Classical mechanics In
classical mechanics, energy is a conceptually and mathematically useful property, as it is a
conserved quantity. Several formulations of mechanics have been developed using energy as a core concept.
Work, a function of energy, is force times distance. : W = \int_C \mathbf{F} \cdot \mathrm{d} \mathbf{s} This says that the work (W) is equal to the
line integral of the
force F along a path
C; for details see the
mechanical work article. Work and thus energy is
frame dependent. For example, consider a ball being hit by a bat. In the
center-of-mass reference frame, the bat does no work on the ball. But, in the reference frame of the person swinging the bat, considerable work is done on the ball. The total energy of a system is sometimes called the
Hamiltonian, after
William Rowan Hamilton. The classical equations of motion can be written in terms of the Hamiltonian, even for highly complex or abstract systems. These classical equations have direct analogs in nonrelativistic quantum mechanics. Another energy-related concept is called the
Lagrangian, after
Joseph-Louis Lagrange. This formalism is as fundamental as the Hamiltonian, and both can be used to derive the equations of motion or be derived from them. It was invented in the context of
classical mechanics, but is generally useful in modern physics. The Lagrangian is defined as the kinetic energy
minus the potential energy. Usually, the Lagrange formalism is mathematically more convenient than the Hamiltonian for non-conservative systems (such as systems with friction).
Noether's theorem (1918) states that any differentiable symmetry of the action of a physical system has a corresponding conservation law. Noether's theorem has become a fundamental tool of modern theoretical physics and the calculus of variations. A generalisation of the seminal formulations on constants of motion in Lagrangian and Hamiltonian mechanics (1788 and 1833, respectively), it does not apply to systems that cannot be modeled with a Lagrangian; for example, dissipative systems with continuous symmetries need not have a corresponding conservation law.
Chemistry In the context of
chemistry,
energy is an attribute of a substance as a consequence of its atomic, molecular, or aggregate structure. Since a chemical transformation is accompanied by a change in one or more of these kinds of structure, it is usually accompanied by a decrease, and sometimes an increase, of the total energy of the substances involved. Some energy may be transferred between the surroundings and the reactants in the form of heat or light; thus the products of a reaction have sometimes more but usually less energy than the reactants. A reaction is said to be
exothermic or
exergonic if the final state is lower on the energy scale than the initial state; in the less common case of
endothermic reactions the situation is the reverse.
Chemical reactions are usually not possible unless the reactants surmount an energy barrier known as the
activation energy. The
speed of a chemical reaction (at a given temperature
T) is related to the activation energy
E by the Boltzmann population factor e−
E/
kT; that is, the probability of a molecule to have energy greater than or equal to
E at a given temperature
T. This exponential dependence of a reaction rate on temperature is known as the
Arrhenius equation. The activation energy necessary for a chemical reaction can be provided in the form of thermal energy.
Biology In
biology, energy is an attribute of all biological systems, from the biosphere to the smallest living organism. It enables the growth, development, and functioning of a biological
cell or
organelle in an organism. All living creatures rely on an external source of energy to be able to grow and reproduce – radiant energy from the Sun in the case of green plants and chemical energy (in some form) in the case of animals. Energy provided through
cellular respiration is stored in nutrients such as
carbohydrates (including sugars),
lipids, and
proteins by
cells. Sunlight's radiant energy is captured by plants as
chemical potential energy in
photosynthesis, when carbon dioxide and water (two low-energy compounds) are converted into carbohydrates, lipids, proteins, and oxygen. Release of the energy stored during photosynthesis as heat or light may be triggered suddenly by a spark in a forest fire, or it may be made available more slowly for animal or human metabolism when organic molecules are ingested and
catabolism is triggered by
enzyme action.
Humans The
basal metabolism rate measures the
food energy expenditure per unit time by
endothermic animals at rest. In other words it is the energy required by body organs to perform normally. For humans,
metabolic equivalent of task (MET) compares the energy expenditure per unit mass while performing a physical activity, relative to a baseline. By convention, this baseline is 3.5 mL of oxygen consumed per kg per minute, which is the energy consumed by a typical individual when sitting quietly. For example, if our bodies run (on average) at 80 watts, then a light bulb running at 100 watts is running at 1.25 human equivalents (100 ÷ 80) i.e. 1.25 H-e. For a difficult task of only a few seconds' duration, a person can put out thousands of watts, many times the 746 watts in one official horsepower. For tasks lasting a few minutes, a fit human can generate perhaps 1,000 watts. For an activity that must be sustained for an hour, output drops to around 300; for an activity kept up all day, 150 watts is about the maximum. The human equivalent assists understanding of energy flows in physical and biological systems by expressing energy units in human terms: it provides a "feel" for the use of a given amount of energy. The daily recommended for a human adult are taken as food molecules, mostly carbohydrates and fats. Only a tiny fraction of the original chemical energy is used for
work: : gain in kinetic energy of a sprinter during a 100 m race: 4 kJ : gain in gravitational potential energy of a 150 kg weight lifted through 2 metres: 3 kJ : daily food intake of a normal adult: 6–8 MJ It would appear that living organisms are remarkably
inefficient (in the physical sense) in their use of the energy they receive (chemical or radiant energy); most
machines manage higher efficiencies. In growing organisms the energy that is converted to heat serves a vital purpose, as it allows the organism's tissue to be highly ordered with regard to the molecules it is built from. The
second law of thermodynamics states that energy (and matter) tends to become more evenly spread out across the universe: to concentrate energy (or matter) in one specific place, it is necessary to spread out a greater amount of energy (as heat) across the remainder of the universe ("the surroundings"). Simpler organisms can achieve higher energy efficiencies than more complex ones, but the complex organisms can occupy
ecological niches that are not available to their simpler brethren. The conversion of a portion of the chemical energy to heat at each step in a metabolic pathway is the physical reason behind the pyramid of biomass observed in
ecology. As an example, to take just the first step in the
food chain: of the estimated 124.7 Pg/a of carbon that is
fixed by
photosynthesis, 64.3 Pg/a (52%) are used for the metabolism of green plants, i.e. reconverted into carbon dioxide and heat.
Cell metabolism Multicellular organisms such as humans have cell forms that are classified as
Eukaryote. These cells include an
organelle called the
mitochondria that generates
chemical energy for the rest of the hosting cell. Ninety percent of the oxygen intake by humans is utilized by the
mitochondria, especially for nutrient processing. The molecule
adenosine triphosphate (ATP) is the primary energy transporter in living cells, providing an energy source for cellular processes. It is continually being broken down and synthesized as a component of cellular respiration. Two examples of nutrients consumed by animals are
glucose (C6H12O6) and
stearin (C57H110O6). These food molecules are oxidized to
carbon dioxide and
water in the mitochondria: C6H12O6 + 6O2 -> 6CO2 + 6H2O C57H110O6 + (81 1/2) O2 -> 57CO2 + 55H2O and some of the energy is used to convert
ADP into
ATP: while
meteorological phenomena like wind, rain,
hail, snow, lightning,
tornadoes, and
hurricanes are all a result of energy transformations in our
atmosphere brought about by
solar energy. Sunlight is the main input to
Earth's energy budget which accounts for its temperature and climate stability, after accounting for interaction with the atmosphere. Sunlight may be stored as gravitational potential energy after it strikes the Earth, as (for example when) water evaporates from oceans and is deposited upon mountains (where, after being released at a hydroelectric dam, it can be used to drive turbines or generators to produce electricity). An example of a solar-mediated weather event is a hurricane, which occurs when large unstable areas of warm ocean, heated over months, suddenly give up some of their thermal energy to power a few days of violent air movement. In a slower process,
radioactive decay of atoms in the core of the Earth releases heat, which supplies more than half of the planet's
internal heat budget. In the present day, this
radiogenic heat production was primarily driven by the decay of
Uranium-235,
Potassium-40, and
Thorium-232 some time in the past. This thermal energy drives
plate tectonics and may lift mountains, via
orogenesis. This slow lifting represents a kind of gravitational potential
energy storage of the thermal energy, which may later be transformed into active kinetic energy during landslides, after a triggering event. Earthquakes also release stored elastic potential energy in rocks, a store that has been produced ultimately from the same radioactive heat sources. Thus, according to present understanding, familiar events such as landslides and earthquakes release energy that has been stored as potential energy in the Earth's gravitational field or elastic strain (mechanical potential energy) in rocks. Prior to this, they represent release of energy that has been stored in heavy atoms since the collapse of long-destroyed supernova stars (which created these atoms). Early in a planet's history, the
accretion process provides impact energy that can partially or completely melt the body. This allows a planet to become
differentiated by chemical element. Chemical phase changes of minerals during formation provide additional internal heating. Over time the internal heat is brought to the surface then radiated away into space, cooling the body. Accreted
radiogenic heat sources settle toward the core, providing thermal energy to the planet on a
geologic time scale. Ongoing
sedimentation provides a persistent internal energy source for
gas giant planets like
Jupiter and
Saturn.
Cosmology In
cosmology and astronomy the phenomena of
stars,
nova,
supernova,
quasars, and
gamma-ray bursts are the universe's highest-output energy transformations of matter. All
stellar phenomena (including solar activity) are driven by various kinds of energy transformations. Energy in such transformations is either from gravitational collapse of matter (usually molecular hydrogen) into various classes of astronomical objects (stars,
black holes, etc.), or from nuclear fusion (of lighter elements, primarily hydrogen). The
nuclear fusion of hydrogen in the Sun also releases another store of potential energy which was created at the time of the
Big Bang. At that time, according to theory, space expanded and the universe cooled too rapidly for hydrogen to completely fuse into heavier elements. This meant that hydrogen represents a store of potential energy that can be released by fusion. Such a fusion process is triggered by heat and pressure generated from gravitational collapse of hydrogen clouds when they produce stars, and some of the fusion energy is then transformed into sunlight. The accretion of matter onto a
compact object is a very efficient means of generating energy from
gravitational potential. This behavior is responsible for some of the universe's brightest persistent energy sources. The
Penrose process is a theoretical method by which energy could be extracted from a rotating black hole.
Hawking radiation is the emission of
black-body radiation from a black hole, which results in a steady loss of mass and rotational energy. As the object evaporates, the temperature of this radiation is predicted to increase, speeding up the process.
Quantum mechanics In
quantum mechanics, energy is defined in terms of the
energy operator (Hamiltonian) as a time derivative of the
wave function. The
Schrödinger equation equates the energy operator to the full energy of a particle or a system. Its results can be considered as a definition of measurement of energy in quantum mechanics. The Schrödinger equation describes the space- and time-dependence of a slowly changing (non-relativistic)
wave function of quantum systems. The solution of this equation for a bound system is discrete (a set of permitted states, each characterized by an
energy level) which results in the concept of
quanta. For electromagnetic waves in a vacuum, the energy states are related to the frequency by the
Planck relation: E = h\nu, where h is the
Planck constant and \nu the frequency. These energy states are called quanta of light or
photons.
Relativity When calculating kinetic energy (
work to accelerate a
massive body from zero
speed to some finite speed) relativistically – using
Lorentz transformations instead of
Newtonian mechanics – Einstein discovered an unexpected by-product of these calculations to be an energy term which does not vanish at zero speed. He called it
rest energy: energy which every massive body must possess even when being at rest. The amount of energy is directly proportional to the mass of the body: E_0 = m_0 c^2 , where •
m0 is the
rest mass of the body, •
c is the
speed of light in vacuum, • E_0 is the rest energy. For example, consider
electron–
positron annihilation, in which the rest energy of these two individual particles (equivalent to their rest mass) is converted to the radiant energy of the photons produced in the process. In this system the
matter and
antimatter (electrons and positrons) are destroyed and changed to non-matter (the photons). However, the total mass and total energy do not change during this interaction. The photons each have no rest mass but nonetheless have radiant energy which exhibits the same inertia as did the two original particles. This is a reversible process – the inverse process is called
pair creation – in which the rest mass of the particles is created from a sufficiently energetic photon near a nucleus. In general relativity, the
stress–energy tensor serves as the source term for the gravitational field, in rough analogy to the way mass serves as the source term in the non-relativistic Newtonian approximation. and is also responsible for the potential ability of the system to perform work or heating ("energy manifestations"), subject to the limitations of other physical laws. In
classical physics, energy is a scalar quantity, the
canonical conjugate to time. In
special relativity energy is also a scalar (although not a
Lorentz scalar but a time component of the
energy–momentum 4-vector). In other words, energy is invariant with respect to rotations of
space, but not invariant with respect to rotations of
spacetime (=
boosts). == Transformation ==