David P., Reid, Obadiah G., Zakutayev, Andriy, Hautier, Geoffroy, and Bauers, Sage R.

Subjects
*OPTICAL films, *SPUTTER deposition, *THIN films, *SOLAR cells, *PHOTOELECTROCHEMICAL cells, *OPTICAL conductivity, *OPTOELECTRONIC devices
Abstract

The development of tandem photovoltaics and photoelectrochemical solar cells requires new absorber materials with bandgaps in the range of ≈1.5–2.3 eV, for use in the top cell paired with a narrower‐gap bottom cell. An outstanding challenge is finding materials with suitable optoelectronic and defect properties, good operational stability, and synthesis conditions that preserve underlying device layers. This study demonstrates the Zintl phosphide compound CaZn2P2 as a compelling candidate semiconductor for these applications. Phase‐pure, ≈500 nm‐thick CaZn2P2 thin films are prepared using a scalable reactive sputter deposition process at growth temperatures as low as 100 °C, which is desirable for device integration. Ultraviolet‐visible spectroscopy shows that CaZn2P2 films exhibit an optical absorptivity of ≈104 cm−1 at ≈1.95 eV direct bandgap. Room‐temperature photoluminescence (PL) measurements show near‐band‐edge optical emission, and time‐resolved microwave conductivity (TRMC) measurements indicate a photoexcited carrier lifetime of ≈30 ns. CaZn2P2 is highly stable in both ambient conditions and moisture, as evidenced by PL and TRMC measurements. Experimental data are supported by first‐principles calculations, which indicate the absence of low‐formation‐energy, deep intrinsic defects. Overall, this study shall motivate future work integrating this potential top cell absorber material into tandem solar cells. [ABSTRACT FROM AUTHOR]

Published
2024
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164. Ferroelectric Modulation of Surface Electronic States in BaTiO3for Enhanced Hydrogen Evolution Activity

Author

Abbasi, Pedram, Barone, Matthew R., de la Paz Cruz-Jáuregui, Ma., Valdespino-Padilla, Duilio, Paik, Hanjong, Kim, Taewoo, Kornblum, Lior, Schlom, Darrell G., Pascal, Tod A., and Fenning, David P.

Abstract

Ferroelectric nanomaterials offer the promise of switchable electronic properties at the surface, with implications for photo- and electrocatalysis. Studies to date on the effect of ferroelectric surfaces in electrocatalysis have been primarily limited to nanoparticle systems where complex interfaces arise. Here, we use MBE-grown epitaxial BaTiO3thin films with atomically sharp interfaces as model surfaces to demonstrate the effect of ferroelectric polarization on the electronic structure, intermediate binding energy, and electrochemical activity toward the hydrogen evolution reaction (HER). Surface spectroscopy and ab initioDFT+U calculations of the well-defined (001) surfaces indicate that an upward polarized surface reduces the work function relative to downward polarization and leads to a smaller HER barrier, in agreement with the higher activity observed experimentally. Employing ferroelectric polarization to create multiple adsorbate interactions over a single electrocatalytic surface, as demonstrated in this work, may offer new opportunities for nanoscale catalysis design beyond traditional descriptors.

Published
2022
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166. The Role of Water in the Reversible Optoelectronic Degradation of Hybrid Perovskites at Low Pressure

Author

Hall, Genevieve N., Stuckelberger, Michael, Nietzold, Tara, Hartman, Jessi, Park, Ji-Sang, Werner, Jeremie, Niesen, Bjoern, Cummings, Marvin L., Rose, Volker, Ballif, Christophe, Chan, Maria K., Fenning, David P., and Bertoni, Mariana I.

Abstract

There is no doubt about the potential offered by the low-cost fabrication and high efficiency of hybrid organic inorganic perovskite solar cells. However, the service lifetimes of these devices must be increased from months to years to capitalize on their potential. The archetypal hybrid perovskite for solar cells, methylammonium lead iodide (CH3NH3PbI3, abbreviated MAPI), readily degrades in ambient atmosphere under standard operating conditions. Understanding the origin and effects of this degradation can pave the way to better engineer photovoltaic devices and the perovskite material itself. Herein we present the effects of varying pressure on the electrical performance of MAPI solar cells. Solar cell parameters, especially open circuit voltage, are significantly affected by the total ambient pressure and present an unexpected reversible behavior upon pressure cycling. We complement photoluminescence studies as a function of ambient atmosphere and temperature with first principles density functional theory (DFT) calculations. The results suggest that the reversible intercalation of water in MAPI is a necessary component underlying this behavior.

170. Hierarchical Porous Carbonized Co3O4 Inverse Opals via Combined Block Copolymer and Colloid Templating as Bifunctional Electrocatalysts in Li-O2 Battery

Author

Cho, Seol A., Jang, Yu Jin, Lim, Hee-Dae, Lee, Ji-Eun, Jang, Yoon Hee, Nguyen, Trang-Thi Hong, Marques Mota, Filipe, Fenning, David P., Kang, Kisuk, Shao-Horn, Yang, Kim, Dong Ha, Cho, Seol A., Jang, Yu Jin, Lim, Hee-Dae, Lee, Ji-Eun, Jang, Yoon Hee, Nguyen, Trang-Thi Hong, Marques Mota, Filipe, Fenning, David P., Kang, Kisuk, Shao-Horn, Yang, and Kim, Dong Ha

Abstract

Hierarchically organized porous carbonized-Co3O4 inverse opal nanostructures (C-Co3O4 IO) are synthesized via complementary colloid and block copolymer self-assembly, where the triblock copolymer Pluronic P123 acts as the template and the carbon source. These highly ordered porous inverse opal nanostructures with high surface area display synergistic properties of high energy density and promising bifunctional electrocatalytic activity toward both the oxygen reduction reaction (ORR) and oxygen evolution reaction (OER). It is found that the as-made C-Co3O4 IO/Ketjen Black (KB) composite exhibits remarkably enhanced electrochemical performance, such as increased specific capacity (increase from 3591 to 6959 mA h g−1), lower charge overpotential (by 284.4 mV), lower discharge overpotential (by 19.0 mV), and enhanced cyclability (about nine times higher than KB in charge cyclability) in Li–O2 battery. An overall agreement is found with both C-Co3O4 IO/KB and Co3O4 IO/KB in ORR and OER half-cell tests using a rotating disk electrode. This enhanced catalytic performance is attributed to the porous structure with highly dispersed carbon moiety intact with the host Co3O4 catalyst.

171. Strong-bonding hole-transport layers reduce ultraviolet degradation of perovskite solar cells.

Author

Chengbin Fei, Kuvayskaya, Anastasia, Xiaoqiang Shi, Mengru Wang, Zhifang Shi, Haoyang Jiao, Silverman, Timothy J., Owen-Bellini, Michael, Yifan Dong, Yeming Xian, Scheidt, Rebecca, Xiaoming Wang, Guang Yang, Hangyu Gu, Nengxu Li, Dolan, Connor J., Deng, Zhewen J. D., Cakan, Deniz N., Fenning, David P., and Yanfa Yan

Subjects
*SOLAR cells, *PEROVSKITE, *PHOSPHONIC acids, *LIGHT emitting diodes, *PHOTOVOLTAIC power systems, *CHEMICAL bonds, *POLYMERS
Abstract

The light-emitting diodes (LEDs) used in indoor testing of perovskite solar cells do not expose them to the levels of ultraviolet (UV) radiation that they would receive in actual outdoor use. We report degradation mechanisms of p-i-n–structured perovskite solar cells under unfiltered sunlight and with LEDs. Weak chemical bonding between perovskites and polymer hole-transporting materials (HTMs) and transparent conducting oxides (TCOs) dominate the accelerated A-site cation migration, rather than direct degradation of HTMs. An aromatic phosphonic acid, [2-(9-ethyl-9H-carbazol-3-yl)ethyl]phosphonic acid (EtCz3EPA), enhanced bonding at the perovskite/HTM/TCO region with a phosphonic acid group bonded to TCOs and a nitrogen group interacting with lead in perovskites. A hybrid HTM of EtCz3EPA with strong hole-extraction polymers retained high efficiency and improved the UV stability of perovskite devices, and a champion perovskite minimodule—independently measured by the Perovskite PV Accelerator for Commercializing Technologies (PACT) center—retained operational efficiency of >16% after 29 weeks of outdoor testing. [ABSTRACT FROM AUTHOR]

Published
2024
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172. Scanning x-ray excited optical luminescence of heterogeneity in halide perovskite alloys.

Author

Dolan, Connor J, Cakan, Deniz N, Kumar, Rishi E, Kodur, Moses, Palmer, Jack R, Luo, Yanqi, Lai, Barry, and Fenning, David P

Subjects
*X-rays, *LUMINESCENCE, *PEROVSKITE, *ELECTRONIC probes, *VISIBLE spectra, *IRRADIATION
Abstract

Understanding the optoelectronic properties of optically active materials at the nanoscale often proves challenging due to the diffraction-limited resolution of visible light probes and the dose sensitivity of many optically active materials to high-energy electron probes. In this study, we demonstrate correlative synchrotron-based scanning x-ray excited optical luminescence (XEOL) and x-ray fluorescence (XRF) to simultaneously probe local composition and optoelectronic properties of halide perovskite thin films of interest for photovoltaic and optoelectronic devices. We find that perovskite XEOL stability, emission redshifting, and peak broadening under hard x-ray irradiation correlates with trends seen in photoluminescence measurements under continuous visible light laser irradiation. The XEOL stability is sufficient under the intense x-ray probe irradiation to permit proof-of-concept correlative mapping. Typical synchrotron XRF and nano-diffraction measurements use acquisition times 10–100 x shorter than the 5-second acquisition employed for XEOL scans in this study, suggesting that improving luminescence detection should allow correlative XEOL measurements to be performed successfully with minimal material degradation. Analysis of the XEOL emission from the quartz substrate beneath the perovskite reveals its promise for use as a real-time in-situ x-ray dosimeter, which could provide quantitative metrics for future optimization of XEOL data collection for perovskites and other beam-sensitive materials. Overall, the data suggest that XEOL represents a promising route towards improved resolution in the characterization of nanoscale heterogeneities and defects in optically active materials that may be implemented into x-ray nanoprobes to complement existing x-ray modalities. [ABSTRACT FROM AUTHOR]

Published
2022
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173. Europium Addition Reduces Local Structural Disorder and Enhances Photoluminescent Yield in Perovskite CsPbBr3.

Author

Quinn, Xueying L., Kumar, Rishi E., Kodur, Moses, Cakan, Deniz N., Cai, Zhonghou, Zhou, Tao, Holt, Martin V., and Fenning, David P.

Subjects
*EUROPIUM, *PEROVSKITE, *OPTOELECTRONIC devices, *X-ray microscopy, *X-ray diffraction, *SYNCHROTRONS
Abstract

Correlative X‐ray microscopy, including synchrotron X‐ray diffraction and fluorescence, is leveraged to understand the local role of europium as a B‐site additive in CsPbBr3 perovskite crystals. Europium addition reduces microstrain in the perovskite, despite the fact that the degree of europium incorporation into the perovskite varies locally, with a maximum loading over twice the nominal stoichiometry. The presence of europium improves photoluminescence yield and bandwidth, while shifting the emission to bluer wavelengths. Finally, europium‐containing crystals have greatly improved X‐ray hardness. The findings show promise for europium as an additive in perovskite optoelectronic devices. [ABSTRACT FROM AUTHOR]

Published
2021
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174. A Wearable Colorimetric Dosimeter to Monitor Sunlight Exposure.

Author

Wang, Junxin, Jeevarathinam, Ananthakrishnan Soundaram, Jhunjhunwala, Anamik, Ren, Haowen, Lemaster, Jeanne, Luo, Yanqi, Fenning, David P., Fullerton, Eric E., and Jokerst, Jesse V.

Subjects
*DOSIMETERS, *ULTRAVIOLET radiation measurement, *COLORIMETRIC analysis, *SUNSHINE, *WEARABLE technology, *ULTRAVIOLET radiation
Abstract

Abstract: The personal ultraviolet (UV) dosimeter is a useful measurement tool to prevent UV induced dermal damages; however, conventional digital dosimeters are either bulky or require external power sources. Here, a wearable, colorimetric UV film dosimeter that provides color transition, from purple to transparent, is reported to indicate the UV dose. The film dosimeter is made of a purple photodegradable dye ((2Z,6Z)‐2,6‐bis(2‐(2,6‐diphenyl‐4H‐thiopyran‐4‐ylidene)ethylidene)cyclohexanone or DTEC) blended in low density polyethylene film. The DTEC film discolored 3.3 times more under the exposure of UV light (302 nm) than visible light (543 nm), and a UV bandpass filter is developed to increase this selectivity to UV light. The DTEC film completely discolors to transparency in 2 h under an AM 1.5 solar simulator, suggesting the potential as an indicator for individuals with types I–VI skin to predict interventions to avoid sunburn. Finally, the DTEC film is integrated with the UV bandpass filter on a wristband to function as a wearable dosimeter for low cost and convenient monitoring of sunlight exposure. [ABSTRACT FROM AUTHOR]

Published
2018
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175. The Relationship between Chemical Flexibility and Nanoscale Charge Collection in Hybrid Halide Perovskites.

Author

Luo, Yanqi, Aharon, Sigalit, Stuckelberger, Michael, Magaña, Ernesto, Lai, Barry, Bertoni, Mariana I., Etgar, Lioz, and Fenning, David P.

Subjects
*ORGANOMETALLIC compounds, *PEROVSKITE, *HALIDES, *MICROSTRUCTURE, *OPTOELECTRONIC devices
Abstract

Abstract: Hybrid organometal halide perovskites are known for their excellent optoelectronic functionality as well as their wide‐ranging chemical flexibility. The composition of hybrid perovskite devices has trended toward increasing complexity as fine‐tuned properties are pursued, including multielement mixing on the constituents A and B and halide sites. However, this tunability presents potential challenges for charge extraction in functional devices. Poor consistency and repeatability between devices may arise due to variations in composition and microstructure. Within a single device, spatial heterogeneity in composition and phase segregation may limit the device from achieving its performance potential. This review details how the nanoscale elemental distribution and charge collection in hybrid perovskite materials evolve as chemical complexity increases, highlighting recent results using nondestructive operando synchrotron‐based X‐ray nanoprobe techniques. The results reveal a strong link between local chemistry and charge collection that must be controlled to develop robust, high‐performance hybrid perovskite materials for optoelectronic devices. [ABSTRACT FROM AUTHOR]

Published
2018
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176. In-situ determination of moisture- and temperature-driven deflection of an encapsulated Si photovoltaic cell.

Author

Slauch, Ian M., Gandhi, Hir, Kumar, Rishi E., Sidawi, Tala, Tracy, Jared, Choudhury, Roy Kaushik, Meier, Rico, Fenning, David P., and Bertoni, Mariana I.

Subjects
*PHOTOVOLTAIC cells, *X-ray topography, *SOLAR cells, *WATERFRONTS, *RESIDUAL stresses, *PHOTOVOLTAIC power systems, *BUILDING-integrated photovoltaic systems
Abstract

Module reliability and service lifetime are critical factors in improving photovoltaic system performance and reducing the levelized cost of electricity (LCOE). Soldering and lamination of the cell impart residual stresses that persist over time and superimpose additional loads during operation. This paper demonstrates the use of X-ray Topography (XRT) to image in-situ the dynamic response of a glass/backsheet mini-module upon drying at elevated temperature after saturation at humidity levels compatible with accelerated testing. The local water content in the encapsulant is also determined in-situ over time via Water Reflectometric Detection (WaRD), with diffusion of water in the front (glass side) and rear (backsheet side) resolved. As water diffuses out from the back of the glass/backsheet module, the cell curves towards the backsheet concomitantly. We find that the cell edges deflect 40 μm out-of-plane with respect to its center while the encapsulant dries, compared to ∼100 μm deflection when heating from 25 °C to 85 °C. The local cell deflections (changes in cell orientation) are correlated with the dynamic loss of water in the backside encapsulant. We conclude that the observed cell deflections are the result of hygroscopic stress induced by the encapsulant upon moisture outdiffusion. Therefore, the cell experiences a continually changing stress state and curvature dependent on local humidity and temperature. Depending on cell architecture and interconnection, this "breathing" mode of the cell may induce wear out and fatigue of the interconnects, affect the electrical connection of cracked pieces or cause failure near the interconnected edges of two cells. • The mechanical response to moisture diffusion in Glass/Backsheet PV modules is detectable by lab-scale X-Ray Topography. • The effect of moisture on the mechanical state of the cell can be decoupled from the influence of temperature. • Moisture diffusion dynamically changes the curvature of the PV cell, increasing as moisture diffuses out of the encapsulant. • The dynamic mechanical response to moisture raises the question of daily humidity cycling in mechanical fatigue of the cell. [ABSTRACT FROM AUTHOR]

Published
2023
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177. Synchrotron-based investigation of transition-metal getterability in n-type multicrystalline silicon.

Author

Morishige, Ashley E., Jensen, Mallory A., Hofstetter, Jasmin, Yen, Patricia X. T., Chenlei Wang, Lai, Barry, Fenning, David P., and Buonassisi, Tonio

Subjects
*SYNCHROTRONS, *TRANSITION metals spectra, *SOLAR cells, *PHOTOVOLTAIC power generation, *PRECIPITATION (Chemistry), *X-ray fluorescence
Abstract

Solar cells based on n-type multicrystalline silicon (mc-Si) wafers are a promising path to reduce the cost per kWh of photovoltaics; however, the full potential of the material and how to optimally process it are still unknown. Process optimization requires knowledge of the response of the metalsilicide precipitate distribution to processing, which has yet to be directly measured and quantified. To supply this missing piece, we use synchrotron-based micro-X-ray fluorescence (µ-XRF) to quantitatively map >250 metal-rich particles in n-type mc-Si wafers before and after phosphorus diffusion gettering (PDG).We find that 820 °C PDG is sufficient to remove precipitates of fast-diffusing impurities and that 920 °C PDG can eliminate precipitated Fe to below the detection limit of µ-XRF. Thus, the evolution of precipitated metal impurities during PDG is observed to be similar for n- and p-type mc-Si, an observation consistent with calculations of the driving forces for precipitate dissolution and segregation gettering. Measurements show that minority-carrier lifetime increases with increasing precipitate dissolution from 820 °C to 880°C PDG, and that the lifetime after PDG at 920 °C is between the lifetimes achieved after 820 °C and 880 °C PDG. [ABSTRACT FROM AUTHOR]

Published
2016
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178. Synchrotron-based analysis of chromium distributions in multicrystalline silicon for solar cells.

Author

Jensen, Mallory Ann, Hofstetter, Jasmin, Morishige, Ashley E., Coletti, Gianluca, Lai, Barry, Fenning, David P., and Buonassisi, Tonio

Subjects
*CHROMIUM, *SILICON crystals, *SYNCHROTRONS, *SOLAR cells, *SILICON wafers, *X-ray fluorescence
Abstract

Chromium (Cr) can degrade silicon wafer-based solar cell efficiencies at concentrations as low as 1010cm-3. In this contribution, we employ synchrotron-based X-ray fluorescence microscopy to study chromium distributions in multicrystalline silicon in as-grown material and after phosphorous diffusion. We complement quantified precipitate size and spatial distribution with interstitial Cr concentration and minority carrier lifetime measurements to provide insight into chromium gettering kinetics and offer suggestions for minimizing the device impacts of chromium. We observe that Cr-rich precipitates in as-grown material are generally smaller than iron-rich precipitates and that Cri point defects account for only one-half of the total Cr in the as-grown material. This observation is consistent with previous hypotheses that Cr transport and CrSi2 growth are more strongly diffusion-limited during ingot cooling. We apply two phosphorous diffusion gettering profiles that both increase minority carrier lifetime by two orders of magnitude and reduce [Cri] by three orders of magnitude to ≈1010cm-3. Some Cr-rich precipitates persist after both processes, and locally high [Cri] after the high-temperature process indicates that further optimization of the chromium gettering profile is possible. [ABSTRACT FROM AUTHOR]

Published
2015
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179. Finite- vs. infinite-source emitters in silicon photovoltaics: Effect on transition metal gettering

Author

N. Khelifati, Sebastian Husein, Zhengjun Liu, Haibing Huang, Ville Vähänissi, Mariana I. Bertoni, Hele Savin, Hannu S. Laine, Ashley E. Morishige, D. Bouhafs, David P. Fenning, Barry Lai, Ernesto Magana, Tonio Buonassisi, Massachusetts Institute of Technology. Department of Mechanical Engineering, Laine, Hannu, Morishige, Ashley Elizabeth, Bertoni, Mariana I, Buonassisi, Anthony, Fenning, David P, and Savin, Hele Irene

Subjects
Materials science, Silicon, ta114, Precipitation (chemistry), business.industry, Physics::Instrumentation and Detectors, chemistry.chemical_element, 02 engineering and technology, Chemical vapor deposition, 010402 general chemistry, 021001 nanoscience & nanotechnology, 01 natural sciences, 0104 chemical sciences, chemistry, Getter, Photovoltaics, Impurity, Optoelectronics, Physics::Accelerator Physics, Diffusion (business), 0210 nano-technology, business, Common emitter
Abstract

Control of detrimental metal impurities is crucial to silicon solar cell performance. Traditional silicon solar cell emitters are diffused in an infinite-source regime and are known to cause strong point defect segregation towards the emitter and thus enhance bulk minority carrier diffusion length. With the advent of ion-implantation and chemical vapor deposition (CVD) glasses, finite-source diffused emitters are attracting interest. This contribution aims to increase their adoption by elucidating the dominant gettering mechanisms present in finite-source diffused emitters. Our findings indicate that infinite-source diffusion is critical for effective segregation gettering, but that high enough surface phosphorus concentration can activate segregation gettering via finite-source diffusion as well. In the case of ion-implanted emitters, the traditional segregation gettering may be considerably enhanced by impurity precipitation in the implanted layer., United States. Department of Energy. Office of Basic Energy Sciences (Contract No. DE-AC02-06CH11357), National Science Foundation (U.S.) (CA No. EEC-1041895), Finnish Cultural Foundation, Fulbright-Technology Industries of Finland Grant, University of California, San Diego. Start Up Funds

Published
2016

180. Synchrotron-based analysis of chromium distributions in multicrystalline silicon for solar cells

Author

Ashley E. Morishige, David P. Fenning, Jasmin Hofstetter, Gianluca Coletti, Tonio Buonassisi, Barry Lai, Mallory A. Jensen, Massachusetts Institute of Technology. Department of Mechanical Engineering, Jensen, Mallory Ann, Hofstetter, Jasmin, Morishige, Ashley Elizabeth, Fenning, David P, and Buonassisi, Anthony

Subjects
Technology, Materials science, Physics and Astronomy (miscellaneous), Silicon, Analytical chemistry, chemistry.chemical_element, 02 engineering and technology, 01 natural sciences, 7. Clean energy, law.invention, Chromium, Engineering, law, 0103 physical sciences, Solar cell, Wafer, Ingot, Applied Physics, 010302 applied physics, Carrier lifetime, Orders of magnitude (numbers), 021001 nanoscience & nanotechnology, Crystallographic defect, Crystallography, chemistry, Physical Sciences, 0210 nano-technology
Abstract

Chromium (Cr) can degrade silicon wafer-based solar cell efficiencies at concentrations as low as 10¹⁰cm⁻³. In this contribution, we employ synchrotron-based X-ray fluorescence microscopy to study chromium distributions in multicrystalline silicon in as-grown material and after phosphorous diffusion. We complement quantified precipitate size and spatial distribution with interstitial Cr concentration and minority carrier lifetime measurements to provide insight into chromium gettering kinetics and offer suggestions for minimizing the device impacts of chromium. We observe that Cr-rich precipitates in as-grown material are generally smaller than iron-rich precipitates and that Cr[subscript i] point defects account for only one-half of the total Cr in the as-grown material. This observation is consistent with previous hypotheses that Cr transport and CrSi₂ growth are more strongly diffusion-limited during ingot cooling. We apply two phosphorous diffusion gettering profiles that both increase minority carrier lifetime by two orders of magnitude and reduce [Cr[subscript i]] by three orders of magnitude to 10¹⁰cm⁻³. Some Cr-rich precipitates persist after both processes, and locally high [Cr[subscript i]] after the high-temperature process indicates that further optimization of the chromium gettering profile is possible., United States. Department of Energy (Contract DE-EE0005314), National Science Foundation (U.S.) (Contract EEC-1041895), United States. Department of Energy (Contract EEC-1041895), National Science Foundation (U.S.) (Grant 1122374)

Published
2015
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181. Simulated co-optimization of crystalline silicon solar cell throughput and efficiency using continuously ramping phosphorus diffusion profiles

Author

Douglas M. Powell, Tonio Buonassisi, David P. Fenning, Ashley E. Morishige, Jasmin Hofstetter, Massachusetts Institute of Technology. Department of Mechanical Engineering, Morishige, Ashley Elizabeth, Fenning, David P., Hofstetter, Jasmin, Powell, Douglas Michael, and Buonassisi, Tonio

Subjects
Materials science, Silicon, business.industry, Photovoltaic system, chemistry.chemical_element, Carrier lifetime, law.invention, Solar cell efficiency, chemistry, law, Solar cell, Optoelectronics, Crystalline silicon, Diffusion (business), business, Sheet resistance
Abstract

http://ieeexplore.ieee.org/stamp/stamp.jsp?tp=&arnumber=6318036, Defect engineering is essential for the production of high-performance silicon photovoltaic (PV) devices with cost-effective solar-grade Si input materials. Phosphorus diffusion gettering (PDG) can mitigate the detrimental effect of metal impurities on PV device performance. Using the Impurity-to-Efficiency (I2E) simulator, we investigate the effect of gettering temperature on minority carrier lifetime while maintaining an approximately constant sheet resistance. We simulate a typical constant temperature plateau profile and an alternative “volcano” profile that consists of a ramp up to a peak temperature above the typical plateau temperature followed by a ramp down with no hold time. Our simulations show that for a given PDG process time, the “volcano” produces an increase in minority carrier lifetime compared to the standard plateau profile for as-grown iron distributions that are typical for multicrystalline silicon. For an initial total iron concentration of 5×1013 cm-3, we simulate a 30% increase in minority carrier lifetime for a fixed PDG process time and a 43% reduction in PDG process cost for a given effective minority carrier lifetime while achieving a constant sheet resistance of 100 Ω/□., National Science Foundation (U.S.), United States. Dept. of Energy (NSF CA No. EEC-1041895), Massachusetts Institute of Technology. School of Engineering (SMA2 Fellowship), National Science Foundation (U.S.) (NSF Graduate Research Fellowship), Alexander von Humboldt-Stiftung (Feodor Lynen Fellowship Program), United States. Dept. of Defense (National Defense Science and Engineering Graduate Fellowship)

Published
2012
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182. Surface-Grafted Biocompatible Polymer Conductors for Stable and Compliant Electrodes for Brain Interfaces.

Author

Blau R, Russman SM, Qie Y, Shipley W, Lim A, Chen AX, Nyayachavadi A, Ah L, Abdal A, Esparza GL, Edmunds SJ, Vatsyayan R, Dunfield SP, Halder M, Jokerst JV, Fenning DP, Tao AR, Dayeh SA, and Lipomi DJ

Subjects
Surface Properties, Electrodes, Electric Conductivity, Brain physiology, Brain-Computer Interfaces, Animals, Polyethylene Glycols chemistry, Gold chemistry, Polymers chemistry, Biocompatible Materials chemistry
Abstract

Durable and conductive interfaces that enable chronic and high-resolution recording of neural activity are essential for understanding and treating neurodegenerative disorders. These chronic implants require long-term stability and small contact areas. Consequently, they are often coated with a blend of conductive polymers and are crosslinked to enhance durability despite the potentially deleterious effect of crosslinking on the mechanical and electrical properties. Here the grafting of the poly(3,4 ethylenedioxythiophene) scaffold, poly(styrenesulfonate)-b-poly(poly(ethylene glycol) methyl ether methacrylate block copolymer brush to gold, in a controlled and tunable manner, by surface-initiated atom-transfer radical polymerization (SI-ATRP) is described. This "block-brush" provides high volumetric capacitance (120 F cm ─3 ), strong adhesion to the metal (4 h ultrasonication), improved surface hydrophilicity, and stability against 10 000 charge-discharge voltage sweeps on a multiarray neural electrode. In addition, the block-brush film showed 33% improved stability against current pulsing. This approach can open numerous avenues for exploring specialized polymer brushes for bioelectronics research and application., (© 2024 The Author(s). Advanced Healthcare Materials published by Wiley‐VCH GmbH.)

Published
2024
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183. Understanding Process-Structure Relationships during Lamination of Halide Perovskite Interfaces.

Author

Lanaghan CL, Okia O, Coons T, Yadavalli SK, Palmer JR, Zhang M, Hersh K, Kodur M, Trejo O, Dunfield SP, Thouless MD, Fenning DP, Huan X, and Dasgupta NP

Abstract

Fabrication of halide perovskite (HP) solar cells typically involves the sequential deposition of multiple layers to create a device stack, which is limited by the thermal and chemical incompatibility of top contact layers with the underlying HP semiconductor. One emerging strategy to overcome these restrictions on material selection and processing conditions is lamination, where two half-stacks are independently processed and then diffusion bonded to complete the device. Lamination reduces the processing constraints on the top side of the solar cell to allow new device designs, expanded use of deposition methods, and self-encapsulation of devices. While laminated perovskite solar cells with high efficiencies and novel interlayer combinations have been demonstrated, there is a limited understanding of how the lamination process parameters affect the diffusion-bond quality and material properties of the resulting HP layer. In this study, we systematically vary temperature, pressure, and time during lamination and quantify the resulting impacts on bonded area, grain domain size, and photoluminescence. A design of experiments is performed, and statistical analysis of the experimental results is used to quantitatively evaluate the resulting process-structure-property relationships. The lamination temperature is found to be the key parameter controlling these properties. A temperature of 150 °C enables successful bonding over 95% of the substrate area and also results in increases in apparent grain domain size and photoluminescence intensity. Based on these insights, the lamination temperature of functional perovskite solar cell devices is varied, demonstrating the importance of the resulting bond quality on device performance metrics.

Published
2024
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184. Cl alloying improves thermal stability and increases luminescence in iodine-rich inorganic perovskites.

Author

Cakan DN, Dolan CJ, Oberholtz E, Kodur M, Palmer JR, Vossler HM, Luo Y, Kumar RE, Zhou T, Cai Z, Lai B, Holt MV, Dunfield SP, and Fenning DP

Abstract

The inorganic perovskite CsPbI 3 shows promising photophysical properties for a range of potential optoelectronic applications but is metastable at room temperature. To address this, Br can be alloyed into the X-site to create compositions such as CsPbI 2 Br that are stable at room temperature but have bandgaps >1.9 eV - severely limiting solar applications. Herein, in an effort to achieve phase stable films with bandgaps <1.85 eV, we investigate alloying chlorine into iodine-rich triple-halide CsPb(I 0.8 Br 0.2- x Cl x ) 3 with 0 < x < 0.1. We show that partial substitution of iodine with bromine and chlorine provides a path to maintain broadband terrestrial absorption while improving upon the perovskite phase stability due to chlorine's smaller size and larger ionization potential than bromine. At moderate Cl loading up to ≈5%, X-ray diffraction reveals an increasingly smaller orthorhombic unit cell, suggesting chlorine incorporation into the lattice. Most notably, this Cl incorporation is accompanied by a significant enhancement over Cl-free controls in the duration of black-phase stability of up to 7× at elevated temperatures. Additionally, we observe up to 5× increased steady state photoluminescence intensity (PL), along with a small blue-shift. In contrast, at high loading (≈10%), Cl accumulates in a second phase that is visible at grain boundaries via synchrotron fluorescence microscopy and negatively impacts the perovskite phase stability. Thus, replacing small fractions of bromine for chlorine in the iodine-rich inorganic perovskite lattice results in distinct improvement thermal stability and optoelectronic quality while minimally impacting the bandgap., Competing Interests: There are no conflicts to declare., (This journal is © The Royal Society of Chemistry.)

Published
2024
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185. Two-dimensional perovskite templates for durable, efficient formamidinium perovskite solar cells.

Author

Sidhik S, Metcalf I, Li W, Kodalle T, Dolan CJ, Khalili M, Hou J, Mandani F, Torma A, Zhang H, Garai R, Persaud J, Marciel A, Muro Puente IA, Reddy GNM, Balvanz A, Alam MA, Katan C, Tsai E, Ginger D, Fenning DP, Kanatzidis MG, Sutter-Fella CM, Even J, and Mohite AD

Abstract

We present a design strategy for fabricating ultrastable phase-pure films of formamidinium lead iodide (FAPbI 3 ) by lattice templating using specific two-dimensional (2D) perovskites with FA as the cage cation. When a pure FAPbI 3 precursor solution is brought in contact with the 2D perovskite, the black phase forms preferentially at 100°C, much lower than the standard FAPbI 3 annealing temperature of 150°C. X-ray diffraction and optical spectroscopy suggest that the resulting FAPbI 3 film compresses slightly to acquire the (011) interplanar distances of the 2D perovskite seed. The 2D-templated bulk FAPbI 3 films exhibited an efficiency of 24.1% in a p-i-n architecture with 0.5-square centimeter active area and an exceptional durability, retaining 97% of their initial efficiency after 1000 hours under 85°C and maximum power point tracking.

Published
2024
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186. Conductive block copolymer elastomers and psychophysical thresholding for accurate haptic effects.

Author

Blau R, Abdal A, Root N, Chen AX, Rafeedi T, Ramji R, Qie Y, Kim T, Navarro A, Chin J, Becerra LL, Edmunds SJ, Russman SM, Dayeh SA, Fenning DP, Rouw R, and Lipomi DJ

Subjects
Humans, Adult, Female, Male, Equipment Design, Electric Stimulation, Young Adult, Polymers, Electrodes, Calibration, Touch Perception physiology, Elastomers, Touch physiology, Electric Conductivity, Psychophysics
Abstract

Electrotactile stimulus is a form of sensory substitution in which an electrical signal is perceived as a mechanical sensation. The electrotactile effect could, in principle, recapitulate a range of tactile experience by selective activation of nerve endings. However, the method has been plagued by inconsistency, galvanic reactions, pain and desensitization, and unwanted stimulation of nontactile nerves. Here, we describe how a soft conductive block copolymer, a stretchable layout, and concentric electrodes, along with psychophysical thresholding, can circumvent these shortcomings. These purpose-designed materials, device layouts, and calibration techniques make it possible to generate accurate and reproducible sensations across a cohort of 10 human participants and to do so at ultralow currents (≥6 microamperes) without pain or desensitization. This material, form factor, and psychophysical approach could be useful for haptic devices and as a tool for activation of the peripheral nervous system.

Published
2024
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187. Strong-bonding hole-transport layers reduce ultraviolet degradation of perovskite solar cells.

Author

Fei C, Kuvayskaya A, Shi X, Wang M, Shi Z, Jiao H, Silverman TJ, Owen-Bellini M, Dong Y, Xian Y, Scheidt R, Wang X, Yang G, Gu H, Li N, Dolan CJ, Deng ZJD, Cakan DN, Fenning DP, Yan Y, Beard MC, Schelhas LT, Sellinger A, and Huang J

Abstract

The light-emitting diodes (LEDs) used in indoor testing of perovskite solar cells do not expose them to the levels of ultraviolet (UV) radiation that they would receive in actual outdoor use. We report degradation mechanisms of p-i-n-structured perovskite solar cells under unfiltered sunlight and with LEDs. Weak chemical bonding between perovskites and polymer hole-transporting materials (HTMs) and transparent conducting oxides (TCOs) dominate the accelerated A-site cation migration, rather than direct degradation of HTMs. An aromatic phosphonic acid, [2-(9-ethyl-9H-carbazol-3-yl)ethyl]phosphonic acid (EtCz3EPA), enhanced bonding at the perovskite/HTM/TCO region with a phosphonic acid group bonded to TCOs and a nitrogen group interacting with lead in perovskites. A hybrid HTM of EtCz3EPA with strong hole-extraction polymers retained high efficiency and improved the UV stability of perovskite devices, and a champion perovskite minimodule-independently measured by the Perovskite PV Accelerator for Commercializing Technologies (PACT) center-retained operational efficiency of >16% after 29 weeks of outdoor testing.

Published
2024
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188. Lamination of >21% Efficient Perovskite Solar Cells with Independent Process Control of Transport Layers and Interfaces.

Author

Yadavalli SK, Lanaghan CL, Palmer J, Gayle AJ, Penley D, Okia O, Zaccherini M, Trejo O, Dunfield SP, Fenning DP, and Dasgupta NP

Abstract

Transport layer and interface optimization is critical for improving the performance and stability of perovskite solar cells (PSCs) but is restricted by the conventional fabrication approach of sequential layer deposition. While the bottom transport layer is processed with minimum constraints, the narrow thermal and chemical stability window of the halide perovskite (HP) layer severely restricts the choice of top transport layer and its processing conditions. To overcome these limitations, we demonstrate lamination of HPs─where two transport layer-perovskite half-stacks are independently processed and diffusion-bonded at the HP-HP interface─as an alternative fabrication strategy that enables self-encapsulated solar cells. Power conversion efficiencies (PCE) of >21% are realized using cells that incorporate a novel transport layer combination along with dual-interface passivation via self-assembled monolayers, both of which are uniquely enabled by the lamination approach. This is the highest reported PCE for any laminated PSC encapsulated between glass substrates. We further show that this approach expands the processing window beyond traditional fabrication processes and is adaptable for different transport layer compositions. The laminated PSCs retained >75% of their initial PCE after 1000 h of 1-sun illumination at 40 °C in air using an all-inorganic transport layer configuration without additional encapsulation. Furthermore, a laminated 1 cm 2 device maintained a V oc of 1.16 V. The scalable lamination strategy in this study enables the implementation of new transport layers and interfacial engineering approaches for improving performance and stability.

Published
2024
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189. Effect of Additives on the Surface Morphology, Energetics, and Contact Resistance of PEDOT:PSS.

Author

Chen AX, Esparza GL, Simon I, Dunfield SP, Qie Y, Bunch JA, Blau R, Lim A, Zhang H, Brew SE, O'Neill FM, Fenning DP, and Lipomi DJ

Abstract

For a poly(3,4-ethylenedioxythiophene) polystyrene sulfonate (PEDOT:PSS) film employed in a device stack, charge must pass through both the bulk of the film and interfaces between adjacent layers. Thus, charge transport is governed by both bulk and contact resistances. However, for ultrathin films (e.g., flexible devices, thin-film transistors, printed electronics, solar cells), interfacial properties can dominate over the bulk properties, making contact resistance a significant determinant of device performance. For most device applications, the bulk conductivity of PEDOT:PSS is typically improved by blending additives into the solid film. Doping PEDOT:PSS with secondary dopants (e.g., polar small molecules), in particular, increases the bulk conductivity by inducing a more favorable solid morphology. However, the effects of these morphological changes on the contact resistance (which play a bigger role at smaller length scales) are relatively unstudied. In this work, we use transfer length method (TLM) measurements to decouple the bulk resistance from the contact resistance of PEDOT:PSS films incorporating several common additives. These additives include secondary dopants, a silane crosslinker (typically used to stabilize the PEDOT:PSS film), and multi-walled carbon nanotubes (conductive fillers). Using conductive atomic force microscopy, Kelvin probe force microscopy, Raman spectroscopy, and photoelectron spectroscopy, we connect changes in the contact resistance to changes in the surface morphology and energetics as governed by the blended additives. We find that the contact resistance at the PEDOT:PSS/silver interface can be reduced by (1) increasing the ratio of PEDOT to PSS chains, (2) decreasing the work function, (3) decreasing the benzoid-to-quinoid ratio at the surface of the solid film, (4) increasing the film uniformity and contact area, and (5) increasing the phase-segregated morphology of the solid film.

Published
2023
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190. Investigation of local distortion effects on X-ray absorption of ferroelectric perovskites from first principles simulations.

Author

Abbasi P, Fenning DP, and Pascal TA

Abstract

Understanding the role of ferroelectric polarization in modulating the electronic and structural properties of crystals is critical for advancing these materials for overcoming various technological and scientific challenges. However, due to difficulties in performing experimental methods with the required resolution, or in interpreting the results of methods therein, the nanoscale morphology and response of these surfaces to external electric fields has not been properly elaborated. In this work we investigate the effect of ferroelectric polarization and local distortions in a BaTiO 3 perovskite, using two widely used computational approaches which treat the many-body nature of X-ray excitations using different philosophies, namely the many-body, delta-self-consistent-field determinant (mb-ΔSCF) and the Bethe-Salpeter equation (BSE) approaches. We show that in agreement with our experiments, both approaches consistently predict higher excitations of the main peak in the O-K edge for the surface with upward polarization. However, the mb-ΔSCF approach mostly fails to capture the L 2,3 separations at the Ti-L edge, due to the absence of spin-orbit coupling in Kohn-Sham density functional theory (KS-DFT) at the generalized gradient approximation level. On the other hand, and most promising, we show that application of the GW/BSE approach successfully reproduces the experimental XAS, both the relative peak intensities as well as the L 2,3 separations at the Ti-L edges upon ferroelectric switching. Thus simulated XAS is shown to be a powerful method for capturing the nanoscale structure of complex materials, and we underscore the need for many-body perturbation approaches, with explicit consideration of core-hole and multiplet effects, for capturing the essential physics in these systems.

Published
2023
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191. Solvent-Free Transfer of Freestanding Large-Area Conjugated Polymer Films for Optoelectronic Applications.

Author

Esparza GL, Kodur M, Chen AX, Wang B, Bunch JA, Cramlet J, Runser R, Fenning DP, and Lipomi DJ

Abstract

Conventional processes for depositing thin films of conjugated polymers are restricted to those based on vapor, liquid, and solution-phase precursors. Each of these methods bear some limitations. For example, low-bandgap polymers with alternating donor-acceptor structures cannot be deposited from the vapor phase, and solution-phase deposition is always subject to issues related to the incompatibility of the substrate with the solvent. Here, a technique to enable deposition of large-area, ultra-thin films (≈20 nm or more), which are transferred from the surface of water, is demonstrated. From the water, these pre-solidified films can then be transferred to a desired substrate, circumventing limitations such as solvent orthogonality. The quality of these films is characterized by a variety of imaging and electrochemical measurements. Mechanical toughness is identified as a limiting property of polymer compatibility, along with some strategies to address this limitation. As a demonstration, the films are used as the hole-transport layer in perovskite solar cells, in which their performance is shown to be comparable to controls formed by spin-coating., (© 2023 Wiley-VCH GmbH.)

Published
2023
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192. Surface reaction for efficient and stable inverted perovskite solar cells.

Author

Jiang Q, Tong J, Xian Y, Kerner RA, Dunfield SP, Xiao C, Scheidt RA, Kuciauskas D, Wang X, Hautzinger MP, Tirawat R, Beard MC, Fenning DP, Berry JJ, Larson BW, Yan Y, and Zhu K

Abstract

Perovskite solar cells (PSCs) with an inverted structure (often referred to as the p-i-n architecture) are attractive for future commercialization owing to their easily scalable fabrication, reliable operation and compatibility with a wide range of perovskite-based tandem device architectures 1,2 . However, the power conversion efficiency (PCE) of p-i-n PSCs falls behind that of n-i-p (or normal) structure counterparts 3-6 . This large performance gap could undermine efforts to adopt p-i-n architectures, despite their other advantages. Given the remarkable advances in perovskite bulk materials optimization over the past decade, interface engineering has become the most important strategy to push PSC performance to its limit 7,8 . Here we report a reactive surface engineering approach based on a simple post-growth treatment of 3-(aminomethyl)pyridine (3-APy) on top of a perovskite thin film. First, the 3-APy molecule selectively reacts with surface formamidinium ions, reducing perovskite surface roughness and surface potential fluctuations associated with surface steps and terraces. Second, the reaction product on the perovskite surface decreases the formation energy of charged iodine vacancies, leading to effective n-type doping with a reduced work function in the surface region. With this reactive surface engineering, the resulting p-i-n PSCs obtained a PCE of over 25 per cent, along with retaining 87 per cent of the initial PCE after over 2,400 hours of 1-sun operation at about 55 degrees Celsius in air., (© 2022. The Author(s), under exclusive licence to Springer Nature Limited.)

Published
2022
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193. Ferroelectric Modulation of Surface Electronic States in BaTiO 3 for Enhanced Hydrogen Evolution Activity.

Author

Abbasi P, Barone MR, de la Paz Cruz-Jáuregui M, Valdespino-Padilla D, Paik H, Kim T, Kornblum L, Schlom DG, Pascal TA, and Fenning DP

Abstract

Ferroelectric nanomaterials offer the promise of switchable electronic properties at the surface, with implications for photo- and electrocatalysis. Studies to date on the effect of ferroelectric surfaces in electrocatalysis have been primarily limited to nanoparticle systems where complex interfaces arise. Here, we use MBE-grown epitaxial BaTiO 3 thin films with atomically sharp interfaces as model surfaces to demonstrate the effect of ferroelectric polarization on the electronic structure, intermediate binding energy, and electrochemical activity toward the hydrogen evolution reaction (HER). Surface spectroscopy and ab initio DFT+U calculations of the well-defined (001) surfaces indicate that an upward polarized surface reduces the work function relative to downward polarization and leads to a smaller HER barrier, in agreement with the higher activity observed experimentally. Employing ferroelectric polarization to create multiple adsorbate interactions over a single electrocatalytic surface, as demonstrated in this work, may offer new opportunities for nanoscale catalysis design beyond traditional descriptors.

Published
2022
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194. Homogenized halides and alkali cation segregation in alloyed organic-inorganic perovskites.

Author

Correa-Baena JP, Luo Y, Brenner TM, Snaider J, Sun S, Li X, Jensen MA, Hartono NTP, Nienhaus L, Wieghold S, Poindexter JR, Wang S, Meng YS, Wang T, Lai B, Holt MV, Cai Z, Bawendi MG, Huang L, Buonassisi T, and Fenning DP

Abstract

The role of the alkali metal cations in halide perovskite solar cells is not well understood. Using synchrotron-based nano-x-ray fluorescence and complementary measurements, we found that the halide distribution becomes homogenized upon addition of cesium iodide, either alone or with rubidium iodide, for substoichiometric, stoichiometric, and overstoichiometric preparations, where the lead halide is varied with respect to organic halide precursors. Halide homogenization coincides with long-lived charge carrier decays, spatially homogeneous carrier dynamics (as visualized by ultrafast microscopy), and improved photovoltaic device performance. We found that rubidium and potassium phase-segregate in highly concentrated clusters. Alkali metals are beneficial at low concentrations, where they homogenize the halide distribution, but at higher concentrations, they form recombination-active second-phase clusters., (Copyright © 2019 The Authors, some rights reserved; exclusive licensee American Association for the Advancement of Science. No claim to original U.S. Government Works.)

Published
2019
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