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Books on the topic 'Interface turbulent'

Author: Grafiati

Published: 20 April 2024

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1

Komori, Satoru. Turbulence structure and CO₂ transfer at the air-sea interface and turbulent diffusion in thermally-stratified flows. Tsukuba, Japan: Center for Global Environmental Research, National Institute for Environmental Studies, Environment Agency of Japan, 1996.

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2

Michael, Kelley, and Institute for Computer Applications in Science and Engineering., eds. Tracking a turbulent spot in an immersive environment. Hampton, VA: Institute for Computer Applications in Science and Engineering, NASA Langley Research Center, 1995.

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3

Michael, Kelley, and Institute for Computer Applications in Science and Engineering., eds. Tracking a turbulent spot in an immersive environment. Hampton, VA: Institute for Computer Applications in Science and Engineering, NASA Langley Research Center, 1995.

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4

Marcelo J.S. de Lemos. Turbulent Impinging Jets into Porous Materials. Berlin, Heidelberg: Springer Berlin Heidelberg, 2012.

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5

Carlo, Gualtieri, and Mihailovic Dragutin T, eds. Fluid mechanics of environmental interfaces. London: Taylor & Francis, 2008.

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6

Burgers-KPZ turbulence: Göttingen lectures. Berlin: Springer, 1998.

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7

Lorencez-González, Carlos Martín. Turbulent momentum transfer at a gas-liquid interface in horizontal stratified flow in a rectangular channel. 1994.

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8

Lyness, Karen S., and Hilal E. Erkovan. The Changing Dynamics of Careers and the Work–Family Interface. Edited by Tammy D. Allen and Lillian T. Eby. Oxford University Press, 2015. http://dx.doi.org/10.1093/oxfordhb/9780199337538.013.29.

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Although careers are an important part of people’s lives, career constructs have not always been well represented in the work–family (WF) literature. Accordingly, this chapter is written as a resource for WF scholars by providing a concise review of the rich career literature dating back over 100 years to show how conceptualizations of careers have evolved over time, with examples of key psychological and sociological theories that have enriched our understanding of careers. We also draw on the WF literature to illustrate how early career theories and concepts are still being applied to WF issues. We then focus on contemporary career theories and conceptualizations that reflect today’s turbulent work environment, and thus differ from traditional perspectives. In addition, we review the recent WF literature to examine how well these contemporary views of careers are represented, with examples of WF literature that illustrate the insights they offer. The chapter concludes with suggestions for further integration of ideas and constructs from the career literature in future WF research.

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9

National Aeronautics and Space Administration (NASA) Staff. Aspects of Turbulent / Non-Turbulent Interfaces. Independently Published, 2018.

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10

Kraus, Eric B., and Joost A. Businger. Atmosphere-Ocean Interaction. Oxford University Press, 1995. http://dx.doi.org/10.1093/oso/9780195066180.001.0001.

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With both the growing importance of integrating studies of air-sea interaction and the interest in the general problem of global warming, the appearance of the second edition of this popular text is especially welcome. Thoroughly updated and revised, the authors have retained the accessible, comprehensive expository style that distinguished the earlier edition. Topics include the state of matter near the interface, radiation, surface wind waves, turbulent transfer near the interface, the planetary boundary layer, atmospherically-forced perturbations in the oceans, and large-scale forcing by sea surface buoyancy fluxes. This book will be welcomed by students and professionals in meteorology, physical oceanography, physics and ocean engineering.

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11

Powell, Gregory Merlin. Structure of Velocity and Density Interfaces in a Weakly Turbulent Stratified Shear Flow. Creative Media Partners, LLC, 2018.

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12

(Editor), W. J. Plant, M. A. Donelan (Editor), and W. H. Hui (Editor), eds. The Air-Sea Interface: Radio and Acoustic Sensing, Turbulence and Wave Dynamics. University of Miami Iberian Studies Institute, 1996.

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13

Lemos, Marcelo J. S. de. Turbulent Impinging Jets into Porous Materials. Springer, 2012.

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14

Shiva, Sajjan G., Dragutin T. Mihailovic, and Carlo Gualtieri. Fluid Mechanics of Environmental Interfaces. Taylor & Francis Group, 2012.

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15

Shiva, Sajjan G., Dragutin T. Mihailovic, and Carlo Gualtieri. Fluid Mechanics of Environmental Interfaces. Taylor & Francis Group, 2012.

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16

Fluid Mechanics of Environmental Interfaces. Taylor & Francis Group, 2012.

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17

Mihailovic, Dragutin T., and Carlo Gualtieri. Fluid Mechanics of Environmental Interfaces. Taylor & Francis Group, 2018.

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18

Mihailovic, Dragutin T., and Carlo Gualtieri. Fluid Mechanics of Environmental Interfaces. Taylor & Francis Group, 2012.

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19

Shiva, Sajjan G., Dragutin T. Mihailovic, and Carlo Gualtieri. Fluid Mechanics of Environmental Interfaces. Taylor & Francis Group, 2012.

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20

Mihailovic, Dragutin T., and Carlo Gualtieri. Fluid Mechanics of Environmental Interfaces. Taylor & Francis Group, 2008.

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21

Shiva, Sajjan G., Dragutin T. Mihailovic, and Carlo Gualtieri. Fluid Mechanics of Environmental Interfaces. Taylor & Francis Group, 2012.

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22

Mihailovic, Dragutin T., and Carlo Gualtieri. Fluid Mechanics of Environmental Interfaces. Taylor & Francis Group, 2008.

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23

Shiva, Sajjan G., Dragutin T. Mihailovic, and Carlo Gualtieri. Fluid Mechanics of Environmental Interfaces. Taylor & Francis Group, 2012.

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24

Mihailovic, Dragutin T., and Carlo Gualtieri. Fluid Mechanics of Environmental Interfaces. Taylor & Francis Group, 2008.

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25

Sanz-Ramos, M., L. Cea, E. Bladé, D. López-Gómez, E. Sañudo, G. Corestein, G. García-Alén, and J. Aragón-Hernández. Iber v3. Reference manual and user's interface of the new implementations. CIMNE, 2022. http://dx.doi.org/10.23967/iber.2022.01.

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Iber is a two-dimensional hydraulic model for the simulation of free surface flow in rivers and estuaries, and the simulation of environmental processes in fluvial hydraulics. Since the release of the first version of Iber, which included a hydrodynamic calculation engine fully coupled with sediment transport processes and turbulence, it has evolved to become a free surface flow modelling tool for highly complex environmental processes. This document presents the developments made for version 3, where the advances are applied mainly in four current research lines: a new urban drainage module, a significant advance in the capabilities of the hydrological process module, a new soil erosion module, and a new module for calculating sediment transport considering non-uniform material (mixtures). Likewise, all the work has been accompanied by a cross-cutting task of improving the interface, both for existing modules and the creation of new windows and menus for new modules aiming to improve the whole workflow.

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26

Eckert, Michael. Turbulence--An Odyssey: Origins and Evolution of a Research Field at the Interface of Science and Engineering. Springer International Publishing AG, 2022.

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27

Davies, J. T. Turbulence Phenomena: An Introduction to the Eddy Transfer of Momentum, Mass, and Heat, Particularly at Interfaces. Elsevier Science & Technology Books, 2012.

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28

Succi, Sauro. The Lattice Boltzmann Equation. Oxford University Press, 2018. http://dx.doi.org/10.1093/oso/9780199592357.001.0001.

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Over the past near three decades, the Lattice Boltzmann method has gained a prominent role as an efficient computational method for the numerical simulation of a wide variety of complex states of flowing matter across a broad range of scales, from fully developed turbulence, to multiphase micro-flows, all the way down to nano-biofluidics and lately, even quantum-relativistic subnuclear fluids. After providing a self-contained introduction to the kinetic theory of fluids and a thorough account of its transcription to the lattice framework, this book presents a survey of the major developments which have led to the impressive growth of the Lattice Boltzmann across most walks of fluid dynamics and its interfaces with allied disciplines, such as statistical physics, material science, soft matter and biology. This includes recent developments of Lattice Boltzmann methods for non-ideal fluids, micro- and nanofluidic flows with suspended bodies of assorted nature and extensions to strong non-equilibrium flows beyond the realm of continuum fluid mechanics. In the final part, the book also presents the extension of the Lattice Boltzmann method to quantum and relativistic fluids, in an attempt to match the major surge of interest spurred by recent developments in the area of strongly interacting holographic fluids, such as quark-gluon plasmas and electron flows in graphene. It is hoped that this book may provide a source information and possibly inspiration to a broad audience of scientists dealing with the physics of classical and quantum flowing matter across many scales of motion.

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