Ranojoy Duffadar scite author profile

This experimental study explores the capture and manipulation of micrometer-scale particles by single surface-immobilized nanoparticles. The nanoparticles, approximately 10 nm in diameter, are cationic and therefore attract the micrometer-scale silica particles in an analyte suspension. The supporting surface on which the nanoparticles reside is negative (also silica) and repulsive toward approaching microparticles. In the limit where there are as few as 9 nanoparticles per square micrometer of collector, it becomes possible to capture and hold micrometer-scale silica particles with single nanoparticles. The strong nanoparticle-microparticle attractions, their nanometer-scale protrusion forward of the supporting surface, and their controlled density on the supporting surface facilitate microparticle-surface contact occurring through a single nanoelement. This behavior differs from most particle-particle, cell-cell, or particle (or cell)-surface interactions that involve multiple ligand-receptor bonds or much larger contact areas. Despite the limited contact of microparticles with surface-immobilized nanoparticles, microparticles resist shear forces of 9 pN or more but can be released through an increase in the ionic strength. The ability of nanoparticles to reversibly trap and hold much larger targets has implications in materials self-assembly, cell capture, and sorting applications, whereas the single point of contact affords precision in particle manipulation.

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Practical Guide to Lost Returns Treatment Selection Based on a Holistic Model of the State of the Near Wellbore Stresses

Duffadar

Dupriest

Zeilinger

2013

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This paper presents a holistic model describing the relationship between the state of the hoop stress in a given well and the selection of lost circulation treatments. While some losses are vugular, the majority of lost returns events are due to the propagation of a fracture that develops when the borehole pressure overcomes the total hoop stress, which is the stress holding the hole closed. Although methods such as casing drilling, lost circulation pills or continuous fracture sealing fluids appear dissimilar, each stops losses by modifying the hoop stress. If a treatment does not modify the stress holding the hole closed, it does not change the pressure at which the borehole will open. This unifying concept is not always apparent to engineers and operations personnel since treatments are described to act in ways as diverse and seemingly unrelated as tip plugging, sealing, smearing, etc. Consequently, those who develop and execute new treatments may not be asking important questions that could further improve treatment performance and operational practices.In the proposed model, the potential state of the hoop stress is placed on a single pathway that is divided into four distinct regimes. At one end of the spectrum are those treatments that prevent losses by simply ensuring that the ideal hoop stress predicted by Kirsch is preserved. At the other end of the spectrum are severely depleted wells where treatments must achieve very large increases in hoop stress. Common industry treatments are categorized by the hoop stress regime in which they are applicable, and the conceptual limit to which each might enhance integrity is discussed.The authors' purpose in describing these concepts and treatments within a holistic hoop stress continuum is to improve treatment selection, facilitate field diagnostics, and highlight the need for further research in some areas.

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Ranojoy Duffadar

Dynamic adhesion behavior of micrometer-scale particles flowing over patchy surfaces with nanoscale electrostatic heterogeneity

The impact of nanoscale chemical features on micron-scale adhesion: Crossover from heterogeneity-dominated to mean-field behavior

Interaction of micrometer-scale particles with nanotextured surfaces in shear flow

Manipulating Microparticles with Single Surface-Immobilized Nanoparticles

Practical Guide to Lost Returns Treatment Selection Based on a Holistic Model of the State of the Near Wellbore Stresses

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