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1. Euler–Lagrange simulation of slurry droplet evaporation in spray drying using a kinetics-based drying model

   https://doi.org/10.1063/5.0259902  

   Bhattacharjee, Anurag; Gnanaskandan, Aswin (April 2025, Physics of Fluids)

   This paper presents a numerical model to describe the evaporation and drying of liquid droplets containing dissolved solids, relevant to processes like spray drying and spray pyrolysis in the food and pharmaceutical industries. A one-way coupled Euler–Lagrange approach is developed, where the gas flow inside the dryer is addressed in the Eulerian framework while the droplet dynamics and motion are tracked using the Lagrangian framework. In the Lagrangian framework, a novel and detailed kinetics-based multi-stage drying model is developed. The droplet level model is validated against experimental data for skim-milk droplet drying, showing strong agreement. Effects of different activation energy models are also analyzed and it is found that one model predicts the drying characteristics better than the other. Finally, large-scale three-dimensional simulations are performed on a lab scale spray dryer drying Maltodextrin solution in water. It is demonstrated that the model correctly predicts variation in final particle size distribution due to changes in drying air characteristics, paving way for the deployment of the model in predicting final particle characteristics in a spray dryer. 

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2. Modeling Solution Drying by Moving a Liquid-Vapor Interface: Method and Applications

   https://doi.org/10.3390/polym14193996  

   Tang, Yanfei; McLaughlan, John E.; Grest, Gary S.; Cheng, Shengfeng (October 2022, Polymers)

   A method of simulating the drying process of a soft matter solution with an implicit solvent model by moving the liquid-vapor interface is applied to various solution films and droplets. For a solution of a polymer and nanoparticles, we observe “polymer-on-top” stratification, similar to that found previously with an explicit solvent model. Furthermore, “polymer-on-top” is found even when the nanoparticle size is smaller than the radius of gyration of the polymer chains. For a suspension droplet of a bidisperse mixture of nanoparticles, we show that core-shell clusters of nanoparticles can be obtained via the “small-on-outside” stratification mechanism at fast evaporation rates. “Large-on-outside” stratification and uniform particle distribution are also observed when the evaporation rate is reduced. Polymeric particles with various morphologies, including Janus spheres, core-shell particles, and patchy particles, are produced from drying droplets of polymer solutions by combining fast evaporation with a controlled interaction between the polymers and the liquid-vapor interface. Our results validate the applicability of the moving interface method to a wide range of drying systems. The limitations of the method are pointed out and cautions are provided to potential practitioners on cases where the method might fail. 

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3. Material assembly by droplet drying: From mechanics theories to applications

   https://doi.org/10.1002/dro2.76  

   Chen, Ziyu; Peng, Kangyi; Xu, Baoxing (August 2023, Droplet)

   Abstract Evaporation of droplets composed of insoluble materials provides a low‐cost and facile route for assembling materials and structures in a wide spectrum of functionalities down to the nanoscale and also serves as a basis for innovating ink‐solution‐based future manufacturing technologies. This review summarizes the fundamental mechanics theories of material assembly by droplet drying both on solid and liquid substrates and in a fully suspended air environment. The evolution of assembly patterns, material deformation, and liquid flow during droplet drying and its response to external stimuli ranging from solution surfactant and pH value, surface geometric pattern and wettability, drying temperature, pressure environment, to electrical field have been highlighted to elucidate the coupling mechanisms between solid materials and liquid solutions and the manipulation strategies for material assembly through an either active or passive means. The recent progresses in ink‐based printing technologies with selected examples are also presented to illustrate the immediate applications of droplet drying, with a focus on printing electronic sensors and biomedical devices. The remaining challenges and emerging opportunities are discussed. 

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4. Exploring the role of hydrodynamic interactions in spherically confined drying colloidal suspensions

   https://doi.org/10.1063/5.0260883  

   Kundu, Mayukh; Kritika, Kritika; Wani, Yashraj M; Nikoubashman, Arash; Howard, Michael P (April 2025, The Journal of Chemical Physics)

   We study the distribution of colloidal particles confined in drying spherical freestanding droplets using both dynamic density functional theory (DDFT) and particle-based simulations. In particular, we focus on the advection-dominated regime typical of aqueous droplets drying at room temperature and systematically investigate the role of hydrodynamic interactions (HIs) during this nonequilibrium process. In general, drying produces transient particle concentration gradients within the droplet in this regime, with a considerable accumulation of particles at the droplet’s liquid–vapor interface. We find that these gradients become significantly larger with pairwise HIs between colloidal particles instead of a free-draining hydrodynamic approximation; however, the solvent’s boundary conditions at the droplet’s interface (unbounded, slip, or no-slip) do not have a significant effect on the particle distribution. DDFT calculations leveraging the radial symmetry of the drying droplet are in excellent agreement with particle-based simulations for free-draining hydrodynamics, but DDFT unexpectedly fails for pairwise HIs after the particle concentration increases during drying, manifesting as an ejection of particles from the droplet. We hypothesize that this unphysical behavior originates from an inaccurate approximation of the two-body density correlations based on the bulk pair correlation function, which we support by measuring the confined equilibrium two-body density correlations using particle-based simulations. We identify some potential strategies for addressing this issue in DDFT. 

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5. VLE-Based High Pressure Stationary Droplet Evaporation at Spray Detonation Conditions

   https://doi.org/10.2514/6.2024-1636  

   Srinivasan, Navneeth; Suryanarayan, Ramachandran; Zhang, Hongyuan; Ghosh, Abeetath; Dammati, Sai Sandeep; Poludnenko, Alexei; Yang, Suo (January 2024, American Institute of Aeronautics and Astronautics)

   This paper numerically investigates the evaporation characteristics of a single n-dodecane fuel droplet in high-pressure nitrogen environment relevant to rotating detonation engines. A validated computational fluid dynamics solver coupled with real-fluid thermophysical models is utilized. The effects of pressure, droplet temperature, and ambient gas temperature on the evaporation rate are analyzed by tracking the droplet diameter evolution. Two interface tracking techniques, namely a mean density-based method and a novel vapor-liquid equilibrium-based method, are implemented and compared. The results show appreciable deviations from the classical d2-law for droplet evaporation. Increasing the ambient temperature and droplet temperature (toward critical point) substantially accelerate the evaporation process. Meanwhile, higher pressures decrease the evaporation rate owing to slower species/thermal diffusions. At certain conditions, discernible differences are observed between the two interface tracking methods indicating deficiencies in the simple mean density approach. The paper demonstrates an effective computational framework for transcritical droplet evaporation simulations. And the generated high-pressure droplet evaporation datasets can inform sub-model development for spray combustion modeling. 

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