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1. Hydrophobic and Hydrophilic Solid-Fluid Interaction

   https://doi.org/10.1145/3550454.3555478  

   Liu, Jinyuan; Wang, Mengdi; Feng, Fan; Tang, Annie; Le, Qiqin; Zhu, Bo (December 2022, ACM Transactions on Graphics)

   We propose a novel solid-fluid coupling method to capture the subtle hydrophobic and hydrophilic interactions between liquid, solid, and air at their multi-phase junctions. The key component of our approach is a Lagrangian model that tackles the coupling, evolution, and equilibrium of dynamic contact lines evolving on the interface between surface-tension fluid and deformable objects. This contact-line model captures an ensemble of small-scale geometric and physical processes, including dynamic waterfront tracking, local momentum transfer and force balance, and interfacial tension calculation. On top of this contact-line model, we further developed a mesh-based level set method to evolve the three-phase T-junction on a deformable solid surface. Our dynamic contact-line model, in conjunction with its monolithic coupling system, unifies the simulation of various hydrophobic and hydrophilic solid-fluid-interaction phenomena and enables a broad range of challenging small-scale elastocapillary phenomena that were previously difficult or impractical to solve, such as the elastocapillary origami and self-assembly, dynamic contact angles of drops, capillary adhesion, as well as wetting and splashing on vibrating surfaces. 

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2. Interaction of Blood and Bacteria with Slippery Hydrophilic Surfaces

   https://doi.org/10.1002/admi.202300564  

   Kantam, Prem; Manivasagam, Vignesh_K; Jammu, Tarun_Kumar; Sabino, Roberta_Maia; Vallabhuneni, Sravanthi; Kim, Young_Jae; Kota, Arun_K; Popat, Ketul_C (October 2023, Advanced Materials Interfaces)

   Abstract Slippery surfaces (i.e., surfaces that display high liquid droplet mobility) are receiving significant attention due to their biofluidic applications. Non‐textured, all‐solid, slippery hydrophilic (SLIC) surfaces are an emerging class of rare and counter‐intuitive surfaces. In this work, the interactions of blood and bacteria with SLIC surfaces are investigated. The SLIC surfaces demonstrate significantly lower platelet and leukocyte adhesion (≈97.2% decrease in surface coverage), and correspondingly low platelet activation, as well as significantly lower bacterial adhesion (≈99.7% decrease in surface coverage of liveEscherichia Coliand ≈99.6% decrease in surface coverage of liveStaphylococcus Aureus) and proliferation compared to untreated silicon substrates, indicating their potential for practical biomedical applications. The study envisions that the SLIC surfaces will pave the path to improved biomedical devices with favorable blood and bacteria interactions. 

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3. Different temperature- and pressure-effects on the water-mediated interactions between hydrophobic, hydrophilic, and hydrophobic–hydrophilic nanoscale surfaces

   https://doi.org/10.1063/5.0097908  

   Engstler, Justin; Giovambattista, Nicolas (August 2022, The Journal of Chemical Physics)

   Water-mediated interactions (WMIs) are responsible for diverse processes in aqueous solutions, including protein folding and nanoparticle aggregation. WMI may be affected by changes in temperature and pressure, and hence, they can alter chemical/physical processes that occur in aqueous environments. Traditionally, attention has been focused on hydrophobic interactions while, in comparison, the role of hydrophilic and hybrid (hydrophobic–hydrophilic) interactions have been mostly overlooked. Here, we study the role of T and P on the WMI between nanoscale (i) hydrophobic–hydrophobic, (ii) hydrophilic–hydrophilic, and (iii) hydrophilic–hydrophobic pairs of (hydroxylated/non-hydroxylated) graphene-based surfaces. We find that hydrophobic, hydrophilic, and hybrid interactions are all sensitive to P. However, while hydrophobic interactions [case (i)] are considerably sensitive to T-variations, hydrophilic [case (ii)] and hybrid interactions [case (iii)] are practically T-independent. An analysis of the entropic and enthalpic contributions to the potential of mean force for cases (i)–(iii) is also presented. Our results are important in understanding T- and P-induced protein denaturation and the interactions of biomolecules in solution, including protein aggregation and phase separation processes. From the computational point of view, the results presented here are relevant in the design of implicit water models for the study of molecular and colloidal/nanoparticle systems at different thermodynamic conditions. 

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4. Solvent and crystallization effects on skin absorption of hydrophilic and lipophilic solutes

   Xu, Lijing (April 2023, James L. Winkle College of Pharmacy Research Forum)

   This publication was an oral presentation of Ms. Xu's research given at a college research conference on Apr. 1, 2023. 

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5. Nanoscale Friction of Hydrophilic and Hydrophobic Self-Assembled Monolayers in Water

   https://doi.org/10.1007/s11249-020-01301-0  

   Yang, Quanpeng; Nanney, Warren; Hu, Xiaoli; Ye, Tao; Martini, Ashlie (June 2020, Tribology Letters)