Investigation of the Effect of 3D Meniscus Geometry on Fluid Dynamics and Crystallization via In Situ Optical Microscopy‐Assisted Mathematical Modeling. Issue 1 (20th October 2021)
- Record Type:
- Journal Article
- Title:
- Investigation of the Effect of 3D Meniscus Geometry on Fluid Dynamics and Crystallization via In Situ Optical Microscopy‐Assisted Mathematical Modeling. Issue 1 (20th October 2021)
- Main Title:
- Investigation of the Effect of 3D Meniscus Geometry on Fluid Dynamics and Crystallization via In Situ Optical Microscopy‐Assisted Mathematical Modeling
- Authors:
- Lee, Jeong‐Chan
Seo, Hyeji
Lee, Minho
Kim, Dongjae
Lee, Hyeon Seok
Park, Hyunmin
Ball, Nathaniel
Woo, Junhee
Kim, Su Yeong
Nam, Jaewook
Park, Steve - Abstract:
- Abstract: Solution‐based thin‐film solidification is a complex process involving various transport phenomena that are intricately dependent on multiple experimental parameters. The difficulty of analyzing this process experimentally or conducting exact numerical simulation make it challenging to understand, predict, and control the solidification process. In this work, a simple and effective technique to analyze the thin‐film solidification process during solution shearing, based on 3D geometrical model of the meniscus, is proposed. The 3D meniscus geometry, which changes depending on the experimental parameters, is attained using high‐speed side‐view and top‐view in situ microscopy. Thereafter, mass and momentum transport mathematical models are applied to obtain numerical solutions of transport phenomena within the meniscus. Utilizing these results, the underlying mechanism of dendritic growth of small molecule organic semiconductor is elucidated, which has previously been unknown. The 3D meniscus modeling is particularly important for this analysis, as dendrite formation is strongly dependent on the meniscus geometry near the contact line and mass transport variation perpendicular to the coating direction. This technique enables the study of complex relationship between experimental parameters and solidification process, which is widely applicable to various materials and coating systems; whereby, better understanding of thin‐film growth and device performanceAbstract: Solution‐based thin‐film solidification is a complex process involving various transport phenomena that are intricately dependent on multiple experimental parameters. The difficulty of analyzing this process experimentally or conducting exact numerical simulation make it challenging to understand, predict, and control the solidification process. In this work, a simple and effective technique to analyze the thin‐film solidification process during solution shearing, based on 3D geometrical model of the meniscus, is proposed. The 3D meniscus geometry, which changes depending on the experimental parameters, is attained using high‐speed side‐view and top‐view in situ microscopy. Thereafter, mass and momentum transport mathematical models are applied to obtain numerical solutions of transport phenomena within the meniscus. Utilizing these results, the underlying mechanism of dendritic growth of small molecule organic semiconductor is elucidated, which has previously been unknown. The 3D meniscus modeling is particularly important for this analysis, as dendrite formation is strongly dependent on the meniscus geometry near the contact line and mass transport variation perpendicular to the coating direction. This technique enables the study of complex relationship between experimental parameters and solidification process, which is widely applicable to various materials and coating systems; whereby, better understanding of thin‐film growth and device performance optimization is possible. Abstract : The 3D geometrical model of the meniscus is attained using high‐speed side‐view and top‐view in situ microscopy, within which a mathematical model for momentum and mass transport is developed. Utilizing 3D meniscus geometry, the underlying mechanism of dendritic growth of small molecule organic semiconductors is elucidated, which is widely applicable to various materials and coating systems. … (more)
- Is Part Of:
- Advanced materials. Volume 34:Issue 1(2022)
- Journal:
- Advanced materials
- Issue:
- Volume 34:Issue 1(2022)
- Issue Display:
- Volume 34, Issue 1 (2022)
- Year:
- 2022
- Volume:
- 34
- Issue:
- 1
- Issue Sort Value:
- 2022-0034-0001-0000
- Page Start:
- n/a
- Page End:
- n/a
- Publication Date:
- 2021-10-20
- Subjects:
- crystallization -- fluid dynamics -- in situ microscopy -- mathematical modeling -- meniscus
Materials -- Periodicals
Chemical vapor deposition -- Periodicals
620.11 - Journal URLs:
- http://onlinelibrary.wiley.com/journal/10.1002/(ISSN)1521-4095 ↗
http://onlinelibrary.wiley.com/ ↗ - DOI:
- 10.1002/adma.202105035 ↗
- Languages:
- English
- ISSNs:
- 0935-9648
- Deposit Type:
- Legaldeposit
- View Content:
- Available online (eLD content is only available in our Reading Rooms) ↗
- Physical Locations:
- British Library DSC - 0696.897800
British Library DSC - BLDSS-3PM
British Library HMNTS - ELD Digital store - Ingest File:
- 24521.xml