Leveling and Drying Dynamics of Printed Liquid Films of Organic Semiconductor Solutions in OLED/OPV Applications

Sauer, Hans Martin; Braig, Felix; Dörsam, Edgar

doi:10.1002/admt.202000160

Cited by 13 publications

(8 citation statements)

References 38 publications

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“…In this work, high density anilox rollers (25 µm cell size) are utilized to achieve ultrathin films while minimizing the wavelength of modulations, allowing for faster leveling. [ 41 ] Based on measured film thicknesses and modulation wavelengths, the inks used here are estimated to level in ≈0.1–0.4s, significantly shorter than the observed drying times of ≈2 s. We note that it is possible to further decrease the ink viscosity to enhance leveling by changing the solvent ratio. For NiO x solutions mixed with ethanol (EtOH) and 2‐ME, increasing the amount of EtOH used decreases the viscosity of the solution (Figure S3, Supporting Information), which is to be expected since the viscosity of pure EtOH (1.1 mPa s) is smaller than the viscosity of pure 2‐ME (1.7 mPa s).…”

Section: Resultsmentioning

confidence: 84%

Eliminating the Perovskite Solar Cell Manufacturing Bottleneck via High‐Speed Flexography

Huddy

Scheideler

2022

Adv Materials Technologies

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Perovskite solar cells have potential to deliver terawatt‐scale power via low‐cost manufacturing. However, scaling is limited by slow, high‐temperature annealing of the inorganic transport layers and the lack of reliable, large‐area methods for depositing thin (<30 nm) charge transport layers (CTLs). We present a method for scaling ultrathin NiOx hole transport layers (HTLs) by pairing high‐speed (60 m min−1) flexographic printing with rapidly annealed sol–gel inks to achieve the fastest reported process for fabrication of inorganic CTLs for perovskites. By engineering precursor rheology for rapid film‐leveling, NiOx HTLs were printed with high uniformity and ultralow pinhole densities resulting in photovoltaic performance exceeding that of spin‐coated devices. Integrating these printed transport layers in planar inverted PSCs allows rapid fabrication of high‐efficiency (PCE > 15%) CsxFA1−xPbI solar cells with improved short circuit currents (Jsc) of 22.4 mA cm−2. Rapid annealing of the HTL accelerates total processing time by 60X, while maintaining the required balance of optoelectronic properties and the chemical composition for effective hole collection. These results build an improved understanding of ultrathin NiOx and reveal opportunities to enhance device performance via scalable manufacturing of inorganic CTLs.

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Section: Resultsmentioning

confidence: 84%

Eliminating the Perovskite Solar Cell Manufacturing Bottleneck via High‐Speed Flexography

Huddy

Scheideler

2022

Adv Materials Technologies

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“…Therefore the deposited films show higher RMS variability at lower concentration since they are unable to level and eliminate viscous fingering effects resulting from ink transfer during printing before the film is "frozen" in its final state by drying. [45,49] This shows that both the drying process and the ink viscosity must be considered when optimizing the film uniformity. Thicker wet films printed from higher viscosity inks dry slower, allowing more time for the film to level, which could result in more uniform films.…”

Section: Mapping the Optoelectronic Uniformity Of Printed Perovskite ...mentioning

confidence: 99%

Rapid 2D Patterning of High‐Performance Perovskites Using Large Area Flexography

Huddy,

Scheideler

2023

Adv Funct Materials

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Solution processing of metal halide perovskites offers the potential for efficient, high‐speed roll‐based manufacturing of emerging optoelectronic devices such as lightweight photovoltaics and light emitting diodes at lower cost than achievable with incumbent technologies (e.g., Silicon). However, current perovskite fabrication methods are limited in their speed, uniformity, and patterning resolution, relying on subtractive postdeposition scribing for integration of modules and device arrays. Here, a method for flexographic printing of MA0.6FA0.4PbI3 at 60 m min−1, the fastest reported perovskite absorber deposition and the first report of inline drying integrated with roll‐based printing, is presented. This process delivers high‐resolution patterning (< 3 µm line edge roughness) and precise thickness control through rheological design of precursor inks, allowing scalably printed 50 µm features over large areas (140 cm2), while obviating damaging scribing steps. 2D scanning photoluminescence (PL) is applied to resolve correlations between ink leveling dynamics and optoelectronic quality. Integrating these highly uniform printed perovskite absorbers into n‐i‐p planar perovskite solar cells, photovoltaic conversion efficiency up to 20.4% (0.134 cm2), the highest performance yet reported for any roll‐printed perovskite cells is achieved. This study, thus, establishes flexography as a scalable approach to deposit precisely‐patterned high‐quality perovskites extensible to applications in emitter and detector arrays.

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“…The distribution of colloidal particles significantly affects their target-oriented properties in functional films used as electrodes in lithium-ion secondary batteries and fuel cells 1,2 as well as in applications such as paints, 3 drug delivery, 4 and optical films. 5,6 It is desirable to control the particle stratification by adjusting process conditions ( e.g. , drying rate and solid concentration) in industrial processes, rather than modifying the material properties of colloidal particles.…”

Section: Introductionmentioning

confidence: 99%

Mild stratification in drying films of colloidal mixtures

et al. 2022

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Leveling and Drying Dynamics of Printed Liquid Films of Organic Semiconductor Solutions in OLED/OPV Applications

Cited by 13 publications

References 38 publications

Eliminating the Perovskite Solar Cell Manufacturing Bottleneck via High‐Speed Flexography

Eliminating the Perovskite Solar Cell Manufacturing Bottleneck via High‐Speed Flexography

Rapid 2D Patterning of High‐Performance Perovskites Using Large Area Flexography

Mild stratification in drying films of colloidal mixtures

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