Energetics

Information about Energetics

Energetics is the scientific study of energy flows and storages under transformation. Because energy flows at all scales, from the quantum level, to the biosphere and cosmos, energetics is therefore a very broad discipline, encompassing for example thermodynamics, chemistry, biological energetics, biochemistry and ecological energetics. Where each branch of energetics begins and ends is a topic of constant debate. For example, Lehninger (1973, p.21) contended that when the science of thermodynamics deals with energy exchanges of all types, it can be called energetics.

Aims

In general, energetics is concerned with seeking principles that accurately describe the useful and non-useful tendencies of energy flows and storages under transformation. 'Principles' are understood here as phenomena which behave like historical invariants under multiple observations. When some critical number of people have observed such invariance, such a principle is usually then given the status of a 'fundamental law' of science. Like in all science, whether or not a theorem or principle is considered a fundamental law appears to depend on how many people agree to such a proposition. The ultimate aim of energetics therefore is the description of fundamental laws. Philosophers of science have held that the fundamental laws of thermodynamics can be treated as the laws of energetics, (Reiser 1926, p.432). Through the clarification of these laws energetics aims to produce reliable predictions about energy flow and storage transformations at any scale; nano to macro.

History

Energetics has a controversial history. Some authors maintain that the origins of energetics can be found in the work of the ancient Greeks, but that the mathematical formalisation began with the work of Leibniz. Liet.-Col. Richard de Villamil (1928) said that Rankine formulated the Science of Energetics in his paper Outlines of the Science of Energetics published in the Proceedings of the Philosophical Society of Glasgow in 1855. W. Ostwald and E. Mach subsequently developed the study and in the late 1800s energetics was understood to be incompatible with the atomic view of the atom forwarded by Boltzmann's gas theory. Proof of the atom settled the dispute but not without significant damage. In the 1920's Lotka then attempted to build on Boltzmann's views through a mathematical synthesis of energetics with biological evolutionary theory. Lotka proposed that the selective principle of evolution was one which favoured the maximum useful energy flow transformation. This view subsequently influenced the further development of ecological energetics, especially the work of Howard T. Odum.

De Villamil attempted to clarify the scope of energetics with respects to other branches of physics by contriving a system that divides mechanics into two branches; energetics (the science of energy) and "pure", "abstract" or "rigid" dynamics (the science of momentum). According to Villamil energetics can be mathematically characterised by scalar equations, and rigid dynamics by vectorial equations. In this division the dimensions for dynamics are space, time and mass, and for energetics, length, time and mass (Villamil 1928, p.9). This division is made according to fundamental pressuppositions about the properties of bodies which can be expressed according to how one answers to following two questions:

1. Are particles rigidly fixed to together?

2. Is there any machinery for stopping moving bodies?

In Villamil's classification system, dynamics says yes to 1 and no to 2, whereas energetics says no to 1 and yes to 2. Therefore, Villamil's in system, dynamics assumes that particles are rigidly fixed together and cannot vibrate, and consequently must all be at zero temperature. The conservation of momentum is a consequence of this view, however it is considered valid only in logic and not to be a true representation of the facts (Villamil, p. 96). In contrast energetics does not assume that particles are rigidly fixed together, particles are therefore free to vibrate, and consequently can be at non-zero temperatures.

Principles of energetics

As a general statement of energy flows under transformation, the principles of energetics include the first four laws of thermodynamics which seek a rigorous description. However the precise place of the laws of thermodynamics within the principles of energetics is a topic currently under debate. If the ecologist Howard T. Odum was right, then the principles of energetics take into consideration a hierarchical ordering of energy forms, which aims to account for the concept of energy quality, and the evolution of the universe. Albert Lehninger (1973, p. 2) called these hierarchical orderings the

... successive stages in the flow of energy through the biological macrocosm

Odum proposed 3 further energetic principles and one corollary that take energy hierarchy into account. The first four principles of energetics are related to the same numbered laws of thermodynamics, and are expanded upon in that article. The final four principles are taken from the ecological energetics of H.T. Odum.

Zeroth principle of energetics
: If two thermodynamic systems A and B are in thermal equilibrium, and B and C are also in thermal equilibrium, then A and C are in thermal equilibrium.
First principle of energetics
: The increase in the internal energy of a system is equal to the amount of energy added to the system by heating, minus the amount lost in the form of work done by the system on its surroundings.
Second principle of energetics
: The total entropy of any isolated thermodynamic system tends to increase over time, approaching a maximum value.
Third principle of energetics
: As a system approaches absolute zero of temperature all processes cease and the entropy of the system approaches a minimum value or zero for the case of a perfect crystalline substance.
Fourth principle of energetics
: There seem to be two opinions on the fourth principle of energetics:
:* The Onsager reciprocal relations are sometimes called the fourth law of thermodynamics. As the fourth law of thermodynamics Onsager reciprocal relations would constitute the fourth principle of energetics.
:* In the field of ecological energetics H.T. Odum considered maximum power, the fourth principle of energetics. Odum also proposed the Maximum empower principle as a corollary of the maximum power principle, and considered it to describe the propensities of evolutionary self-organization.
Fifth principle of energetics
: The energy quality factor increases hierarchically. From studies of ecological food chains, Odum proposed that energy transformations form a hierarchical series measured by Transformity increase (Odum 2000, p. 246). Flows of energy develop hierarchical webs in which inflowing energies interact and are transformed by work processes into energy forms of higher quality that feedback amplifier actions, helping to maximise the power of the system" — (Odum 1994, p. 251)
Sixth principle of energetics
: Material cycles have hierarchical patterns measured by the emergy/mass ratio that determines its zone and pulse frequency in the energy hierarchy. (Odum 2000, p. 246). M.T. Brown and V. Buranakarn write, "Generally, emergy per mass is a good indicator of recycle-ability, where materials with high emergy per mass are more recyclable" (2003, p. 1).

References

S.W.Angrist and L.G.Helper (1973) Order and Chaos: Laws of Energy and Entropy, Penguin, Australia, p. 34
G. Helm (1898) Die Energetic, Leipzig, Verlag.
H.Hertz (1956) Principles of Mechanics, Dover, U.S.A.
A.Lehninger (1973) Bioenergetics W.A.Benjamin, Inc..
H.T. Odum and R.T.Pinkerton (1955) 'Time's Speed Regulator', American Scientist, Vol. 43, No. 2, p. 331.
H.T. Odum (1994) Ecological and General Systems: An Introduction to Systems Ecology, Colorado University Press.
H.T. Odum (2000) 'An Energy Hierarchy Law For Biogeochemical Cycles', in Brown, M.T. (Ed.), Emergy Synthesis: Theory and Applications of the Emergy Methodology. Proceedings of the First Biennial Emergy Analysis Research Conference, Centre for Environmental Policy, University of Florida, Gainesville, FL.
J. R. Partington (1989) A Short History of Chemistry, Dover, New York
Oliver L. Reiser, 1926, Probability, Natural Law, and Emergence: I. Probability and Purpose, The Journal of Philosophy, Vol. 23, No. 16, pp. 421-435
M.Tribus (1961) Thermostatics and Thermodynamics, Van Nostrand, University Series in Basic Engineering, pp. 619-622.
De Villamil, R. (1928) Rational mechanics.

External links

Energetics - Encyclopedia Britannica, 1911 ed.
A history of energetics
Journal of Energetic Materials

Thermodynamics (from the Greek θερμη, therme, meaning "heat" and δυναμις, dynamis, meaning "power") is a branch of physics that studies the effects of changes in temperature, pressure, and volume on
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biological thermodynamics (Greek: bios = life and logikos = reason + Greek: thermos = heat and dynamics = power) or bioenergetics^[1] is the study of energy transformation in the biological sciences.
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Biochemistry is the study of the chemical processes in living organisms.^[1] The word "biochemistry" comes from the Greek word βιοχημεία biochēmeia, which means "the chemistry of life.
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Ecological energetics is the quantitative study of the flow of energy through ecological systems. It aims to uncover the principles which describe the propensity of such energy flows through the trophic, or 'energy availing' levels of ecological networks.
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For a list of set rules, see .

A physical law, scientific law, or a law of nature is a scientific generalization based on empirical observations of physical behavior.
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laws of thermodynamics, in principle, describe the specifics for the transport of heat and work in thermodynamic processes. Since their conception, however, these laws have become some of the most important in all of physics and other branches of science connected to thermodynamics.
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Gottfried Wilhelm Leibniz

Gottfried Wilhelm Leibniz
Born July 1 (June 21 Old Style) 1646
Leipzig, Electorate of Saxony
Died November 14 1716
Hannover, Hanover
Nationality German
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Richard de Villamil (1850-1936) was a british officer and scientist physician).

Grandson of Martin de Villamil (1783-1843), he was at first officer of the British army (India, Jamaica) (1869-1889 at least).
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Ludwig Boltzmann

Ludwig Eduard Boltzmann (1844-1906)
Born January 20 1844
Vienna, Austrian Empire
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Alfred James Lotka (March 2, 1880 - December 5, 1949) was a US mathematician, physical chemist, and statistician famous for his work in population dynamics and energetics.

Life

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Howard Thomas Odum
Birth: 1 September 1924
Chapel Hill, North Carolina, USA
Death: 11 September 2002
Gainesville, Florida, United States
School/tradition: Zoology
Main interests: Mathematics, Ecology and Natural philosophy
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For other uses, see Mechanic (disambiguation).

Mechanics (Greek Μηχανική
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energy (from the Greek ενεργός, energos, "active, working")^[1] is a scalar physical quantity that is a property of objects and systems of objects which is conserved by nature.
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In physics, dynamics is the branch of classical mechanics that is concerned with the effects of forces on the motion of objects. The former distinguishes it from kinematics and the latter distinguishes it from statics.
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momentum (pl. momenta; SI unit kg m/s, or, equivalently, N•s) is the product of the mass and velocity of an object. For more accurate measures of momentum, see the section "modern definitions of momentum" on this page.
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Energy quality the contrast between different forms of energy, the different trophic levels in ecological systems and the propensity of energy to convert from one form to another.
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Albert Lester Lehninger
Born January 17 1917
Bridgeport, Connecticut
Died March 4 1986 (aged 69)
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Ice melting - a classic example of entropy increasing^[1] described in 1862 by Rudolf Clausius as an increase in the disgregation of the molecules of the body of ice.
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In thermodynamics, the Onsager reciprocal relations express the equality of certain relations between flows and forces in thermodynamic systems out of equilibrium, but where a notion of local equilibrium exists.
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Maximum power can refer to different concepts:

In electronics, the maximum power theorem
In systems theory, the maximum power principle

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The concept of transformity was first introduced by David M. Scienceman in collaboration with the late Howard T. Odum. In 1987 Scienceman proposed that the phrases, "energy quality", "energy quality factor", and "energy transformation ratio", all used by H.T.
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The term Emergy was originally coined by David M. Scienceman in collaboration with the late Howard T. Odum. H.T.Odum used 'emergy' to mean both sequestered energy and emergent property of energy use.
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Mass is a fundamental concept in physics, roughly corresponding to the intuitive idea of "how much matter there is in an object". Mass is a central concept of classical mechanics and related subjects, and there are several definitions of mass within the framework of relativistic
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