Rational Ink Design and Combinatorial Slot-Die Coating of Metal Halide Perovskites for Solar Cells

Li, Jinzhao

06 December 2023

In dieser Dissertation wird eine umfassende Untersuchung von Perowskit-Tintenformulierungen für die Herstellung von hocheffizienten MAPbI3- und FAPbI3-Bauelementen durchgeführt. Darüber hinaus schlagen wir einen kombinatorischen Slot-Die-Beschichtungsansatz für das Screening und die Herstellung von Perowskit-Zusammensetzungen vor. Diese Ergebnisse zeigen, dass die Slot-Die-Beschichtung eine vielversprechende Technik für die Hochskalierung von Metallhalogenid-Perowskit-Dünnschichten ist. / This dissertation gives a comprehensive investigation into perovskite ink formulations for the fabrication of highly efficient MAPbI3 and FAPbI3 devices. Additionally, we propose a combinatorial slot-die coating approach for screening and fabricating perovskite compositions. These results demonstrate that slot-die coating is a promising technique for the upscaling of metal-halide perovskite thin-films.

Slot-Die-Beschichtung

Metallhalogenid-Perowskit

Kombinatorische Slot-Die-Beschichtung

Perowskit-Solarzellen

Slot-die coating

Metal halide perovskite

Combinatorial slot-die coating

Perovskite solar cells

541 Physikalische Chemie

ddc:541

Applied study and modeling of penetration depth for slot die coating onto porous substrates

Ding, Xiaoyu

08 June 2015

A distinctive field in the coatings industry is the coating of porous media, with broad applications in paper, apparel, textile, electronics, bioengineering, filtration and energy sector. A primary industrial scale process that can be used to coat porous media in a fast and flexible manner is slot die extrusion. A major concern when coating porous media with a wetting fluid is fluid penetration into the substrate. Although some level of penetration is desirable to obtain specific material properties, inadequate or excessive fluid penetration can negatively affect the strength, functionality or performance of the resulting material. In spite of its apparent industrial importance, limited modeling and experimental work has been conducted to study fluid penetration into porous media during fabrication. The effects of processing parameters on the penetration depth, the effects of penetration on material quality, and the method to predict and control the penetration depth are not well understood. This dissertation is composed of two parts. Part I is an applied study for coating onto porous media. This part focuses on the first objective of this dissertation which is to elucidate clearly the feasibility, advantages and disadvantages of the direct coating method as a potential fabrication route for membrane electrode assembly (MEA). MEA samples are fabricated using both traditional and the direct coating methods. Then, the quality and performance of the MEA samples are examined. Experimental results in Part I demonstrate that it is feasible to fabricate MEAs using the direct coating method. However, Nafion® solution penetrates into the catalyst layer during the coating process and causes lower performance of fuel cells, which is the motivation for Part II of this thesis. The objective of Part II is to fundamentally understand the fluid penetration process and predict the penetration depth when directly coating porous media, using a comprehensive approach. A series of computational and analytical models are developed to predict the penetration depth for both Newtonian and non-Newtonian fluids with or without capillary pressure. Finally the accuracy of developed models are validated through experiments. The relative error between the predicted and experimentally measured penetration depth is generally lower than 20%.

Slot die coating

Porous media

Fuel cell

Membrane electrode assembly

Penetration

Detection and elimination of defects during manufacture of high-temperature polymer electrolyte membranes

Bhamidipati, Kanthi Latha

02 March 2011

Defect generation and propagation in thin films, such as separation membranes, can lead to premature or catastrophic failure of devices such as polymer electrolyte membrane fuel cells (PEMFC). It is hypothesized that defects (e.g., air bubbles, pin-holes, and holes) originate during the manufacturing stage, if precise control is not maintained over the coating process, and they propagate during system operation. Experimental and numerical studies were performed to detect and eliminate defects that were induced during slot die coating of high-viscosity (1 to 40 Pa-s), shear-thinning solutions. The effects of fluid properties, geometric parameters and processing conditions on air entrainment and coating windows (limited set of processing conditions for which defect-free coating exists) were studied. When smaller slot gaps and coating gaps were used, relatively small bubbles were entrained in the coated film. The air bubble sizes increased as the viscosity of the coating solution decreased. A semi-empirical model correlating the maximum coating speed to a solution's material properties, geometric parameters and processing conditions was developed. Such a predictive model will enable engineers to determine the maximum coating boundary for shear-thinning and Newtonian solutions within certain constraints. Smaller coating gaps and low-viscosity solutions produced higher coating speeds. The surface tension property of the coating solution provided stability to the coating bead. Therefore, solutions with higher surface tension could be processed at higher coating speeds.

PEM

Slot die coating

Shear-thinning solutions

High-viscosity solutions

Coating windows

Air entrainment

Membranes (Technology)

Polyelectrolytes

Surfaces (Technology) Defects

Materiálový tisk světelných dozimetrů / Material printing of light dosimeters

Kabelková, Markéta

January 2019

This diploma thesis is focused on material printing of light dosimeters, especially printing of dosimeters for visible light and two types of UV radiation dosimeters. The aim of this work was to convert optimized systems from laboratory scale to pilot plant and to prepare individual systems for large-scale printing. The experimental part deals with the preparation and gradual scaling of compositions to a pilot scale, including optimization of individual components. Problems which were found during scaling up are discussed. A roll-to-roll material printer with slot-die technique was used to convert to a pilot scale. The prepared layers were exposed and their color changes was studied in detail. In addition to printing optimization, the thicknesses of the prepared layers and their resistance were determined, as well as tests of shelf life and reaction of dosimeters to ozone. According to the tests which were performed, guidelines for quality control of light dosimeters printing were compiled.

Quality Improvements for Anode Coating in Lithium-Ion Battery Cell Manufacturing : A Case Study at Northvolt Labs / Kvalitetsförbättringar för anodbeläggning vid tillverkning av litiumjonbattericeller : En fallstudie på Northvolt Labs

König, Nikolaj, Norlin, Johan

January 2021

Lithium-ion batteries (LIB) represent a promising energy storage solution in the pursuit of electrification to combat climate change. In order for LIBs to be used across different industries, they have to be commercially viable. The viability for manufacturing LIBs at scale is increasing, with manufacturing costs decreasing 89% in the last ten years. However, the LIB manufacturing process is complex and can generate large amounts of scrap due to various non-conformities (NCs). Therefore, to further increase the ability to manufacture high-quality LIBs at scale, it is crucial to minimize the occurrence of NCs by understanding their root causes. This thesis examines the characteristics of one of the non-conformities occurring in the electrode coating process, namely the formation of craters on the coated surface of the anode electrode. The thesis was conducted at Northvolt Labs using a DMAIC approach to establish relationships between various process parameters and the formation of craters in two processes, coating, and its precursor process, slurry mixing. Utilizing the data models linear regression, CART regression, regularized linear regression, and a slurry experiment, process parameters and characteristics that affect crater formation were identified. Firstly, from the data models, it was distinguished that the speed of the supply pump used in transferring the slurry from the supply tank to the slot die, and the pressure in the filter pump, have the largest effect on crater formation. Further, the time that the slurry spends in storage, i.e. from a completely mixed slurry batch to it being applied in coating, affects crater formation. In this case, the longer the slurry is stored, the more craters are found. Another notable result is that refilling the coating supply tank induces crater formation. The mentioned results indicate that the various stages of slurry transfer undertaken before coating can result in advantageous conditions for craters to form. Moreover, it was discovered that changes in the loading level of the coated anode surface can indicate crater formation. The slurry experiment discovered that by contaminating the slurry with lubricant grease, NCs with similar characteristics to the crater could be generated. While not likely related to craters, this result provides valuable insights for slurry contamination. In addition to the data models and experiments, actions to facilitate future statistical analysis investigations are proposed. This thesis also proposes actions that can be undertaken to potentially mitigate the formation of craters. Suggested actions include methods to investigate the optimal storage time of the slurry before used in coating. Further, we recommend that the coating process should be monitored through the use of control charts on the loading level measurements of the coated surface. Consequently, large changes in loading level can be detected, entailing potential crater formation. We also propose adding lubricant grease as a potential risk in the PFMEA Northvolt uses for process risk evaluation. This recommendation is also complemented with suggested actions on how to handle the risks of lubricant grease contamination. / Användandet av litiumjonbatterier (LIB) som energilagring är en potentiell lösning för omställning till ett elektrifierat samhälle. Tillverkningsprocessen för LIBs är dock komplex och har en tendens att generera stora mängder kassationer på grund av olika typer av defekter. Denna studie ämnar att undersöka egenskaperna hos en av defekterna som kallas krater som kan förekomma i en av delprocesserna för litiumjonbatteritillverkning, elektrodbeläggning, där batteriets elektroder skapas genom att en blandning av aktiva material appliceras på en metallfolie. Kratern förekommer som en cirkulär form på den belagda ytan av anodelektroden. Studien genomfördes hos batteritillverkaren Northvolt Labs och använde en struktur enligt DMAIC cykeln. Syftet med studien var att fastställa samband mellan olika processparametrar och kraterformation för två olika processer, elektrodbeläggning och dess föregångare, framställning av den aktiva materialblandningen. Genom att använda datamodellerna linjär regression, CART-regression, en regulariserad linjär regression  samt ett experiment kunde processparametrar och egenskaper som påverkar kraterbildningen etableras. Resultaten från datamodellerna indikerar att varvtalet i pumpen som tillför ytbeläggningsmaskinen med den aktiva materialblandningen samt trycket i filterpumpen har den största effekten på kraterbildning. Vidare så påverkar tiden som den aktiva materialblandningen lagras innan den används i beläggningsprocessen. Resultaten indikerar att ju längre tid en aktiv materialblandning lagras, desto mer kraterbildning. Samtliga resultat som nämnts ovan anvisar att de olika stadier den aktiva materialblandningen överförs bland olika behållare och verktyg kan ge upphov till kraterbildning. Ytterligare resultat från datamodellerna indikerar att en minskad tjocklek av den belagda ytan, mätt med enheten g/cm2, kan påvisa när kratrar uppstår. Detta resultat kan härledas till att kratrarna orsakar en nedåtbuktning i den belagda ytan. Utifrån experimentet med den aktiva materialblandningen kunde det fastlås att kraterliknande defekter kunde genereras genom att kontaminera blandningen med smörjfett. Dessa defekter är sannolikt inte besläktade med kratern, men dess uppkomst ger värdefulla insikter hur kontaminering kan påverka kvaliteten på den belagda ytan. Utöver resultat från datamodellerna och experimentet så presenterar även denna studie förslag på hur framtida undersökningar av statistisk karaktär kan förbättras. Studien föreslår också konkreta åtanganden som kan genomföras med syfte att reducera kraterbildning. Detta inkluderar hur ett projekt med syfte att fastslå den optimala lagringstiden för den aktiva materialblandningen innan den används i ytbeläggningsprocessen kan utformas. Vidare rekommenderas att ytbeläggningsprocessen övervakas med hjälp av att upprätta styrdiagram för ytbeläggningens nivåförändringar. Följaktligen kan stora förändringar i ytbeläggningens jämnhet detekteras, vilket kan vara en indikator på kraterbildning. Studien rekommenderar också att tillägga kontaminering av smörjfett i den aktiva materialblandningen som en potentiell risk i Northvolts PFMEA. Denna rekommendation kompletteras även med förslag på åtanganden som kan tas för att hantera risken för kontaminering av smörjfett.

Lithium-ion battery cells

slot die coating

data analysis

electrode

anode

non-conformities

Reliability and Maintenance

Tillförlitlighets- och kvalitetsteknik

Business Administration

Företagsekonomi

Materiálový tisk na R2R tiskovém stroji / Material printing on R2R printer

Knobová, Klára

January 2015

This diploma thesis deals with material printing using roll to roll material printer. Several kinds of printing inks were prepared and their parameters, like viscosity and homogeneity were optimized. Corona treated PET foil was used as the flexible substrate. Thin layers of function material were prepared by coating by using the smooth cylinder and slot die method. Layers homogeneity was characterized by optical density. Layer thickness was measured by profilometer.

[pt] ESCOAMENTOS DE SUPERFÍCIES LIVRE COM INTERFACE COMPLEXAS / [en] FREE SURFACE FLOWS WITH COMPLEX INTERFACES

PAULO ROBERTO DE CASTRO MENDES JUNIOR

30 March 2020

[pt] Diversos processos apresentam escoamentos com superfícies livres. Alguns desses processos vão além dos problemas de engenharia, incluindo questões cotidianas como gotas de chuva caindo do céu, água fluindo pelo rio ou através de uma torneira. Na indústria, o processo de extrusão e revestimento são dois exemplos de processos que são fortemente afetados pelo comportamento da interface. O modelo de interface livre mais comumente utilizado foi desenvolvido no século XIX e descreve como isotrópico o comportamento das interfaces e dependente de um único parâmetro, denominado tensão interfacial. Desde então, os avanços na área de reologia interfacial vêm mostrando que os fenômenos interfaciais são mais complexos e precisam de mais informações para serem modelados. Nesta linha de pensamento, este trabalho analisa o efeito da viscosidade interfacial na dinâmica do processo de extrusão e revestimento por slot, no qual o conjunto de equações diferenciais que governam o problema é resolvido pelo método dos elementos finitos. / [en] Several processes present free surfaces flows. Some of those processes go beyond engineering problems, including everyday issues like raindrops falling from the sky, water flowing down the river or through a faucet. In industry, extrusion and coating process are two examples of processes that are strongly affected by the behavior of the interface. The most commonly used free interface model was developed in the 19th century and describes as isotropic the behavior of interfaces and dependent on asingle parameter called interfacial tension. Since then, advances in the areaof interfacial rheology have been showing that the interfacial phenomena are more complex and accurate of more information to be modeled. In this line of thinking, this work analyzes the effect of interface viscosity on the dynamics of extrusion and slot coating process, in which the set of differential equations that governs the problem is solved by Finite Element method.

[pt] EXTRUSAO DE FLUIDO

[pt] VISCOSIDADES INTERFACIAIS

[pt] INTERFACES COMPLEXAS

[pt] REVESTIMENTO EM SLOT DIE

[en] EXTRUSION FLOW

[en] SURFACE VISCOSITY

[en] COMPLEX INTERFACES

[en] SLOT COATING FLOW

Synthesis and Ligand Engineering of Colloidal Metal Chalcogenide Nanoparticles for Scalable Solution Processed Photovoltaics

Ryan Gupta Ellis (9175325)

09 September 2022

<p>As global population continue to rise, the demand for energy is slated to increase substantially. To combat climate change, large amounts of renewable energy will be needed to feed this growing demand. Of renewable energy sources, photovoltaics are well positioned to meet this increasing demand due to the immense abundance of solar energy incident on earth. However, existing energy intensive, low throughput, and costly manufacturing techniques for photovoltaics may pose a barrier to continued large scale implementation.</p> <p>Solution processing has emerged as a promising photovoltaics fabrication technique with high throughput, high materials utilization, and lower cost than existing vacuum-based methods. Thin film photovoltaic materials such as Cu(In,Ga)(S,Se)₂ and CdTe have both been fabricated using various solution processing methods. Of the various solution processing routes, colloidal metal chalcogenide nanoparticles have demonstrated promise as a hydrazine-free route for the solution processing of high efficiency Cu(In,Ga)(S,Se)₂ solar cells. However, conventional solution processing with colloidal nanoparticles has long suffered from anionic and carbonaceous impurities, stemming from legacy synthesis methods. The work in this dissertation aims to solve these issues through the development of novel synthetic methods, ligand engineering, and ultimately improved scalability through slot-die coating.</p> <p> Typical colloidal syntheses rely on the use of metal salts as precursors such as metal halides, nitrates, acetates, and so forth, where the anions may incorporate and alter the electrical properties of the targeted nanomaterials. In this work, the recent advances in amine-thiol chemistry and its unique ability to solubilize many metal containing species are expanded upon. Alkylammonium metal thiolate species are easily formed upon addition of monoamine and dithiol to elemental Cu, In, Ga, Sn, Zn, Se, or metal chalcogenides such as Cu₂S and Ag₂S. These species were then used directly for the synthesis of colloidal nanoparticles without the need for any additional purification. The metal thiolate thermal decomposition pathway was studied, verifying that only metal chalcogenides and volatile byproducts are formed, providing a flexible route to compositionally uniform, phase pure, and anionic impurity-free colloidal nanoparticles including successful syntheses of In₂S₃, (In_xGa_1–x)₂S₃, CuInS₂, CuIn(S_xSe_1–x)₂, Cu(In_xGa_1–x)S₂, Cu₂ZnSnS₄, and AgInS₂. </p> <p>However, further impurities from deleterious carbonaceous residues originating from long chain native ligands were still a persistent problem. This impurity carbon has been observed to hinder grain formation during selenization and leave a discrete residue layer between the absorber layer and the back contact. An exhaustive hybrid organic/inorganic ligand exchange was developed in this work to remove tightly bound oleyalmine ligands through a combination of microwave-assisted solvothermal pyridine ligand stripping followed by inorganic capping with diammonium sulfide, yielding greater than 98% removal of native ligands via a rapid process. Despite the aggressive ligand removal, the nanoparticle stoichiometry remained largely unaffected when making use of the hybrid ligand exchange. Scalable blade coating of the ligand exchanged nanoparticle inks from non-toxic dimethyl sulfoxide inks yielded remarkably smooth and crack free films with RMS roughness less than 7 nm. Selenization of ligand exchanged nanoparticle films afforded substantially improved grain growth as compared to conventional non-ligand exchanged methods yielding an absolute improvement in device efficiency of 2.8%. Hybrid ligand exchange nanoparticle-based devices reached total-area power conversion efficiencies of 12.0%.</p> <p>While extremely effective in ligand removal, ligand exchange pathways increase process complexity and solvent usage substantially, which may limit the cost advantage solution processing aims to provide. Further synthesis improvement was developed through a ligand exchange free, direct sulfide capped strategy. Using sulfolane as a benign solvent, CuInS₂ nanoparticles with thermally degradable thioacetamide ligands were synthesized using thermal decomposition of isolated metal thiolates from Cu₂S and In precursors. Through gentle thermal treatment, these ligands decomposed into non-contaminating gaseous byproducts leaving carbon free nanoparticle films without the need for ligand exchange.</p> <p>With the development of virtually contamination free colloidal nanoparticle inks, focus was shifted to scalability using slot die coating. Unlike typical lab-scale coating techniques such as spin coating, slot die coating is a widely used industrial coating technique with nearly 100% materials utilization, and high throughput roll-to-roll compatibility. A custom lab-scale slot-die coater was used to rapidly proof coating conditions, which were rapidly analyzed for uniformity using absorbance scanning in conjunction with profilometry. A cosolvent chlorobenzene/dichlorobenzene ink was developed to yield highly uniform, crack free thin films from non-ligand-exchanged Cu(In,Ga)S₂ nanoparticles, which were finished into devices with champion total are efficiencies of 10.7%. To the best of our knowledge, this represents the first report of slot die coated Cu(In,Ga)(S,Se)₂ photovoltaics. The methods presented in this work offer a pathway towards low impurity, high efficiency, scalable solution processed Cu(In,Ga)(S,Se)₂ photovoltaics to enable low cost renewable energy.</p>

Nanochemistry

Supramolecular chemistry

Nanoparticle

CIGS

CIGSSe

Photovoltaics

Solution Processing

Slot-Die

Ligand Exchange

Selenization