Physicochemical hydrodynamics of droplets in inkjet printing
Event details
Date | 13.10.2022 |
Hour | 10:15 › 11:15 |
Speaker | Prof. Detlef Lohse |
Location | Online |
Category | Conferences - Seminars |
Event Language | English |
Abstract :
Inkjet printing is the most widespread technological application of microfluidics. It is characterized by its high drop productivity, small volumes and extreme reproducibility. In this talk I will give a synopsis of the fluid dynamics of inkjet printing and discusses the main challenges for present and future research [1]. These lie both on the printhead side – namely the detailed flow inside the printhead, entrained bubbles, the meniscus dynamics, wetting phenomena at the nozzle plate, and jet formation – and on the receiving substrate side – namely droplet impact, merging, wetting of the substrate, droplet evaporation, and drying. In most cases the droplets are multicomponent, displaying rich physicochemical hydrodynamic phenomena [2]. The challenges on the printhead side and on the receiving substrate side are interwoven, as optimizing the process and the materials with respect to either the printhead side or the substrate side is not enough: As the same ink (or other jetted liquid) is used and as droplet frequency and size matter on both sides, the process must be optimized as a whole. One example for conflicting requirements from the printhead side on the one hand and from the receiving substrate or more specifically the paper side on the other hand is the volatility of the ink: At the nozzle, it would be preferable if the evaporation of ink were avoided to prevent nozzle clogging, but on the paper side, fast evaporation of ink is desirable to enable productive printing and to prevent paper deformation.
Even such a seemingly simple process as the evaporation of multicomponent droplets keeps surprising us through its richness of phenomena. I will show and explain several of such phenomena, namely evaporation-triggered segregation thanks to either weak solutal Marangoni flow or thanks to gravitational effects. The dominance of the latter implies that sessile droplets and pending droplets show very different evaporation behavior, even for Bond number << 1. I will also explain the full phase diagram in the Marangoni number vs Rayleigh number phase space, and show where Rayleigh convections rolls prevail, where Marangoni convection rolls prevail, and where they compete, and why these processes are very important in piezoacoustic inkjet printing. I will also extend these considerations to ternary and colloidal droplets and show and explain the new, fascinating, and often counter-intuitive phenomena which occur for these case of complex ink droplets.
[1] Detlef Lohse, Annu. Rev. Fluid Mech. 54, 349-382 (2022).
[2] Detlef Lohse and Xuehua Zhang, Nature Rev. Phys. 2, 426-443 (2020).
Speaker’s Bio
Detlef Lohse studied physics at the Universities of Kiel & Bonn (Germany), and got his PhD at Univ. of Marburg (1992). He then joined Univ. of Chicago as postdoc. After his habilitation (Marburg, 1997), in 1998 he became Chair at Univ. of Twente in the Netherlands and built up the Physics of Fluids group. Since 2015 he is also Member of the Max Planck Society and of the Max-Planck Institute in Göttingen. Lohse's present research interests include turbulence and multiphase flow and micro- and nanofluidics (bubbles, drops, inkjet printing, wetting). He does both fundamental and more applied science and combines experimental, theoretical, and numerical methods.
Lohse is Associate Editor of J. Fluid Mech. (among others journals) and serves as Chair of the Executive Board of the Division of Fluid Dynamics of the American Physical Society and Member of the Executive Board of IUTAM. He is Member of the (American) National Academy of Engineering (2017), of the Dutch Academy of Sciences (KNAW, 2005), the German Academy of Sciences (Leopoldina, 2002) and Fellow of APS (2002). He won various scientific prizes, among which the Spinoza Prize (NWO, 2005), the Simon Stevin Meester Prize (STW, 2009), the Physica Prize of the Dutch Physics Society (2011), the AkzoNobel Science Award (2012), two European Research Council Advanced Grants (2010 & 2017), the George K. Batchelor Prize (IUTAM, 2012), the APS Fluid Dynamics Prize (2017), the Balzan Prize (2018), and the Max Planck Medal (2019). In 2010, he got knighted to become “Ridder in de Orde van de Nederlandse Leeuw”.
Inkjet printing is the most widespread technological application of microfluidics. It is characterized by its high drop productivity, small volumes and extreme reproducibility. In this talk I will give a synopsis of the fluid dynamics of inkjet printing and discusses the main challenges for present and future research [1]. These lie both on the printhead side – namely the detailed flow inside the printhead, entrained bubbles, the meniscus dynamics, wetting phenomena at the nozzle plate, and jet formation – and on the receiving substrate side – namely droplet impact, merging, wetting of the substrate, droplet evaporation, and drying. In most cases the droplets are multicomponent, displaying rich physicochemical hydrodynamic phenomena [2]. The challenges on the printhead side and on the receiving substrate side are interwoven, as optimizing the process and the materials with respect to either the printhead side or the substrate side is not enough: As the same ink (or other jetted liquid) is used and as droplet frequency and size matter on both sides, the process must be optimized as a whole. One example for conflicting requirements from the printhead side on the one hand and from the receiving substrate or more specifically the paper side on the other hand is the volatility of the ink: At the nozzle, it would be preferable if the evaporation of ink were avoided to prevent nozzle clogging, but on the paper side, fast evaporation of ink is desirable to enable productive printing and to prevent paper deformation.
Even such a seemingly simple process as the evaporation of multicomponent droplets keeps surprising us through its richness of phenomena. I will show and explain several of such phenomena, namely evaporation-triggered segregation thanks to either weak solutal Marangoni flow or thanks to gravitational effects. The dominance of the latter implies that sessile droplets and pending droplets show very different evaporation behavior, even for Bond number << 1. I will also explain the full phase diagram in the Marangoni number vs Rayleigh number phase space, and show where Rayleigh convections rolls prevail, where Marangoni convection rolls prevail, and where they compete, and why these processes are very important in piezoacoustic inkjet printing. I will also extend these considerations to ternary and colloidal droplets and show and explain the new, fascinating, and often counter-intuitive phenomena which occur for these case of complex ink droplets.
[1] Detlef Lohse, Annu. Rev. Fluid Mech. 54, 349-382 (2022).
[2] Detlef Lohse and Xuehua Zhang, Nature Rev. Phys. 2, 426-443 (2020).
Speaker’s Bio
Detlef Lohse studied physics at the Universities of Kiel & Bonn (Germany), and got his PhD at Univ. of Marburg (1992). He then joined Univ. of Chicago as postdoc. After his habilitation (Marburg, 1997), in 1998 he became Chair at Univ. of Twente in the Netherlands and built up the Physics of Fluids group. Since 2015 he is also Member of the Max Planck Society and of the Max-Planck Institute in Göttingen. Lohse's present research interests include turbulence and multiphase flow and micro- and nanofluidics (bubbles, drops, inkjet printing, wetting). He does both fundamental and more applied science and combines experimental, theoretical, and numerical methods.
Lohse is Associate Editor of J. Fluid Mech. (among others journals) and serves as Chair of the Executive Board of the Division of Fluid Dynamics of the American Physical Society and Member of the Executive Board of IUTAM. He is Member of the (American) National Academy of Engineering (2017), of the Dutch Academy of Sciences (KNAW, 2005), the German Academy of Sciences (Leopoldina, 2002) and Fellow of APS (2002). He won various scientific prizes, among which the Spinoza Prize (NWO, 2005), the Simon Stevin Meester Prize (STW, 2009), the Physica Prize of the Dutch Physics Society (2011), the AkzoNobel Science Award (2012), two European Research Council Advanced Grants (2010 & 2017), the George K. Batchelor Prize (IUTAM, 2012), the APS Fluid Dynamics Prize (2017), the Balzan Prize (2018), and the Max Planck Medal (2019). In 2010, he got knighted to become “Ridder in de Orde van de Nederlandse Leeuw”.
Practical information
- General public
- Free
- This event is internal