Synthesis cost dictates the commercial viability of lead sulfide and perovskite quantum dot photovoltaics

Jean, Joel; Xiao, Jianxiong; Nick, Robert; Moody, Nicole; Nasilowski, Michel; Bawendi, Moungi G.; Bulović, Vladimir

doi:10.1039/c8ee01348a

Cited by 125 publications

(122 citation statements)

References 29 publications

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“…In a separate synthetic step, OAcapped PbS QDs are exchanged with short ligands in solution and then suspended at a high concentration in a solvent to form an ink. [8] In addition to this added cost, the toxicological properties, environmental impact, and end-of-life disposal of Pb-based PVs, including perovskites, is of critical importance and has received only minimal attention. [1] With this advancement the fabrication of the active layer is now more facile, however, the scalability of PbS QD solar cells is still uncertain.…”

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confidence: 99%

Decreased Synthesis Costs and Waste Product Toxicity for Lead Sulfide Quantum Dot Ink Photovoltaics

Moody

Yoon

Johnson

et al. 2019

Advanced Sustainable Systems

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the photoactive QD films, leading to poor QD PV device performance. [5] It has been shown that a significant improvement in QD PV performance can be achieved if the deposited PbS QD films are chemically treated to undergo ligand exchange, replacing OA with shorter ligands, such as halides and short-chain thiols, which leads to high charge conductivities within QD films, boosting the power conversion efficiency of QD PVs. [5] Solution-phase ligand exchange is currently the leading method of preparing the active layers in top-performing PbS QD PVs. In a separate synthetic step, OAcapped PbS QDs are exchanged with short ligands in solution and then suspended at a high concentration in a solvent to form an ink. [1][2][3][4] This ink can then be deposited on a substrate to form the QD PV device active layer, [1][2][3][4] with recently reported PbS QD PVs achieving 12% power conversion efficiency (PCE). [1] With this advancement the fabrication of the active layer is now more facile, however, the scalability of PbS QD solar cells is still uncertain. A recent report by Jean et al. revealed that current solutionphase QD ligand exchange methods create an added cost of $6.30 g −1 of QDs, an expense that negatively impacts the commercial viability of QD PV modules. [8] In addition to this added cost, the toxicological properties, environmental impact, and end-of-life disposal of Pb-based PVs, including perovskites, is of critical importance and has received only minimal attention. [9][10][11] For example, the leading PbS QD ligand exchange procedures employing lead halides such as lead(II) bromide [1][2][3] and lead(II) iodide [1][2][3][4] have yet to be evaluated with regards to U.S. Environmental Protection Agency and European Union regulatory limits.In this study, we present a solution-phase ligand exchange method that reduces the amount of utilized lead by employing tetrabutylammonium iodide (TBAI) as the source of iodide ligands. The resulting PbS QD PVs have a 10% PCE under AM1.5 illumination, with more than 1000 h of storage stability when stored unpackaged in ambient conditions. Importantly, this synthetic methodology is evaluated with regards to its ability to lower costs and toxicity compared to the current champion lead halide (PbX 2 ) based ligand exchange methods. [1] This work provides a potential pathway toward improved compatibility with industrial scale thin-film PV device production as well as a framework to test the toxicity of new device fabrication procedures for a wide range of PVs. Use of lead sulfide (PbS) colloidal quantum dot (QD) films as photoactive layers in photovoltaic (PV) devices typically requires replacement of nativeQD ligands with lead-based capping ligands (i.e., PbX 2 , X = Br, I) for the best-performing QD PVs. This ligand replacement process often requires additional solvents and toxic reagents. In the present study, an alternative PbS QD PV fabrication method with a lead-free tetrabutylammonium iodide (TBAI) ligand source and lower material requirements and toxicity is demonstrated,...

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Decreased Synthesis Costs and Waste Product Toxicity for Lead Sulfide Quantum Dot Ink Photovoltaics

Moody

Yoon

Johnson

et al. 2019

Advanced Sustainable Systems

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“…Finally, large‐scale and cost‐efficient production of robust QDs with precisely controlled optical properties, high photo and thermal stability, preprogrammed chemical compositions, and long shell life can catalyze fast future progress. This acceleration has already happened very recently in a wide range of general commercial applications, such as in the field of large TV and large panel displays with enhanced brightness and colored characteristics due to the embedded QD‐containing light sources and multicolored pixels …”

Section: Qd Composite Structure For Lasingmentioning

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Composite Structures with Emissive Quantum Dots for Light Enhancement

Smith

Lin

et al. 2018

Advanced Optical Materials

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The optical properties of these nanostructures can be controlled via precise control of the synthetic parameters resulting in a wide range of chemical compositions, shapes, and dimensions. QDs are quite advantageous in comparison to traditional organic dye counterparts, offering size, and composition dependent energy band gaps (i.e., tunable absorption and photoluminescence), prospective excellent photostability, and solution and aqueous processability based on choice of surface chemistries. [2] Intense research in this field in the past two decades has focused on precisely engineering core-shell composition of QD nanostructures resulting in an appreciable impact on the field of photonic materials and structures to develop composite nanomaterials with precise control of refractive index, permittivity, and permeability.QDs are the promising candidate to control interactions in photonic systems in many respects due to their enhanced photostability, near 100% quantum yield, and versatile surface chemistry. More recently, facile synthetic techniques for large-scale high-quality production have been introduced that involve wet chemical processes to expand applicability of these components in light-managements devices. [5][6][7] However, the overall processability and scalability of these components into robust large-area structures are still a critical concern limiting real-life implementation in robust designs. While there are many techniques to produce QDs, common limitations for this class of nanomaterials are low quantity, large dispersibility in size, compositional nonuniformity, and the presence of excess passive components resulting from wet chemistry synthetic procedures (e.g., ligands).Providing a convenient host matrix not only overcomes some of these common limitations but allows for QDs to be used in more technologically exploitable forms such as robust, flexible, mechanically and chemically stable fibers, coatings, films, and patterns. [8] For such composite systems, inclusion of nanoparticles into sophisticated matrices typically results in the significant improvements of thermal, mechanical, electrical, and optical stabilities making them more applicable in device environment than other traditional organic materials.While the concept of embedding various nanostructures into different surrounding materials is not new, synthetic techniques required to combine these can be rather complex. Most Since their inception, quantum dots have proven to be advantageous for light management applications due to their high brightness and wellcontrolled absorption, scattering, and emission properties. As quantum dots become commercially available at large scale, the need for robust, stable, and flexible optical components continues to drive the development of robust and flexible quantum dot composite materials. In this review, after a thorough introduction to quantum dots, discussion delves into methods for fabricating quantum dot loaded composite optical elements such as thin films, microfabricated patterns, and micros...

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“…The research group of Vladimir Bulović of the Massachusetts Institute of Technology finds that this approach of focusing solely on PCE might not be the most favorable route to commercialization of this technology. 5 They found that the CQD synthesis step currently limits production costs. They also found that the currently used hot-injection synthesis method is significantly capital-intensive, owing to low yields and therefore incompatible with industrial scale-up.…”

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“…6 The heat-up method allows for high yields resulting in reduced synthesis costs down to USD$0.15/W from USD$0.51/W for the hot-injection method (compared to <USD$0.4/W for commercial silicon PV). 5 Additional encapsulant layers and balance-ofmodule components required for CQD PV, however, expectedly increase this number significantly. Jean et al 5 present guidelines to reduce CQD synthesis costs to as low as USD$0.05/W, including avoiding expensive precursors, deploying lowergrade precursors, and recycling solvents.…”

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“…5 Additional encapsulant layers and balance-ofmodule components required for CQD PV, however, expectedly increase this number significantly. Jean et al 5 present guidelines to reduce CQD synthesis costs to as low as USD$0.05/W, including avoiding expensive precursors, deploying lowergrade precursors, and recycling solvents. The article also discusses the commercial prospects of CsPbI 3 CQDs, and the analysis suggests these to be significantly more expensive than PbS CQD PV.…”

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