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Published: 30 May 2022
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1

Canada, Canada Natural Resources. Renewable energy strategy: Creating a new momentum. Ottawa, Ont: Natural Resources Canada, 1996.

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2

Canada. Natural Resources Canada. Renewable energy strategy: Creating a new momentum, summary. [Ottawa]: Natural Resources Canada, 1996.

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3

Bonnett, George M. Anatomy of the collision: Energy, momentum, restitution and the reconstructionist. 2nd ed. Jacksonville, Fla: Institute of Police Technology and Management, University of North Florida, 2006.

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4

Fennelly, A. J. Inflation in Einstein-Cartan theory with improved energy-momentum tensor with spin. [Washington, DC?: National Aeronautics and Space Administration, 1988.

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5

Fennelly, A. J. Inflation in Einstein-Cartan theory with improved energy-momentum tensor with spin. [Washington, DC?: National Aeronautics and Space Administration, 1988.

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6

Fennelly, A. J. Inflation in Einstein-Cartan theory with improved energy-momentum tensor with spin. [Washington, DC?: National Aeronautics and Space Administration, 1988.

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7

Fennelly, A. J. Inflation in Einstein-Cartan theory with improved energy-momentum tensor with spin. [Washington, DC?: National Aeronautics and Space Administration, 1988.

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8

Fennelly, A. J. Inevitable inflation in Einstein-Cartan theory with improved energy-momentum tensor with spin. [Washington, DC?: National Aeronautics and Space Administration, 1988.

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9

Coupled dynamics in soil: Experimental and numerical studies of energy, momentum and mass transfer. Berlin: Springer, 2013.

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10

Yanagihara, Ryosuke. Distribution of Energy Momentum Tensor around Static Charges in Lattice Simulations and an Effective Model. Singapore: Springer Singapore, 2021. http://dx.doi.org/10.1007/978-981-16-6234-8.

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11

Wang, Yinkun. Energy dispersive x-ray diffraction system: A response function for the CZT detector and an analysis of noise a low momentum transfer arguments. Sudbury, Ont: Laurentian University, School of Graduate, 2006.

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12

Momentum. New York: Holiday House, 2012.

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13

V, Radyushkin A., Stoler Paul, and Thomas Jefferson National Accelerator Facility (U.S.), eds. Exclusive processes at high momentum transfer: May 15-18, 2002, Jefferson Lab, Newport News, Virginia. River Edge, NJ: World Scientific, 2002.

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14

Papanikolaou, N. Handbook of calculated electron momentum distributions, compton profiles, and x-ray form factors of elemental solids. Boca Raton: CRC Press, 1991.

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15

Yudaev, Vasiliy. Hydraulics. ru: INFRA-M Academic Publishing LLC., 2021. http://dx.doi.org/10.12737/996354.

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The textbook corresponds to the general education programs of the general courses "Hydraulics" and "Fluid Mechanics". The basic physical properties of liquids, gases, and their mixtures, including the quantum nature of viscosity in a liquid, are described; the laws of hydrostatics, their observation in natural phenomena, and their application in engineering are described. The fundamentals of the kinematics and dynamics of an incompressible fluid are given; original examples of the application of the Bernoulli equation are given. The modes of fluid motion are supplemented by the features of the transient flow mode at high local resistances. The basics of flow similarity are shown. Laminar and turbulent modes of motion in pipes are described, and the classification of flows from a creeping current to four types of hypersonic flow around the body is given. The coefficients of nonuniformity of momentum and kinetic energy for several flows of Newtonian and non-Newtonian fluids are calculated. Examples of solving problems of transient flows by hydraulic methods are given. Local hydraulic resistances, their use in measuring equipment and industry, hydraulic shock, polytropic flow of gas in the pipe and its outflow from the tank are considered. The characteristics of different types of pumps, their advantages and disadvantages, and ways of adjustment are described. A brief biography of the scientists mentioned in the textbook is given, and their contribution to the development of the theory of hydroaeromechanics is shown. The four appendices can be used as a reference to the main text, as well as a subject index. Meets the requirements of the federal state educational standards of higher education of the latest generation. For students of higher educational institutions who study full-time, part-time, evening, distance learning forms of technological and mechanical specialties belonging to the group "Food Technology".
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16

Wittman, David M. Energy and Momentum. Oxford University Press, 2018. http://dx.doi.org/10.1093/oso/9780199658633.003.0012.

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Tis chapter explains the famous equation E = mc2 as part of a wider relationship between energy, mass, and momentum. We start by defning energy and momentum in the everyday sense. We then build on the stretching‐triangle picture of spacetime vectors developed in Chapter 11 to see how energy, mass, and momentum have a deep relationship that is not obvious at everyday low speeds. When momentum is zero (a mass is at rest) this energy‐momentum relation simplifes to E = mc2, which implies that mass at rest quietly stores tremendous amounts of energy. Te energymomentum relation also implies that traveling near the speed of light (e.g., to take advantage of time dilation for interstellar journeys) will require tremendous amounts of energy. Finally, we look at the simplifed form of the energy‐momentum relation when the mass is zero. Tis gives us insight into the behavior of massless particles such as the photon.
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17

Mansuripur, Masud, ed. Field, Force, Energy and Momentum in Classical Electrodynamics. BENTHAM SCIENCE PUBLISHERS, 2012. http://dx.doi.org/10.2174/97816080525301110101.

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18

Engineering Mechanics: Solids: Energy and Momentum (Engineering Mechanics: Solids). Open University Worldwide, 1990.

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19

Bonnett, George M. Anatomy of the collision: Energy, momentum, restitution, and the reconstructionist. Institute of Police Technology and Management, University of North Florida, 1999.

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20

Mansuripur, Masud, ed. Field, Force, Energy and Momentum in Classical Electrodynamics (Revised Edition). BENTHAM SCIENCE PUBLISHERS, 2017. http://dx.doi.org/10.2174/97816810855621170101.

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21

Energy and the Environment (Momentum Literacy Program, Step 6, Level D). Troll, 2000.

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22

Troop, Michael Scott. The interaction of energy and momentum in gradually varied open channel flow. 2007, 2007.

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23

Zeng, Yijian. Coupled Dynamics in Soil: Experimental and Numerical Studies of Energy, Momentum and Mass Transfer. Springer, 2012.

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24

Zeng, Yijian. Coupled Dynamics in Soil: Experimental and Numerical Studies of Energy, Momentum and Mass Transfer. Springer, 2015.

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25

United States. National Aeronautics and Space Administration., ed. An analysis code for the Rapid Engineering Estimation of Momentum and Energy Losses (REMEL). [Washington, DC]: National Aeronautics and Space Administration, 1994.

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26

United States. National Aeronautics and Space Administration., ed. An analysis code for the Rapid Engineering Estimation of Momentum and Energy Losses (REMEL). [Washington, DC]: National Aeronautics and Space Administration, 1994.

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27

del Guayo, Iñigo, Lee Godden, Donald D. Zillman, Milton Fernando Montoya, and José Juan González, eds. Energy Justice and Energy Law. Oxford University Press, 2020. http://dx.doi.org/10.1093/oso/9780198860754.001.0001.

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Energy justice has emerged as a matter of vital concern in energy law, with resonances in the attention directed to energy poverty, and the United Nations Sustainable Development Goals. There are energy justice concerns in areas of law as diverse as human rights, consumer protection, international law and trade, and in many forms of regional and national energy law and regulation. The book covers main themes related to justice. Distributive justice, the equitable distribution of the benefits and burdens of energy activities, is challenged mainly by the existence of people suffering from energy poverty. This concept is also associated with substantive energy equity through such measures as the realization of ‘energy’ rights. There is also a procedural (or participation) justice, consisting in the right of all communities to participate in decision-making regarding energy projects and policies that affect them (this dimension of energy justice often includes procedural rights to information and access to courts). Under the concept of reparation (or restorative) justice, the book includes even-handed enforcement of energy statutes and regulations, as well as access to remedies when legal rights are violated. Finally, the idea of recognition or social justice means that energy injustice cannot be separated from other social ills, such as poverty and subordination based on caste, race, gender, or indigeneity, the need to take into account people who are often ignored. These issues are given specific momentum by thinking through how we might achieve a ‘just’ energy transition as the world faces the climate change challenges.
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28

Ring, Jordan. Volcanic Momentum: Get Things Done by Setting Destiny Goals, Mastering the Energy Code, and Never Losing Steam. Jordan Ring, 2018.

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29

Gordon, R. J. Calculation and Measurement Techniques for Momentum, Energy and Mass Transfer (Aichemi Modular Instruction Series C : Transport Vol 7). American Institute of Chemical Engineers, 1988.

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30

Deruelle, Nathalie, and Jean-Philippe Uzan. The Maxwell equations. Oxford University Press, 2018. http://dx.doi.org/10.1093/oso/9780198786399.003.0030.

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This chapter presents Maxwell equations determining the electromagnetic field created by an ensemble of charges. It also derives these equations from the variational principle. The chapter studies the equation’s invariances: gauge invariance and invariance under Poincaré transformations. These allow us to derive the conservation laws for the total charge of the system and also for the system energy, momentum, and angular momentum. To begin, the chapter introduces the first group of Maxwell equations: Gauss’s law of magnetism, and Faraday’s law of induction. It then discusses current and charge conservation, a second set of Maxwell equations, and finally the field–energy momentum tensor.
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31

Deruelle, Nathalie, and Jean-Philippe Uzan. Conservation laws. Oxford University Press, 2018. http://dx.doi.org/10.1093/oso/9780198786399.003.0045.

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This chapter studies how the ‘spacetime symmetries’ can generate first integrals of the equations of motion which simplify their solution and also make it possible to define conserved quantities, or ‘charges’, characterizing the system. As already mentioned in the introduction to matter energy–momentum tensors in Chapter 3, the concepts of energy, momentum, and angular momentum are related to the invariance properties of the solutions of the equations of motion under spacetime translations or rotations. The chapter explores these in greater detail. It first turns to isometries and Killing vectors. The chapter then examines the first integrals of the geodesic equation, and Noether charges.
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32

J, Dobosy Ronald, Birdwell Kevin R, and Air Resources Laboratory (U.S.), eds. Airborne measurements of mass, momentum, and energy fluxes for the Boardman-Arm Regional Flux Experiment--1991 preliminary data release. Silver Spring, Md: U.S. Dept. of Commerce, National Oceanic and Atmospheric Administration, Environmental Research Laboratories, Air Resources Laboratory, 1993.

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33

Mechanics II: Momentum, Energy, Rotational and Harmonic Motion, and Chaos (Units 8-15), Module 2, Workshop Physics(r) Activity Guide. Wiley, 1996.

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34

Maggiore, Michele. Helicity decomposition of metric perturbations. Oxford University Press, 2018. http://dx.doi.org/10.1093/oso/9780198570899.003.0009.

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Decomposition of the perturbations over FRW into scalar, vector and tensor perturbations. Physical and unphysical degrees of freedom. Gauge-invariant metric perturbations, Bardeen variables. Gauge-invariant perturbations of the energy-momentum tensor
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35

Focus on Momentum. Focus Readers, 2017.

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36

Forest, Christopher. Focus on Momentum. Focus Readers, 2017.

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37

Golizadeh-Mojarad, Roksana, and Supriyo Datta. NEGF-based models for dephasing in quantum transport. Edited by A. V. Narlikar and Y. Y. Fu. Oxford University Press, 2017. http://dx.doi.org/10.1093/oxfordhb/9780199533046.013.3.

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This article describes the use of NEGF-based models for elastic dephasing in quantum transport. The non-equilibrium Green's function (NEGF) method provides a rigorous prescription for including any kind of dephasing mechanisms to any order starting from a microscopic Hamiltonian through an appropriate choice of the self-energy function. The article first introduces the general approach to quantum transport that provides a general method for modelling a wide class of nanotransistor and spin devices. It then discusses the effect of different types of dephasing on momentum and spin relaxation before considering three simple phenomenological choices of the self-energy function that allows one to incorporate spin, phase and momentum relaxation independently. It also looks at an example that takes into account these three types of dephasing mechanisms: the ‘spin-Hall’ effect.
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38

Changes Within Physical Systems And/or Conservation Of Energy And Momentum: An Anthology Of Current Thought (Contemporary Discourse in the Field of Physics). Rosen Central, 2005.

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39

Momentum. Hachette, 2011.

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40

Deruelle, Nathalie, and Jean-Philippe Uzan. Conservation laws. Oxford University Press, 2018. http://dx.doi.org/10.1093/oso/9780198786399.003.0007.

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This chapter defines the conserved quantities associated with an isolated dynamical system, that is, the quantities which remain constant during the motion of the system. The law of momentum conservation follows directly from Newton’s third law. The superposition principle for forces allows Newton’s law of motion for a body Pa acted on by other bodies Pa′ in an inertial Cartesian frame S. The law of angular momentum conservation holds if the forces acting on the elements of the system depend only on the separation of the elements. Finally, the conservation of total energy requires in addition that the forces be derivable from a potential.
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41

Deruelle, Nathalie, and Jean-Philippe Uzan. Matter in curved spacetime. Oxford University Press, 2018. http://dx.doi.org/10.1093/oso/9780198786399.003.0043.

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This chapter is concerned with the laws of motion of matter—particles, fluids, or fields—in the presence of an external gravitational field. In accordance with the equivalence principle, this motion will be ‘free’. That is, it is constrained only by the geometry of the spacetime whose curvature represents the gravitation. The concepts of energy, momentum, and angular momentum follow from the invariance of the solutions of the equations of motion under spatio-temporal translations or rotations. The chapter shows how the action is transformed, no longer under a modification of the field configuration, but instead under a displacement or, in the ‘passive’ version, under a translation of the coordinate grid in the opposite direction.
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42

United States. National Aeronautics and Space Administration., ed. Rarefied gas effects on aerobraking/reentry vehicles with wakes. [Huntsville, AL]: Remtech, 1995.

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43

Mann, Peter. The Hamiltonian & Phase Space. Oxford University Press, 2018. http://dx.doi.org/10.1093/oso/9780198822370.003.0014.

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This chapter discusses the Hamiltonian and phase space. Hamilton’s equations can be derived in several ways; this chapter follows two pathways to arrive at the same result, thus giving insight into the motivation for forming these equations. The importance of deriving the same result in several ways is that it shows that, in physics, there are often several mathematical avenues to go down and that approaching a problem with, say, the calculus of variations can be entirely as valid as using a differential equation approach. The chapter extends the arenas of classical mechanics to include the cotangent bundle momentum phase space in addition to the tangent bundle and configuration manifold, and discusses conjugate momentum. It also introduces the Hamiltonian as the Legendre transform of the Lagrangian and compares it to the Jacobi energy function.
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44

Transfer, Workshop on Exclusive Processes at High Momentum, and Thomas Jefferson National Accelerator Facility (U S. ). Exclusive Processes at High Momentum Transfer: May 15-18, 2002 Jefferson Lab, Newport News, Virginia. World Scientific Pub Co Inc, 2003.

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45

Morawetz, Klaus. Classical Kinetic Theory. Oxford University Press, 2018. http://dx.doi.org/10.1093/oso/9780198797241.003.0003.

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The classical non-ideal gas shows that the two original concepts of the pressure based of the motion and the forces have eventually developed into drift and dissipation contributions. Collisions of realistic particles are nonlocal and non-instant. A collision delay characterizes the effective duration of collisions, and three displacements, describe its effective non-locality. Consequently, the scattering integral of kinetic equation is nonlocal and non-instant. The non-instant and nonlocal corrections to the scattering integral directly result in the virial corrections to the equation of state. The interaction of particles via long-range potential tails is approximated by a mean field which acts as an external field. The effect of the mean field on free particles is covered by the momentum drift. The effect of the mean field on the colliding pairs causes the momentum and the energy gains which enter the scattering integral and lead to an internal mechanism of energy conversion. The entropy production is shown and the nonequilibrium hydrodynamic equations are derived. Two concepts of quasiparticle, the spectral and the variational one, are explored with the help of the virial of forces.
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46

Coopersmith, Jennifer. Hamiltonian Mechanics. Oxford University Press, 2017. http://dx.doi.org/10.1093/oso/9780198743040.003.0007.

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Hamilton’s genius was to understand what were the true variables of mechanics (the “p − q,” conjugate coordinates, or canonical variables), and this led to Hamilton’s Mechanics which could obtain qualitative answers to a wider ranger of problems than Lagrangian Mechanics. It is explained how Hamilton’s canonical equations arise, why the Hamiltonian is the “central conception of all modern theory” (quote of Schrödinger’s), what the “p − q” variables are, and what phase space is. It is also explained how the famous conservation theorems arise (for energy, linear momentum, and angular momentum), and the connection with symmetry. The Hamilton-Jacobi Equation is derived using infinitesimal canonical transformations (ICTs), and predicts wavefronts of “common action” spreading out in (configuration) space. An analogy can be made with geometrical optics and Huygen’s Principle for the spreading out of light waves. It is shown how Hamilton’s Mechanics can lead into quantum mechanics.
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47

Jenkins, Jesse D., and Valerie J. Karplus. Carbon Pricing under Political Constraints. Oxford University Press, 2017. http://dx.doi.org/10.1093/oso/9780198802242.003.0003.

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The economic prescription for mitigating climate change is clear: price carbon dioxide (CO2) and other greenhouse gas emissions to internalize climate damages. In practice, a variety of political economy constraints have prevented the introduction of a carbon price equal to the full social cost of emissions. This chapter develops insights about the design of climate policy in the face of binding political constraints. Using a stylized model of the energy sector, the authors identify welfare-maximizing combinations of a CO2 price, subsidy for clean energy production, and lump-sum transfers to energy consumers or producers under a set of constraints: limits on the CO2 price, on increases in energy prices, and on energy consumer and producer surplus loss. The authors find that strategically using subsidies or transfers to relieve political constraints can significantly improve the efficiency of carbon pricing policies, while strengthening momentum for a low-carbon transition over time.
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48

Deruelle, Nathalie, and Jean-Philippe Uzan. The Einstein equations. Oxford University Press, 2018. http://dx.doi.org/10.1093/oso/9780198786399.003.0044.

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This chapter deals with Einstein equations. In the absence of matter there is no gravitational field, and the spacetime which represents this empty universe is Minkowski spacetime. More precisely, if the gravitational field created by the matter can be neglected, the appropriate framework for describing the matter is that of special relativity. Einstein gravitational equations relate geometry and matter: specifically, they relate the Riemann tensor, or more precisely the Einstein tensor, to the geometrical object describing ‘inertia’, the energy content of the matter—that is, the energy–momentum tensor. These equations form a set of ten nonlinear partial differential equations. The coordinate system can be chosen arbitrarily.
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49

Morawetz, Klaus. Nonequilibrium Quantum Hydrodynamics. Oxford University Press, 2018. http://dx.doi.org/10.1093/oso/9780198797241.003.0015.

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The balance equations resulting from the nonlocal kinetic equation are derived. They show besides the Landau-like quasiparticle contributions explicit two-particle correlated parts which can be interpreted as molecular contributions. It looks like as if two particles form a short-living molecule. All observables like density, momentum and energy are found as a conserving system of balance equations where the correlated parts are in agreement with the forms obtained when calculating the reduced density matrix with the extended quasiparticle functional. Therefore the nonlocal kinetic equation for the quasiparticle distribution forms a consistent theory. The entropy is shown to consist also of a quasiparticle part and a correlated part. The explicit entropy gain is proved to complete the H-theorem even for nonlocal collision events. The limit of Landau theory is explored when neglecting the delay time. The rearrangement energy is found to mediate between the spectral quasiparticle energy and the Landau variational quasiparticle energy.
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50

Aguado Molina, Roque, José Luis Casteleiro Roca, Esteban Jove Pérez, Francisco Zayas Gato, Héctor Quintián Pardo, and José Luis Calvo Rolle. Hidrógeno y su almacenamiento: el futuro de la energía eléctrica. Servicio de Publicaciones, 2021. http://dx.doi.org/10.17979/spudc.9788497497985.

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Energy storage plays a key role in the modern global economy, in which variable renewable energies are growingly acquiring a major part. One option for energy storage is the production of hydrogen through electrolysis of water with renewable electricity, which can later be used again to produce electricity in a fuel cell, internal combustion engine or gas turbine, among other applications. Renewable hydrogen is quickly approaching economic competitiveness and enjoying unprecedented political and business momentum, with the number of favorable policies and projects worldwide expected to increase rapidly in the coming years. The rising interest in this storage alternative is driven by the urgency of greenhouse gas emission mitigation, by the falling costs of renewable power and by systems integration challenges due to rising shares of variable renewable power supply. This book aims at reviewing the different available technologies for hydrogen production, storage and final use as an energy vector.
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