Benutzer:Rdb/Übersetzung2

de[Bearbeiten | Quelltext bearbeiten]

Die potentielle Energie (oder potenzielle Energie) ist eine der Formen von Energie in der Physik. Es handelt sich dabei um diejenige Energie, welche ein Körper durch seine Position oder Lage in einem konservativen Kraftfeld (etwa einem Gravitationsfeld oder elektrischen Feld) innehat. Man spricht daher auch von Lageenergie. Ein bestimmter Ort in diesem Feld dient dabei als Bezugspunkt; beim Gravitationsfeld der Erde kann dies beispielsweise die Erdoberfläche sein. Die Begriffe Potential und potentielle Energie sind in eng verwandt und unterscheiden sich nur durch eine Konstante (in der Mechanik die Masse, in der Elektrostatik die elektrische Ladung). Als Formelzeichen für die potentielle Energie wird üblicherweise V oder E_pot verwendet.

Definition[Bearbeiten | Quelltext bearbeiten]

Da ein konservatives Kraftfeld ${\displaystyle \mathbf {F} (\mathbf {r} )}$ mathematisch ein Gradientenfeld ist, existiert ein skalares Feld ${\displaystyle V(\mathbf {r} )}$, für das die Beziehung

${\displaystyle \mathbf {F} (\mathbf {r} )=-\nabla V(\mathbf {r} )}$

gilt. Hierbei ist ${\displaystyle \nabla }$ der Nabla-Operator und ${\displaystyle \mathbf {r} }$ der Ortsvektor.

Für einzelne Komponenten des Feldes bedeutet dies

${\displaystyle F_{i}(\mathbf {r} )=-{\frac {\partial V(\mathbf {r} )}{\partial i}}\quad ,\quad i=x,y,z}$.

Dies kann umgeformt werden zu

${\displaystyle -F_{i}(\mathbf {r} )\,\mathrm {d} i=\mathrm {d} V(\mathbf {r} )}$

woraus für die potentielle Energie folgt

${\displaystyle -\int _{r_{1}}^{r^{2}}\mathbf {F} (\mathbf {r} )\mathrm {d} \mathbf {r} =V(\mathbf {r} )}$.

In der Elektrostatik ist das Potential des elektrischen Feldes ${\displaystyle \mathbf {E} (\mathbf {r} )}$

${\displaystyle -\int _{\infty }^{r}\mathbf {E} (\mathbf {r} ')\mathrm {d} \mathbf {r} '=V(\mathbf {r} )}$

Der Zusammenhang zwischen Potential ${\displaystyle \Phi (\mathbf {r} )}$ und potentieller Energie ist

• für eine Ladung q: ${\displaystyle \Phi (\mathbf {r} )={\frac {1}{q}}V(\mathbf {r} )}$

• für eine Masse m: ${\displaystyle \Phi (\mathbf {r} )={\frac {1}{m}}V(\mathbf {r} )}$

Die potentielle Energie entspricht in ihrer Größe der am Körper zu verrichtenden Arbeit, um vom Bezugsniveau die neue Lage zu erreichen. Bei reversiblen Vorgängen (keine Reibung) ist die potentielle gleich der kinetischen Energie, die der Körper gewänne, wenn er der Kraft bis auf das Bezugsniveau folgen, das heißt, sich frei bewegen könnte.

Um die potentielle Energie eines Körpers zu vergrößern, muss Arbeit gegen die Kräfte eines konservativen Kraftfeldes verrichtet werden. So besitzt jeder massebehaftete Körper in einem Gravitationsfeld potentielle Energie. Diese kann jedoch nur erhöht oder vermindert werden, wenn der Körper gegen oder in Richtung der Gravitationskraft verschoben wird.

Befindet sich der Körper auf Bezugsniveau, so ist die potentielle Energie gleich null.

Beispiele[Bearbeiten | Quelltext bearbeiten]

Ein Turmspringer vor dem Abspringen besitzt eine potentielle Energie (im Gravitationsfeld) gegenüber der Wasseroberfläche. Das Bezugsniveau kann aber auch auf den Grund des Beckens gelegt werden, dann hat der Springer entsprechend mehr potentielle Energie. Analog muss er mehr Arbeit aufwenden, um vom Grund auf das Sprungbrett zu kommen, als wenn er lediglich die Treppe am Turm hinaufläuft. Läuft er über das Sprungbrett an, verändert sich seine potentielle Energie nicht, da er keine Arbeit gegen die senkrecht nach unten wirkende Schwerkraft verrichtet.

Auch das in einem Stausee aufgestaute Wasser, ehe es durch Fallrohre hinabstürzt, oder eine Metallkugel welche zwischen zwei elektrisch geladenen Kondensatorplatten im Schwebezustand gehalten wird verfügt über potentielle Energie wenn das Bezugsniveau entsprechend darunter gewählt wird.

Potentielle Energie und der Energieerhaltungssatz[Bearbeiten | Quelltext bearbeiten]

In einem abgeschlossenen System ohne Energieaustausch mit der Umgebung und unter Vernachlässigung jedweder Reibung, gilt zu jedem Zeitpunkt der Energieerhaltungssatz der klassischen Mechanik:

${\displaystyle E=T+V=const.}$

• V - potentielle Energie
• T - kinetische Energie
• E - mechanische Energie

In Worten: Die Summe aus potentieller und kinetischer Energie, einschließlich der Rotationsenergie, ist konstant und entspricht der Gesamtenergie des mechanischen Systems.

In einer höheren Formulierung der Mechanik, dem Hamilton-Formalismus, schreibt man auch

${\displaystyle H=\sum _{k}p_{k}{\dot {q}}_{k}-L=T+V}$

wobei H die Hamiltonfunktion und L die Lagrangefunktion sind.

Potentielle Energie in einem Gravitationsfeld[Bearbeiten | Quelltext bearbeiten]

Für die Funktion ${\displaystyle V(r)}$ der potentiellen Energie eines Massepunktes ${\displaystyle m}$ und der Masse ${\displaystyle M}$ eines sphärischen Himmelskörpers gilt allgemein

${\displaystyle \mathrm {d} V(r)=-F\cdot \mathrm {d} r=-\left(-{\frac {GMm}{r^{2}}}\right)\cdot \mathrm {d} r={\frac {GMm}{r^{2}}}\cdot \mathrm {d} r\,,}$

Wobei ${\displaystyle F}$ die von dem Himmelskörper auf den Massenpunkt ausgeübte Gravitationskraft und ${\displaystyle dr}$ eine infinitesimale Verschiebung der Höhe des Systems bezeichnen.

Wenn der Massenpunkt von einer Höhe ${\displaystyle r_{1}}$ zu einer Höhe ${\displaystyle r_{2}}$ gebracht wird, so ändert sich seine potentielle Energie um

${\displaystyle V(r_{2})-V(r_{1})=\int _{r_{1}}^{r_{2}}dV=\int _{r_{1}}^{r_{2}}{\frac {GMm}{r^{2}}}\,\mathrm {d} r={\frac {GMm}{r_{1}}}-{\frac {GMm}{r_{2}}}}$

Die potentielle Energie des Massenpunktes möge auf der Planetenoberfläche ${\displaystyle R_{p}}$, also ${\displaystyle r_{1}=R_{p}}$, gleich null sein, womit

${\displaystyle V(r_{2})-V(R_{p})=V(r_{2})-0={\frac {GMm}{R_{p}}}-{\frac {GMm}{r_{2}}}}$

ist.

Damit ergibt sich für eine beliebige Höhe ${\displaystyle r}$ mit ${\displaystyle r>R_{p}}$

${\displaystyle V(r)={\frac {GMm}{R_{p}}}-{\frac {GMm}{r}}}$

Schreiben wir die potentielle Energie als Funktion einer Höhe ${\displaystyle h=r-R_{p}}$ über der Planetenoberfläche, so ist sie vergleichbar mit ${\displaystyle mgh}$.

Dann ist

${\displaystyle V(r)={\frac {GMm}{R_{p}}}-{\frac {GMm}{r}}={\frac {GMm}{R_{p}r}}\left(r-R_{p}\right)={\frac {GMm}{R_{p}r}}h}$

Mit der Schwerebeschleunigung ${\displaystyle g=GM/R_{p}^{2}\rightarrow GM=gR_{p}^{2}}$ vereinfacht sich die Formel zu

${\displaystyle V(r)={\frac {GMm}{R_{p}r}}h=m\left({\frac {GM}{R_{p}^{2}}}\right)h{\frac {R_{p}}{r}}=m\left({\frac {gR_{p}^{2}}{R_{p}^{2}}}\right)h{\frac {R_{p}}{r}}=mgh{\frac {R_{p}}{r}}}$

Die potentielle Energie ist also ein ${\displaystyle mgh}$-faches von ${\displaystyle R_{p}/r}$. In unmittelbarer Nähe der Erdoberfläche sind ${\displaystyle R_{p}}$ und ${\displaystyle r}$ näherungsweise gleich, womit die potentielle Energie in einem solchen Fall mit ${\displaystyle mgh}$ approximiert wird. Es ist zu beachten, dass die potentielle Energie mit steigendem ${\displaystyle r}$ nicht unendlich anwächst, sondern vielmehr aus

${\displaystyle V(r)={\frac {GMm}{R_{p}}}-{\frac {GMm}{r}}}$

ersichtlich ist, dass der zweite Term dieser Gleichung mit steigendem ${\displaystyle r}$ gegen null strebt, weshalb sich die potentielle Energie einem maximalen Grenzwert der Größe

${\displaystyle V_{\mathrm {max} }={\frac {GMm}{R_{p}}}=mgR_{p}}$, mit ${\displaystyle GM=gR_{P}^{2}}$

annähert.

Maximale potentielle Energie[Bearbeiten | Quelltext bearbeiten]

Um einen Massenpunkt ${\displaystyle m}$ um eine Strecke ${\displaystyle \mathrm {d} r}$ anzuheben, muss die Arbeit ${\displaystyle \mathrm {d} W=F\cdot \mathrm {d} r}$ geleistet werden, wobei ${\displaystyle F}$ der Gravitationskraft des Planeten entspricht. Um den Massenpunkt von einer Planetenoberfläche ${\displaystyle R}$ aus dem Gravitationsfeld heraus, also in die Unendlichkeit, zu befördern, muss die maximale potentielle Energie des Gravitationsfeldes des Planeten gerade erreicht oder übertroffen werden. Für diese gilt also

${\displaystyle W=V_{\mathrm {max} }=\int _{R}^{\infty }\mathrm {d} W=\int _{R}^{\infty }{\frac {GMm}{R^{2}}}\,\mathrm {d} R=GMm\int _{R}^{\infty }{\frac {1}{R^{2}}}\,\mathrm {d} R=GMm\left[-{\frac {1}{R}}\right]_{R}^{\infty }={\frac {GMm}{R}}=mgR}$

Potentielle Energie einer gespannten Feder[Bearbeiten | Quelltext bearbeiten]

Aus der Federkraft

${\displaystyle F(x)=-kx}$,

ergibt sich für die potentielle Energie

${\displaystyle V(x)=-\int _{0}^{x}F(x)\mathrm {d} x={1 \over 2}kx^{2}}$.

Hierbei ist k die Federkonstante und x die Auslenkung der Feder aus der Ruhelage.

Siehe auch[Bearbeiten | Quelltext bearbeiten]

• kinetische Energie
• Rotationsenergie
• Potential

en[Bearbeiten | Quelltext bearbeiten]

Potential energy is defined as the work done by a certain force (such as gravitational force or Coulomb force) when the relative positions of objects are changed within a physical system. The phrase 'potential energy' was coined by William Rankine.^[1] In other words, it is the work done when an object is moved from one point to another. Conceptually, potential energy can be thought of as the energy stored in an object as a result of the work done to bring it to that position from a reference point. When an object moves from one point to another, and there is a potential difference as a result of this, then work is performed. Potential energy is so named because this stored energy or work has the potential to change the state of other objects when released.

Various forms of energy can be grouped as potential energy. Each of these forms is associated with a particular kind of force, and the work done by each of these types of forces can be considered potential energy. For example, the work of elastic force is called elastic potential energy; work of gravitational force is called gravitational potential energy, work of the Coulomb force is called electric potential energy; work of strong nuclear force or weak nuclear force acting on the baryon charge is called nuclear potential energy. Chemical potential energy is the work of Coulomb force on during rearrangement of mutual positions of electrons and nuclei in atoms and molecules. Thermal energy usually has two components: the kinetic energy of random motion of particles and potential energy of their mutual positions.

Gravitational potential energy[Bearbeiten | Quelltext bearbeiten]

Gravitational potential energy is the work of gravitational force (usually taken with negative sign due to path convention).

For example, consider a book placed on top of a table. When the book is raised from the floor to the table, the gravitational force does negative work. If the book is returned back to the floor, exactly the same (but positive) work will be done by the gravitational force. So, if the book is knocked off the table, this work (called potential energy) goes to accelerate the book (and now is called kinetic energy). When the book hits the floor this kinetic energy is converted into heat and sound by the impact.

The factors that affect an object's gravitational potential energy are the height to which it is raised, its mass, and the strength of the gravitational field in which it is raised. Thus, a book lying on a table has less gravitational potential energy than the same book on top of a taller cupboard, and less gravitational potential energy than a heavier book lying on the same table. An object at a certain height above the Moon's surface has less gravitational potential energy than at the same height on Earth because the Moon's gravity is weaker. (The gravitational force between any two objects is directly proportional to the product of their masses and inversely proportional to the square of the distance between them, according to Newton's law of gravitation.)

Calculation of gravitational potential energy[Bearbeiten | Quelltext bearbeiten]

The work of gravitational force in raising an object (taken with the negative sign) is equal to the negative of the force applied multiplied by the distance through which the object is raised:

${\displaystyle U_{g}=-(-mg)h=mgh\,}$

where

m is the mass of the object

g is the standard gravity (approximately 9.8 m/s² at the earth's surface)

h is the height to which the object is raised, relative to a given reference level (such as the earth's surface).

When applying this equation it is essential to use consistent units. Most scientific work is now done in SI units, in which case mass is measured in kilograms (kg), acceleration in meters per second squared (m/s²), and distance (here height) in meters (m). The resulting energy is expressed in joules (kg m²/s²).

The equation shows that gravitational potential energy is proportional to both mass and height. For example, raising two similar objects, or raising the same object twice as far, doubles the potential energy.

The "mgh" formula works well provided that the acceleration due to gravity, g, is very nearly constant over the distance h. On or close to the surface of the earth this assumption is reasonable, but over the much larger distances applying, for example, to spacecraft and astronomical bodies, it is not.

To calculate gravitational potential energy with varying g it is necessary to sum all the individual increments of potential energy as the masses are separated, taking account of the varying value of g as we go. In the limit, as the increments become "infinitely small", the sum becomes an integral.

To simplify the evaluation of the integral we can make the assumption that the gravitational forces act as if the objects' masses were concentrated at their respective centers of mass. This assumption is mathematically exactly correct for a spherically symmetrical object (such as, to a reasonable approximation, a planet). It is not generally correct in other cases, though if the dimensions of an object are very small compared to the distance of separation then it is reasonable to consider it as a point mass and ignore the details of its shape.

With this simplifying assumption, integrating force over distance leads to the following general expression for the gravitational potential energy, U_g, of a system of two masses:

	${\displaystyle U_{g}\,}$	${\displaystyle =\int _{h_{1}}^{h_{2}}{Gm_{1}m_{2} \over r^{2}}dr}$
		${\displaystyle =Gm_{1}m_{2}\left({\frac {1}{h_{1}}}-{\frac {1}{h_{2}}}\right)}$

where

${\displaystyle m_{1}}$ and ${\displaystyle m_{2}}$ are the masses of the two objects

${\displaystyle G}$ is the gravitational constant, ${\displaystyle \left(6.6742\pm 0.0010\right)\times 10^{-11}\ {\mbox{m}}^{3}\ {\mbox{s}}^{-2}\ {\mbox{kg}}^{-1}\,}$, (not to be confused with the g used earlier)

${\displaystyle h_{1}}$ is the reference level (the separation at which potential energy is considered to be zero)

${\displaystyle h_{2}}$ is the actual distance between the objects.

Subject to the caveats mentioned above, the distances ${\displaystyle h_{1}}$ and ${\displaystyle h_{2}}$ are measured between the objects' centres of mass.

For example, in the case of a small object above the surface of the earth, with reference level at the surface, ${\displaystyle m_{1}}$ and ${\displaystyle m_{2}}$ are respectively the masses of the earth and the object, ${\displaystyle h_{1}}$ is the distance from the earth's centre to the earth's surface, and ${\displaystyle h_{2}}$ is the distance from the earth's centre to the object.

If we try to calculate an "absolute" potential energy by setting the reference level at zero then the formula "blows up" with division by zero. In other words, we can only actually use this formula to measure the difference in potential energy between one non-zero separation and another.

In practice it is often convenient to take the reference level at infinite separation (i.e. ${\displaystyle h_{1}=\infty }$), in which case the formula becomes:

${\displaystyle U_{g}={\frac {-Gm_{1}m_{2}}{r}}}$

where r is now the distance between the centres of mass of the two objects (again noting the earlier caveats). For a small object above the surface of the earth, r is the distance from the object to the earth's centre (and similarly for other spherical bodies).

Using this convention, potential energy is zero when r is infinitely large, and negative at any finite r. However, the difference in potential energy at different values of r – the quantity we are actually interested in – takes the expected sign.

U_g as calculated above measures the potential energy of the whole system. This can be visualised as if two bodies in space were released from rest and allowed to come together under the force of gravity. The sum of the kinetic energy gained by the two objects is exactly equal to the decrease in the potential energy of the system. The ratio of the objects' individual kinetic energy gains is equal to the reciprocal of the ratio of their masses. So, in the case of a relatively light object falling towards a very massive object (such as the earth), the contribution from the massive object is insignificant. In some sense, therefore, we can say that almost all the potential energy of the system is embodied in the light object, and almost none in the very massive object.

See also two-body problem and gravitational binding energy.

Gravitational potential[Bearbeiten | Quelltext bearbeiten]

Gravitational potential is the potential energy per unit mass of an object due to its position in a gravitational field. The gravitational potential due to a point mass:

${\displaystyle E(r)={\frac {-Gm}{r}}\ }$

where:

• ${\displaystyle G\ }$ is the universal gravitational constant,
• ${\displaystyle r\ }$ is the distance to the center of mass of the object,
• ${\displaystyle m\ }$ is the mass of the point object.

In astrodynamics the gravitational potential function has to account for the non-spherical and non-homogeneous nature of typical sources of gravitational potential. In this case a gravitational potential may depend on polar ${\displaystyle \phi \!\,}$ and azimuth ${\displaystyle \lambda \!\,}$ direction of vector ${\displaystyle r\!\,}$.

The most widely used form of the gravitational potential function depends on ${\displaystyle \phi \!\,}$ (latitude) and potential coefficients, Jn, called the zonal coefficients:

${\displaystyle E(r,\phi )={\frac {GM}{r}}\left[1-\sum _{n=2}^{N}J_{n}\left({\frac {R}{r}}\right)^{2}P_{n}(\sin \phi )\right]}$

Elastic potential energy[Bearbeiten | Quelltext bearbeiten]

Elastic potential energy is the potential energy of an elastic object (for example a bow or a catapult) that is deformed under tension or compression (often termed under the word stress by physicists). It arises as a consequence of a force that tries to restore the object to its original shape, which is most often the electromagnetic force between the atoms and molecules that constitute the object.

Calculation of elastic potential energy[Bearbeiten | Quelltext bearbeiten]

In the case of a spring of natural length l and modulus of elasticity λ under an extension of x, elastic potential energy can be calculated using the formula:

${\displaystyle E={\frac {\lambda x^{2}}{2l}}}$

This formula is obtained from the integral of Hooke's Law:

${\displaystyle U_{e}=\int {kx}\,dx={\frac {1}{2}}kx^{2}}$

The equation is often used in calculations of positions of mechanical equilibrium.

In the general case, elastic energy is given by the Helmholtz potential per unit of volume f as a function of the strain tensor components ε_ij:

${\displaystyle f(\epsilon _{ij})=\lambda \left(\sum _{i=1}^{3}\epsilon _{ii}\right)^{2}+2\mu \sum _{i=1}^{3}\sum _{j=1}^{3}\epsilon _{ij}^{2}}$

Where λ and μ are the Lamé elastical coefficients. The connection between stress tensor components and strain tensor components is:

${\displaystyle \sigma _{ij}=\left({\frac {\partial f}{\partial \epsilon _{ij}}}\right)_{S}}$

For a material of Young's modulus, Y (same as modulus of elasticity λ), cross sectional area, A₀, initial length, l₀, which is stretched by a length, ${\displaystyle \Delta l}$:

${\displaystyle U_{e}=\int {\frac {YA_{0}\Delta l}{l_{0}}}\,dl={\frac {YA_{0}{\Delta l}^{2}}{2l_{0}}}}$

where U_e is the elastic potential energy.

The elastic potential energy per unit volume is given by:

${\displaystyle {\frac {U_{e}}{A_{0}l_{0}}}={\frac {Y{\Delta l}^{2}}{2l_{0}^{2}}}={\frac {1}{2}}Y{\varepsilon }^{2}}$

where ${\displaystyle \varepsilon ={\frac {\Delta l}{l_{0}}}}$ is the strain in the material.

Chemical potential energy[Bearbeiten | Quelltext bearbeiten]

Chemical potential energy is a form of potential energy related to the structural arrangement of atoms or molecules. This arrangement may be the result of chemical bonds within a molecule or otherwise. Chemical energy of a chemical substance can be transformed to other forms of energy by a chemical reaction. For example, when a fuel is burned the chemical energy is converted to heat, same is the case with digestion of food metabolized in a biological organism. Green plants transform solar energy to chemical energy through the process known as photosynthesis, and electrical energy can be converted to chemical energy through electrochemical reactions.

The similar term chemical potential is used by chemists to indicate the potential of a substance to undergo a chemical reaction.

Electrical potential energy[Bearbeiten | Quelltext bearbeiten]

An object can also have potential energy by virtue of its electric charge and several forces related to their presence. There are three main kinds of this kind of potential energy; electrostatic potential energy, electrodynamic potential energy (also sometimes called magnetic potential energy)and nuclear potential energy.

Electrostatic potential energy[Bearbeiten | Quelltext bearbeiten]

In case the electric charge of an object can be assumed to be at rest, it has potential energy due to its position relative to other charged objects.

The electrostatic potential energy is the energy of an electrically charged particle (at rest) in an electric field. It is defined as the work that must be done to move it from an infinite distance away to its present location, in the absence of any non-electrical forces on the object. This energy is non-zero if there is another electrically charged object nearby.

The simplest example is the case of two point-like objects A₁ and A₂ with electrical charges q₁ and q₂. The work W required to move A₁ from an infinite distance to a distance d away from A₂ is given by:

${\displaystyle W=k{\frac {q_{1}q_{2}}{d}}}$

where k is Coulomb's constant, equal to ${\displaystyle {\frac {1}{4\pi \epsilon _{0}}}}$.

This equation is obtained by integrating the Coulomb force between the limits of infinity and d.

A related quantity called electric potential is equal to electric potential energy of a unit charge.

Electrodynamic potential energy[Bearbeiten | Quelltext bearbeiten]

In case a charged object or its constituent charged particles are not at rest, it generates a magnetic field giving rise to yet another form of potential energy, often termed as magnetic potential energy. This kind of potential energy is a result of the phenomenon magnetism, whereby an object that is magnetic has the potential to move other similar objects. Magnetic objects are said to have some magnetic moment. Magnetic fields and their effects are best studied under electrodynamics.

Nuclear potential energy[Bearbeiten | Quelltext bearbeiten]

Nuclear potential energy, is the potential energy of the particles inside an atomic nucleus, some of which are indeed electrically charged. This kind of potential energy is different from the previous two kinds of electrical potential energies because in this case the charged particles are extremally close to each other. The nuclear particles are bound together not because of the coulombic force but due to strong nuclear force that binds nuclear particles more strongly and closely. Weak nuclear forces provide the potential energy for certain kinds of radioactive decay, such as beta decay.

Nuclear particles like protons and neutrons are not destroyed in fission and fusion processes, but collections of them have less mass than if they were individually free, and this mass difference is liberated as heat and radiation in nuclear reactions (the heat and radiation have the missing mass, but it often escapes from the system, where it is not measured). The energy from the Sun, also called solar energy, is an example of this form of energy conversion. In the Sun, the process of hydrogen fusion converts about 4 million metric tons of solar matter per second into light, which is radiated into space.

Thermal potential energy[Bearbeiten | Quelltext bearbeiten]

Thermal energy of an object is simply a sum of average kinetic energy of random motion of particles constituting the object plus average potential energy of their displacement (from their equilibrium positions) as they oscillate/move around it. In case of ideal gas there is no potential energy due to interactions of particles, but kinetic energy may include rotational part too (for multiatomic gases) - if rotational levels are exited at given temparature T.

Rest mass energy[Bearbeiten | Quelltext bearbeiten]

Albert Einstein was the first to calculate the amount of work needed to accelerate a body from rest to some finite speed using his definition of relativistic momentum. To his surprise, this work contained an extra term which did not vanish as the speed of accelerated body approached zero:

${\displaystyle E_{0}=mc^{2}\,}$

This term (E₀) was therefore called rest mass energy, as m is the rest mass of the body (c is the speed of light in a vacuum). (The subscript zero is used here to distinguish this form of energy from the others that follow. In most other contexts, the equation is written with no subscript.)

So, the rest mass energy is the amount of energy inherent in the mass when it is at rest. If the mass changes, so must its rest mass energy which must be released or absorbed due to energy conservation law. Thus, this equation quantifies the equivalence of mass and energy.

Due to large numerical value of squared speed of light, even a small amount of mass is equivalent to a very large amount of energy, namely 90 petajoules per kilogram ≈ 21 megaton of TNT per kilogram.

Relation between potential energy and force[Bearbeiten | Quelltext bearbeiten]

Potential energy is closely linked with forces. If the work done moving along a path which starts and ends in the same location is zero, then the force is said to be conservative and it is possible to define a numerical value of potential associated with every point in space. A force field can be re-obtained by taking the vector gradient of the potential field.

For example, gravity is a conservative force. The work done by a unit mass going from point A with ${\displaystyle U=a}$ to point B with ${\displaystyle U=b}$ by gravity is ${\displaystyle (b-a)}$ and the work done going back the other way is ${\displaystyle (a-b)}$ so that the total work done from

${\displaystyle U_{A\to B\to A}=(b-a)+(a-b)=0\,}$

If we redefine the potential at A to be ${\displaystyle a+c}$ and the potential at B to be ${\displaystyle b+c}$ [where ${\displaystyle c}$ can be any number, positive or negative, but it must be the same number for all points] then the work done going from

${\displaystyle U_{A\to B}=(b+c)-(a+c)=b-a\,}$

as before.

In practical terms, this means that you can set the zero of ${\displaystyle U}$ anywhere you like. You might set it to be zero at the surface of the Earth or you might find it more convenient to set it zero at infinity.

A thing to note about conservative forces is that the work done going from A to B does not depend on the route taken. If it did then it would be pointless to define a potential at each point in space. An example of a non-conservative force is friction. With friction, the route you take does affect the amount of work done, and it makes no sense at all to define a potential associated with friction.

All the examples above are actually force field stored energy (sometimes in disguise). For example in elastic potential energy, stretching an elastic material forces the atoms very slightly further apart. Equilibrium between electromagnetic forces and Pauli repulsion of electrons (they are fermions obeying Fermi statistics) is slightly violated resulting in small returning force. Scientists rarely talk about forces on an atomic scale. Often interactions are described in terms of energy rather than force. You can think of potential energy as being derived from force or you can think of force as being derived from potential energy (although last approach then requires independent from force definition of energy - which currently does not exist).

A conservative force can be expressed in the language of differential geometry as a closed form. Because Euclidean space is contractible, its de Rham cohomology vanishes, so every closed form is exact, i.e., is the gradient of a scalar field. This gives a mathematical justification of the fact that all conservative forces are gradients of a potential field.

References[Bearbeiten | Quelltext bearbeiten]