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Books on the topic 'Colloidal Experiments'

Author: Grafiati

Published: 6 September 2023

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1

I, Suh Kwang, and United States. National Aeronautics and Space Administration., eds. Sizing of colloidal particles and protein molecules in a hanging fluid drop. [Washington, D.C.]: National Aeronautics and Space Administration, 1995.

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2

1939-, Somasundaran P., Markovic B. 1957-, American Chemical Society. Division of Colloid and Surface Chemistry, and American Chemical Society Meeting, eds. Concentrated dispersion: Theory, experiment, and applications. Washington, DC: American Chemical Society, 2004.

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3

N, Ryan Joseph, and National Risk Management Research Laboratory (U.S.), eds. Colloid mobilization and transport in contaminant plumes: Field experiments, laboratory experiments, and modeling. Ada, OK: U.S. Environmental Protection Agency, National Risk Management Research Laboratory, 1999.

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4

N, Ryan Joseph, and National Risk Management Research Laboratory (U.S.), eds. Colloid mobilization and transport in contaminant plumes: Field experiments, laboratory experiments, and modeling. Ada, OK: U.S. Environmental Protection Agency, National Risk Management Research Laboratory, 1999.

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5

U, Totsche K., ed. Colloid and colloid-assisted transport of contaminants in porous media: Experimental evidence, theory, modelling. Oxford: Pergamon, 1998.

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6

McNelis, Anne M. Microgravity emissions laboratory testing of the physics of colloids in space experiment. [Cleveland, Ohio]: National Aeronautics and Space Administration, Glenn Research Center, 2002.

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7

Ploeg, Rutger Jan. Preservation of kidney and pancreas with the UK solution: Experimental and clinical studies. [The Netherlands: s.n.], 1991.

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8

Doherty, Michael P. The physics of hard spheres experiment on MSL-1: Required measurements and instrument performance. [Cleveland, Ohio]: National Aeronautics and Space Administration, Lewis Research Center, 1998.

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9

Aarts, D. G. A. L. Soft interfaces: the case of colloid–polymer mixtures. Oxford University Press, 2017. http://dx.doi.org/10.1093/oso/9780198789352.003.0013.

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In this chapter we discuss the interface of a phase separated colloid-polymer mixture. We start by highlighting a number of experimental studies, illustrating the richness of colloidal interface phenomena. This is followed by a derivation of the bulk phase behaviour within free volume theory. We subsequently calculate the interfacial tension using a squared gradient approach. The interfacial tension turns out to be ultralow, easily a million times smaller than a molecular interfacial tension. From the bulk and interface calculations we obtain the capillary length and compare to experiments, where good overall agreement is found. Finally, we focus on the thermal capillary waves of the interface and derive the static and dynamic height–height correlation functions, which describe the experimental data very well. We end with an outlook, where we address some outstanding questions concerning the behaviour of interfaces, to which colloids may provide unique insights.

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10

Furst, Eric M., and Todd M. Squires. Particle motion. Oxford University Press, 2018. http://dx.doi.org/10.1093/oso/9780199655205.003.0002.

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The movement of colloidal particles in simple and complex fluids and viscoelastic solids is central to the microrheology endeavor. All microrheology experiments measure the resistance of a probe particle forced to move within a material, whether that probe is forced externally or simply allowed to fluctuate thermally. This chapter lays a foundation of the fundamental mechanics of micrometer-dimension particles in fluids and soft solids. In an active microrheology experiment, a colloid of radius a is driven externally with a specifed force F (e.g.magnetic, optical, or gravitational), and moves with a velocity V that is measured. Of particular importance is the role of the Correspondence Principle, but other key concepts, including mobility and resistance, hydrodynamic interactions, and both fluid and particle inertia, are discussed. In passive microrheology experiments, on the other hand, the position of a thermally-uctuating probe is tracked and analyzed to determine its diffusivity.

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11

Furst, Eric M., and Todd M. Squires. Magnetic bead microrheology. Oxford University Press, 2018. http://dx.doi.org/10.1093/oso/9780199655205.003.0008.

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Magnetism is a convenient force for actively pulling colloidal particles in a material. Many materials of interest in a microrheology experiment have a negligible magnetic susceptibility, and so embedded magnetic particles can be subject to relatively strong forces by fields imposed from outside of the sample. These are usually generated by electromagnets, but can also include the use of permanent magnets, or a combination of both. Such “magnetic tweezers” are used as sensitive force probes, capable of generating forces ranging from femtonewtons to nanonewtons. Magnetic forces and magnetic materials are reviewed and magnetic tweezer designs discussed. Linear and non-linear measurements using magnetic tweezers are presented, including studies yield stress and shear thinning. The operating regime of magnetic tweezer microrheology is presented, which enables microrheology experiments to access stiffer materials.

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12

Furst, Eric M., and Todd M. Squires. Introduction. Oxford University Press, 2018. http://dx.doi.org/10.1093/oso/9780199655205.003.0001.

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General concepts of rheology and microrheology are presented, including basic concepts of the microrheology measurement, the characteristics of soft materials, rheological functions and principles of conventional rheometric measurements, as well as several common rheological properties that will be encountered throughout the text. Microrheology encompasses a set of rheometric methods or techniques with unique capabilities|a part of the experimental toolbox for characterizing the rheological properties of materials to aid their understanding, or help in the design of new materials. There are limitations to microrheology that are important to understand from the outset. Colloidal particles are central to all microrheology measurements. Basic concepts of colloid science, including typical probe chemistries, colloidal stability, characterization, and preparation are presented.

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13

Mestre, Francesc Sagués. Colloidal Active Matter: Concepts, Experimental Realizations, and Models. CRC Press LLC, 2022.

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14

Mestre, Francesc Sagués. Colloidal Active Matter: Concepts, Experimental Realizations, and Models. Taylor & Francis Group, 2022.

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15

Colloidal Active Matter: Concepts, Experimental Realizations, and Models. Taylor & Francis Group, 2022.

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16

Mestre, Francesc Sagués. Colloidal Active Matter: Concepts, Experimental Realizations, and Models. Taylor & Francis Group, 2022.

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17

Mestre, Francesc Sagués. Colloidal Active Matter: Concepts, Experimental Realizations, and Models. Taylor & Francis Group, 2022.

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18

Furst, Eric M., and Todd M. Squires. Microrheology. Oxford University Press, 2018. http://dx.doi.org/10.1093/oso/9780199655205.001.0001.

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We present a comprehensive overview of microrheology, emphasizing the underlying theory, practical aspects of its implementation, and current applications to rheological studies in academic and industrial laboratories. Key methods and techniques are examined, including important considerations to be made with respect to the materials most amenable to microrheological characterization and pitfalls to avoid in measurements and analysis. The fundamental principles of all microrheology experiments are presented, including the nature of colloidal probes and their movement in fluids, soft solids, and viscoelastic materials. Microrheology is divided into two general areas, depending on whether the probe is driven into motion by thermal forces (passive), or by an external force (active). We present the theory and practice of passive microrheology, including an in-depth examination of the Generalized Stokes-Einstein Relation (GSER). We carefully treat the assumptions that must be made for these techniques to work, and what happens when the underlying assumptions are violated. Experimental methods covered in detail include particle tracking microrheology, tracer particle microrheology using dynamic light scattering and diffusing wave spectroscopy, and laser tracking microrheology. Second, we discuss the theory and practice of active microrheology, focusing specifically on the potential and limitations of extending microrheology to measurements of non-linear rheological properties, like yielding and shear-thinning. Practical aspects of magnetic and optical tweezer measurements are preseted. Finally, we highlight important applications of microrheology, including measurements of gelation, degradation, high-throughput rheology, protein solution viscosities, and polymer dynamics.

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19

Colloid mobilization and transport in contaminant plumes: Field experiments, laboratory experiments, and modeling. Ada, OK: U.S. Environmental Protection Agency, National Risk Management Research Laboratory, 1999.

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20

(Editor), P. Somasundaran, and B. Markovic (Editor), eds. Concentrated Dispersions: Theory, Experiments, and Applications (Acs Symposium Series). An American Chemical Society Publication, 2004.

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21

Surface and Colloid Science : Volume 11: Experimental Methods. Springer, 2012.

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22

Good, R. Surface and Colloid Science : Volume 11: Experimental Methods. Springer, 2012.

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23

Good, R. Surface and Colloid Science : Volume 11: Experimental Methods. Springer London, Limited, 2012.

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24

Furst, Eric M., and Todd M. Squires. Interferometric tracking. Oxford University Press, 2018. http://dx.doi.org/10.1093/oso/9780199655205.003.0006.

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The purpose of this chapter is to present a survey of passive microrheology techniques that are important complements to more widely used particle tracking and light scattering methods. Such methods include back focal plane interferometry and extensions of particle tracking to measure the rotation of colloidal particles. Methods of passive microrheology using back focal plane interferometry are presented, including the experimental design and detector sensitivity and limits in frequency bandwidth and spatial resolution. The Generalized Stokes Einstein relation is derived from linear response theory of the particle position power spectrum and complex susceptibility. Applications of interoferometric tracking include high frequency microrheology and two-point measurements. Lastly, the chapter includes a discussion of rotational passive microrheology and the rotational GSER.

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25

Allen, Michael P., and Dominic J. Tildesley. Computer Simulation of Liquids. Oxford University Press, 2017. http://dx.doi.org/10.1093/oso/9780198803195.001.0001.

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This book provides a practical guide to molecular dynamics and Monte Carlo simulation techniques used in the modelling of simple and complex liquids. Computer simulation is an essential tool in studying the chemistry and physics of condensed matter, complementing and reinforcing both experiment and theory. Simulations provide detailed information about structure and dynamics, essential to understand the many fluid systems that play a key role in our daily lives: polymers, gels, colloidal suspensions, liquid crystals, biological membranes, and glasses. The second edition of this pioneering book aims to explain how simulation programs work, how to use them, and how to interpret the results, with examples of the latest research in this rapidly evolving field. Accompanying programs in Fortran and Python provide practical, hands-on, illustrations of the ideas in the text.

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