A two-step strategy for delivering particles to targets hidden within microfabricated porous media

Tan, Huanshu; Banerjee, Anirudha; Shi, Nan; Tang, Xiaoyu; Abdel‐Fattah, Amr I.; Squires, Todd M.

doi:10.1126/sciadv.abh0638

Cited by 19 publications

(24 citation statements)

References 49 publications

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“…A dead-end pore has been used to demonstrate various transport behaviors along a one-dimensional solute gradient (Figure ). − ,,,,,− As described above, H-shaped channels with open-end pores can also generate a one-dimensional concentration gradient of solutes. In the H-channel, a steady-state concentration gradient can be set up, which generates constant diffusioosmotic velocity along the wall.…”

Section: Microfluidic Systemsmentioning

confidence: 99%

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Diffusiophoresis, Diffusioosmosis, and Microfluidics: Surface-Flow-Driven Phenomena in the Presence of Flow

Shim

2022

Chem. Rev.

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Diffusiophoresis is the spontaneous motion of particles under a concentration gradient of solutes. Since the first recognition by Derjaguin and colleagues in 1947 in the form of capillary osmosis, the phenomenon has been broadly investigated theoretically and experimentally. Early studies were mostly theoretical and were largely interested in surface coating applications, which considered the directional transport of coating particles. In the past decade, advances in microfluidics enabled controlled demonstrations of diffusiophoresis of micro- and nanoparticles. The electrokinetic nature and the typical scales of interest of the phenomenon motivated various experimental studies using simple microfluidic configurations. In this review, I will discuss studies that report diffusiophoresis in microfluidic systems, with the focus on the fundamental aspects of the reported results. In particular, parameters and influences of diffusiophoresis and diffusioosmosis in microfluidic systems and their combinations are highlighted.

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Section: Microfluidic Systemsmentioning

confidence: 99%

Section: Concluding Remarks and Perspectivementioning

confidence: 99%

Diffusiophoresis, Diffusioosmosis, and Microfluidics: Surface-Flow-Driven Phenomena in the Presence of Flow

Shim

2022

Chem. Rev.

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“…Derjaguin first discovered DP under non-electrolyte gradients, 1 and later under electrolyte gradients to explain the high rates of latex deposition during the manufacture of rubber gloves. 2,3 Since then, DP has been leveraged for varied applications including polymer deposition on metals, [4][5][6][7] particle deposition and fouling of membranes, 8,9 transport in dead-end pores, [10][11][12][13] membraneless water filtration, 14 cleaning of fibers and fabrics, 15 particle trapping and separation, [16][17][18][19][20][21][22] self-propelling active particles [23][24][25] and solutoinertial interactions. [26][27][28] Recently, DP has been explored as a means to drive migration of oil droplets out of dead-end pores 10,29 or to deliver sensing and recovery agents to hidden oil in reservoirs for enhanced oil recovery (EOR).…”

Section: Introductionmentioning

confidence: 99%

“…[26][27][28] Recently, DP has been explored as a means to drive migration of oil droplets out of dead-end pores 10,29 or to deliver sensing and recovery agents to hidden oil in reservoirs for enhanced oil recovery (EOR). 12,13,[30][31][32] When low-salinity flood water, which is passed in the reservoir to remove oil, 33 comes in contact with high-salinity connate water present with the trapped oil in dead-end pores and cracks, salinity gradients arise that can potentially drive DP migration. However, reservoir temperatures significantly exceed room temperature, and most experimental studies of DP to date have been carried out under ambient laboratory conditions.…”

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Temperature dependence of diffusiophoresis via a novel microfluidic approach

et al. 2022

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Data‐Driven Intelligent Manipulation of Particles in Microfluidics

2022

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Automated manipulation of small particles using external (e.g., magnetic, electric and acoustic) fields has been an emerging technique widely used in different areas. The manipulation typically necessitates a reduced-order physical model characterizing the field-driven motion of particles in a complex environment. Such models are available only for highly idealized settings but are absent for a general scenario of particle manipulation typically involving complex nonlinear processes, which has limited its application. In this work, the authors present a data-driven architecture for controlling particles in microfluidics based on hydrodynamic manipulation. The architecture replaces the difficult-to-derive model by a generally trainable artificial neural network to describe the kinematics of particles, and subsequently identifies the optimal operations to manipulate particles. The authors successfully demonstrate a diverse set of particle manipulations in a numerically emulated microfluidic chamber, including targeted assembly of particles and subsequent navigation of the assembled cluster, simultaneous path planning for multiple particles, and steering one particle through obstacles. The approach achieves both spatial and temporal controllability of high precision for these settings. This achievement revolutionizes automated particle manipulation, showing the potential of data-driven approaches and machine learning in improving microfluidic technologies for enhanced flexibility and intelligence.

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A two-step strategy for delivering particles to targets hidden within microfabricated porous media

Cited by 19 publications

References 49 publications

Diffusiophoresis, Diffusioosmosis, and Microfluidics: Surface-Flow-Driven Phenomena in the Presence of Flow

Diffusiophoresis, Diffusioosmosis, and Microfluidics: Surface-Flow-Driven Phenomena in the Presence of Flow

Temperature dependence of diffusiophoresis via a novel microfluidic approach

Data‐Driven Intelligent Manipulation of Particles in Microfluidics

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