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'''Rutherford scattering''' is a phenomenon in [[physics]] that was explained by [[Ernest Rutherford]] in 1911,<ref>E. Rutherford , "The Scattering of α and β rays by Matter and the Structure of the Atom",Philos. Mag., vol 6, pp.21, 1911</ref> which led to the development of the [[Rutherford model]] (planetary model) of the [[atom]], and eventually to the [[Bohr model]]. It is now exploited by the materials [[analytical technique]] [[Rutherford backscattering]]. Rutherford scattering is also sometimes referred to as '''Coulomb scattering''' because it relies only upon [[static electricity|static electric]] ([[Coulomb]]) [[force]]s, and the minimal distance between particles is set only by this potential. The classical Rutherford scattering of alpha particles against gold nuclei is an example of "elastic scattering" because the energy and velocity of the outgoing scattered particle is the same as that with which it began.
{{Properties_of_mass}}
The '''Schwarzschild radius''' (sometimes historically referred to as the '''gravitational radius''') is the [[radius]] of a [[sphere]] such that, if all the [[mass]] of an object is compressed within that sphere, the [[escape velocity|escape speed]] from the surface of the sphere would equal the [[speed of light]]. An example of an object smaller than its Schwarzschild radius is a [[black hole]]. Once a [[compact star|stellar remnant]] collapses below this radius, light cannot escape and the object is no longer visible.<ref>Chaisson, Eric, and S. McMillan. Astronomy Today. San Francisco, CA: Pearson / Addison Wesley, 2008. Print.</ref> It is a characteristic radius associated with every quantity of mass. The ''Schwarzschild radius'' was  named after the [[Germany|German]] astronomer [[Karl Schwarzschild]] who calculated this exact solution for the theory of [[general relativity]] in 1916.


Rutherford also later analyzed [[inelastic scattering]] when he projected alpha particles against hydrogen nuclei (protons) ; however this latter process is not referred to as "Rutherford scattering", although Rutherford was first to observe it. At the end of such processes, non-coulombic forces come into play. These forces, and also energy gained from the scattering particle by the lighter target, change the scattering results in fundamental ways which suggest structural information about the target. A similar process probed the insides of nuclei in the 1960s, and is called [[deep inelastic scattering]].
==History==
In 1916, Karl Schwarzschild obtained an exact solution<ref>K. Schwarzschild, "Über das Gravitationsfeld eines Massenpunktes nach der Einsteinschen Theorie", ''Sitzungsberichte der Deutschen Akademie der Wissenschaften zu Berlin, Klasse fur Mathematik, Physik, und Technik'' (1916) pp 189.</ref><ref>K. Schwarzschild, "Über das Gravitationsfeld einer Kugel aus inkompressibler Flussigkeit nach der Einsteinschen Theorie", ''Sitzungsberichte der Deutschen Akademie der Wissenschaften zu Berlin, Klasse fur Mathematik, Physik, und Technik'' (1916) pp 424.</ref> to [[Einstein's field equation]]s for the gravitational field outside a non-rotating, spherically symmetric body (see [[Schwarzschild metric]]). Using the definition <math>M=\frac {Gm} {c^2}</math>, the solution contained a term of the form <math> \frac {1} {2M-r}</math>; where the value of <math>r</math> making this term [[Mathematical singularity|singular]] has come to be known as the ''Schwarzschild radius''. The physical significance of this ''[[Mathematical singularity|singularity]]'', and whether this singularity could ever occur in nature, was debated for many decades; a general acceptance of the possibility of a [[black hole]] did not occur until the second half of the 20th century.


The initial discovery was made by [[Hans Geiger]] and [[Ernest Marsden]] in 1909 when they performed the [[Geiger–Marsden experiment|gold foil experiment]] under the direction of Rutherford, in which they fired a beam of [[alpha particle]]s ([[helium]] nuclei) at layers of [[gold]] leaf only a few atoms thick. At the time of the experiment, the atom was thought to be [[plum-pudding model|analogous to a plum pudding]] (as proposed by [[J.J. Thomson]]), with the negative charges (the plums) found throughout a positive sphere (the pudding). If the [[plum-pudding model]] were correct, the positive "pudding", being more spread out than in the current model of a concentrated [[atomic nucleus|nucleus]], would not be able to exert such large coulombic forces, and the alpha particles should only be deflected by small angles as they pass through.
==Parameters==
The Schwarzschild radius of an object is proportional to the mass. Accordingly, the [[Sun]] has a Schwarzschild radius of approximately {{convert|3.0|km|mi|abbr=on}} while the [[Earth]]'s is only about 9.0&nbsp;mm, the size of a [[peanut]].  The [[observable universe]]'s mass has a Schwarzschild radius of approximately 10 billion light years.{{fact|date=April 2013}}
{| style="border:1px solid gray; border-collapse:collapse" cellpadding="5" cellspacing="0"
|-  style="border-bottom: 1px solid gray"
!
! align="center" |    <math>radius_s</math> (m)
! align="center" |    <math>density_s</math> (g/cm<sup>3</sup>)
|-
| [[Universe]]     ||align="right" | 4.46{{e|25}}{{Citation needed|date=March 2012}} (~10B [[light-year|ly]]) || align="right" | 8{{e|-29}}{{Citation needed|date=March 2012}} (9.9{{e|-30}}<ref>[http://map.gsfc.nasa.gov/universe/uni_matter.html WMAP- Content of the Universe<!-- Bot generated title -->]</ref>)
|-
| [[Milky Way]]     ||align="right" | 2.08{{e|15}} (~0.2 [[light-year|ly]]) || align="right" | 3.72{{e|-8}}
|-
| [[Sun]]    ||align="right" | 2.95{{e|3}} || align="right" | 1.84{{e|16}}
|-
| [[Earth]]   ||align="right" | 8.87{{e|-3}} || align="right" | 2.04{{e|27}}
|}


However, the intriguing results showed that around 1 in 8000 alpha particles were deflected by very large angles (over 90°), while the rest passed straight through with little or no deflection. From this, Rutherford concluded that the majority of the [[mass]] was concentrated in a minute, positively charged region (the nucleus/ central charge) surrounded by electrons. When a (positive) alpha particle approached sufficiently close to the nucleus, it was repelled strongly enough to rebound at high angles. The small size of the nucleus explained the small number of alpha particles that were repelled in this way. Rutherford showed, using the method below, that the size of the nucleus was less than about 10<sup>&minus;14</sup> m (how ''much'' less than this size, Rutherford could not tell from this experiment alone; see more below on this problem of lowest possible size).
An object whose radius is smaller than its Schwarzschild radius is called a [[black hole]]. The surface at the Schwarzschild radius acts as an [[event horizon]] in a non-rotating body (a [[rotating black hole]] operates slightly differently). Neither light nor particles can escape through this surface from the region inside, hence the name "black hole". The Schwarzschild radius of the [[supermassive black hole]] at our [[Galactic Center]] would be approximately 13.3 million kilometres.<ref>http://www.thetimes.co.uk/tto/news/world/article1967154.ece</ref>


== Derivation ==
==Formula for the Schwarzschild radius==
The differential cross section can be derived from the equations of motion for a particle interacting with a central potential.  In general, the equations of motion describing [[Two-body problem|two particles]] interacting under a central force can be decoupled into the center of mass and the motion of the particles relative to one another. For the case of light alpha particles scattering off heavy nuclei, as in the experiment performed by Rutherford, the reduced mass is essentially the mass of the alpha particle and the nucleus off of which it scatters is essentially stationary in the lab frame.
The Schwarzschild radius is proportional to the mass with a proportionality constant involving the [[gravitational constant]] and the speed of light:


Substituting into the [[Binet equation]] yields the equation of trajectory
: <math>r_\mathrm{s} = \frac{2Gm}{c^2},</math>
where:
: <math>r_s\!</math> is the Schwarzschild radius;
: <math>G\!</math> is the [[gravitational constant]];
: <math>m\!</math> is the mass of the object;
: <math>c\!</math> is the [[speed of light]] in vacuum.


: <math>\frac{d^{2}u}{d\theta^{2}}+u=-\frac{Z_{1}Z_{2}e^{2}}{4\pi\epsilon_{0}mv_{0}^{2}b^{2}}=-\kappa,</math>
The proportionality constant, 2''G''/''c''<sup>2</sup>, is approximately {{val|1.48|e=-27|u=m/kg}}, or {{val|2.95|u=km/[[solar mass]]}}.


where <math>u={1 \over r}</math>, <math>v_0</math> is the speed at infinity, and <math>b</math> is the [[impact parameter]].
An object of any density can be large enough to fall within its own Schwarzschild radius,
: <math>V_s \propto \rho^{-3/2},</math>
where:
: <math>V_s\! = \frac{4 \pi}{3} r_\mathrm{s}^3</math> is the volume of the object;


The general solution of the above differential equation is


: <math>u=u_{0}\cos(\theta-\theta_{0})-\kappa,</math>
: <math>\rho\! = \frac{ m }{ V_s\! }</math> is its density.


and the boundary condition is
==Classification by Schwarzschild radius==
===Supermassive black hole===


: <math>u\to 0 \quad r\sin\theta\to b \quad(\theta\to\pi).</math>
Assuming constant density, the Schwarzschild radius of a body is proportional to its mass, but the radius is proportional to the cube root of the volume and hence the mass. Therefore, as one accumulates matter at normal density (10<sup>3</sup> [[kilogram per cubic metre|kg/m<sup>3</sup>]], for example, the density of water), its Schwarzschild radius increases more quickly than its radius. At around 150 million (1.5 × 10<sup>8</sup>) times the mass of the Sun, such an accumulation will fall inside its own Schwarzschild radius and thus it would be a [[supermassive black hole]] of 150 million  solar masses. (Supermassive black holes up to 21 billion (2.1 × 10<sup>10</sup>) solar masses have been observed, such as [[NGC 4889]].)<ref>{{cite web|url=http://www.nature.com/nature/journal/v480/n7376/pdf/nature10636.pdf|title=Two ten-billion-solar-mass black holes at the centres of giant elliptical galaxies|last=McConnell|first=Nicholas J.|date=2011-12-08|publisher=Nature|accessdate=2011-12-06|archiveurl=http://www.webcitation.org/63jBvENqx|archivedate=2011-12-06}}</ref> The supermassive black hole in the center of our galaxy (4.5 ± 0.4 million solar masses) constitutes observationally the most convincing evidence for the existence of black holes in general.


If we choose
It is thought that large black holes like these don't form directly in one collapse of a cluster of stars.
Instead they may start as a stellar-sized black hole and grow larger by the accretion of matter and other black holes. An empirical correlation between the size of supermassive black holes and the stellar [[Velocity dispersion|velocity
dispersion]] <math>\sigma</math> of a [[galaxy]] [[bulge (astronomy)|bulge]]<ref name=gnuk09>{{cite journal |author=Gultekin K, ''et al.'' |year=2009 |bibcode=2009ApJ...698..198G |title=The M<math>-\sigma</math> and M-L Relations in Galactic Bulges, and Determinations of Their Intrinsic Scatter |journal=The Astrophysical Journal |volume=698 |issue=1 |pages=198–221 |doi=10.1088/0004-637X/698/1/198|arxiv = 0903.4897 }}</ref> is called the [[M-sigma relation]].


: <math>\theta_{0}=\frac{\pi}{2}+\arctan b\kappa.</math>
===Stellar black hole===


then the [[deflection angle]] Θ can be seen from solving <math>u\to 0</math> as
If one accumulates matter at [[nuclear density]] (the density of the nucleus of an atom, about 10<sup>18</sup> [[kilogram per cubic metre|kg/m<sup>3</sup>]]; [[neutron star]]s also reach this density), such an accumulation would fall within its own Schwarzschild radius at about 3 solar masses and thus would be a [[stellar black hole]].


: <math>\Theta=2\theta_{0}-\pi=2\arctan b\kappa=2\arctan\frac{Z_{1}Z_{2}e^{2}}{4\pi\epsilon_{0}mv_{0}^{2}b}.</math>
===Primordial black hole===


''b'' can be solved to give
Conversely, a small mass has an extremely small Schwarzschild radius. A mass similar to [[Mount Everest]] has a Schwarzschild radius smaller than a [[nanometre]]. Its average density at that size would be so high that no known mechanism could form such extremely compact objects. Such black holes might possibly be formed in an early stage of the evolution of the universe, just after the [[Big Bang]], when densities were extremely high. Therefore these hypothetical miniature black holes are called [[primordial black hole]]s.


: <math>b=\frac{Z_{1}Z_{2}e^{2}}{4\pi\epsilon_{0}mv_{0}^{2}}\cot\frac{\Theta}{2}.</math>
== Other uses for the Schwarzschild radius ==
=== The Schwarzschild radius in gravitational time dilation ===


To find the scattering cross section from this result consider its definition
[[Gravitational time dilation]] near a large, slowly rotating, nearly spherical body, such as the earth or sun can be reasonably approximated using the Schwarzschild radius as follows:


:: <math>{\frac{d\sigma}{d\Omega}(\Omega) d \Omega}={\hbox{number of particles scattered into solid angle d} \Omega \hbox{ per unit time} \over \hbox{incident intensity}}</math>
:<math> \frac{t_r}{t} = \sqrt{1 - \frac{r_s}{r}} </math>


Since the scattering angle is uniquely determined for a given <math> E</math> and <math> b</math>, the number of particles scattered into an angle between <math>\Theta</math> and <math>\Theta+d\Theta</math> must be the same as the number of particles with associated impact parameters between <math>b</math> and <math>b+db</math>. For an incident intensity <math> I </math>, this implies the following equality
where:
: <math>t_r\!</math> is the elapsed time for an observer at radial coordinate "r" within the gravitational field;
: <math>t\!</math> is the elapsed time for an observer distant from the massive object (and therefore outside of the gravitational field);
: <math>r\!</math> is the radial coordinate of the observer (which is analogous to the classical distance from the center of the object);
: <math>r_s\!</math> is the Schwarzschild radius.


:: <math>2\pi I b \left|db\right| = I \frac{d\sigma}{d\Omega} d\Omega </math>
The results of the [[Pound-Rebka-Snider experiment|Pound, Rebka]] experiment in 1959 were found to be consistent with predictions made by general relativity. By measuring Earth’s gravitational time dilation, this experiment indirectly measured Earth’s Schwarzschild radius.


For a radially symmetric scattering potential, as in the case of the Coulombic potential, <math> d\Omega = 2\pi\sin{\Theta}d\Theta</math>, yielding the expression for the scattering cross section
=== The Schwarzschild radius in Newtonian gravitational fields ===
The Newtonian gravitational field near a large, slowly rotating, nearly spherical body can be reasonably approximated using the Schwarzschild radius as follows:


:: <math> \frac{d\sigma}{d\Omega} = \frac{b}{\sin{\Theta}} \left|\frac{db}{d\Theta}\right| </math>
: <math> \frac{g}{r_s} \left( \frac{r}{c} \right)^2 = \frac{1}{2} </math>
where:


Finally, plugging in the previously derived expression for the impact parameter <math> b(\Theta) </math> we find the Rutherford scattering cross section
: <math>g\!</math> is the gravitational acceleration at radial coordinate "r";
: <math>r_s\!</math> is the Schwarzschild radius of the gravitating central body;
: <math>r\!</math> is the radial coordinate;
: <math>c\!</math> is the [[speed of light]] in vacuum.


:: <math> \frac{d\sigma}{d\Omega} =\left(\frac{ Z_1 Z_2 e^2}{8\pi\epsilon_0 m v_0^2}\right)^2 \csc^4{\left(\frac{\Theta}{2}\right)}. </math>
On the surface of the Earth:


==Details of calculating maximal nuclear size==
: <math> \frac{ 9.80665 \ \mathrm{m} / \mathrm{s}^2 }{ 8.870056 \ \mathrm{mm} } \left( \frac{6375416 \ \mathrm{m} }{299792458 \ \mathrm{m} / \mathrm{s} } \right)^2 = \left( 1105.59 \ \mathrm{s}^{-2} \right)  \left( 0.0212661 \ \mathrm{s} \right)^2 = \frac{1}{2}.</math>
For head on collisions between alpha particles and the nucleus, all the [[kinetic energy]] of the alpha particle is turned into [[potential energy]] and the particle is at rest. The distance from the centre of the alpha particle to the centre of the nucleus (''b'') at this point is a maximum value for the radius, if it is evident from the experiment that the particles have not hit the nucleus.  


Applying the [[inverse-square law]] between the charges on the electron and nucleus, one can write:
=== The Schwarzschild radius in Keplerian orbits ===
For all [[circular orbit]]s around a given central body:


:<math>\frac{1}{2} mv^2 = \frac{1}{4\pi \epsilon_0} \cdot \frac{q_1 q_2}{b}</math>
: <math> \frac{r}{r_s} \left( \frac{v}{c} \right)^2 = \frac{1}{2} </math>
where:
: <math>r\!</math> is the orbit [[radius]];
: <math>r_s\!</math> is the Schwarzschild radius of the gravitating central body;
: <math>v\!</math> is the [[orbital speed]];
: <math>c\!</math> is the [[speed of light]] in vacuum.


Rearranging:
This equality can be generalized to [[elliptic orbit]]s as follows:


:<math>b = \frac{1}{4\pi \epsilon_0} \cdot \frac{2 q_1 q_2}{mv^2}</math>
: <math> \frac{a}{r_s} \left( \frac{2 \pi a}{c T} \right)^2 = \frac{1}{2} </math>
where:
:<math>a\!</math> is the [[semi-major axis]];
:<math>T\!</math> is the [[orbital period]].


For an alpha particle:
For the Earth orbiting the Sun:
* '''m''' (mass) = 6.7×10<sup>&minus;27</sup>&nbsp;kg
* '''q<sub>1</sub>''' = 2×(1.6×10<sup>&minus;19</sup>)&nbsp;C
* '''q<sub>2</sub>''' (for gold) = 79×(1.6×10<sup>&minus;19</sup>)&nbsp;C
* '''v''' (initial velocity) = 2×10<sup>7</sup>&nbsp;m/s


Substituting these in gives the value of about 2.7×10<sup>&minus;14</sup>&nbsp;m. (The true radius is about 7.3×10<sup>&minus;15</sup>&nbsp;m.)  The true radius of the nucleus is not recovered in these experiments because the alphas do not have enough energy to penetrate to more than 27 fm of the nuclear center, as noted, when the actual radius of gold is 7.3 fm. Rutherford realized this, and also realized that actual impact of the alphas on gold causing any force-deviation from that of the 1/r coulomb potential would change the ''form'' of his scattering curve at high scattering angles (the smallest [[impact parameter]]s) from a [[hyperbola]] to something else. This was not seen, indicating that the gold had not been "hit" so that Rutherford also knew the gold nucleus (or the sum of the gold and alpha radii) was smaller than 27 fm (2.7×10<sup>&minus;14</sup>&nbsp;m)
: <math>\frac{1 \,\mathrm{AU}}{2953.25\,\mathrm m} \left( \frac{2 \pi \,\mathrm{AU}}{\mathrm{light\,year}} \right)^2 = \left(50 655 379.7 \right) \left(9.8714403 \times 10^{-9} \right)= \frac{1}{2}.</math>


== {{anchor|Extension to situations with relativistic particles and target recoil}}Extension to situations with relativistic particles and target recoil ==
=== Relativistic circular orbits and the photon sphere ===
The Keplerian equation for circular orbits can be generalized to the relativistic equation for circular orbits by accounting for time dilation in the velocity term:


The extension of Rutherford-type scattering to energy regions in which the incoming particle has spin and magnetic moment, and is traveling at relativistic energies, and there is enough momentum-transfer that the struck particle recoils with some of the incoming particle's energy (so the process is [[inelastic]] rather than [[elastic collision|elastic]]), is called [[Mott scattering]].<ref>[http://hyperphysics.phy-astr.gsu.edu/hbase/nuclear/elescat.html Hyperphysics link]</ref>
: <math> \frac{r}{r_s} \left( \frac{v}{c} \sqrt{1 - \frac{r_s}{r}} \right)^2 = \frac{1}{2} </math>


== See also ==
: <math> \frac{r}{r_s} \left( \frac{v}{c} \right)^2 \left(1 - \frac{r_s}{r} \right) = \frac{1}{2} </math>
*[[Rutherford backscattering spectrometry]]
 
: <math> \left( \frac{v}{c} \right)^2 \left( \frac{r}{r_s} - 1 \right) = \frac{1}{2}.</math>
 
This final equation indicates that an object orbiting at the speed of light would have an orbital radius of 1.5 times the Schwarzschild radius.  This is a special orbit known as the [[photon sphere]].
 
==See also==
*[[Black hole]], a general survey
*[[Chandrasekhar limit]], a second requirement for black hole formation
*[[John Michell]]
Classification of black holes by type:
*[[Schwarzschild black hole|Schwarzschild or static black hole]]
*[[Rotating black hole|Rotating or Kerr black hole]]
*[[Charged black hole|Charged black hole or Newman black hole and Kerr-Newman black hole]]
A classification of black holes by mass:
*[[Micro black hole]] and extra-dimensional black hole
*[[Primordial black hole]], a hypothetical leftover of the Big Bang
*[[Stellar black hole]], which could either be a static black hole or a rotating black hole
*[[Supermassive black hole]], which could also either be a static black hole or a rotating black hole
*[[Visible universe]], if its density is the [[Friedmann_equations#Density_parameter|critical density]]


==References==
==References==
{{reflist}}
{{Reflist}}
 
== Textbooks ==
* {{cite book | first = Herbert| last = Goldstein| authorlink = Herbert Goldstein| first2=Charles|last2=Poole|first3=John|last3=Safko | year = 2002 | month = | title = Classical Mechanics | chapter = | editor =  | others =  | edition = third | pages =  | publisher = Adison Wesley| location = | isbn = 0-201-65702-3 | url = }}


== External links ==
{{Black holes}}
* E. Rutherford, [http://www.lawebdefisica.com/arts/structureatom.pdf ''The Scattering of α and β Particles by Matter and the Structure of the Atom''],  Philosophical Magazine. Series 6, vol. '''21'''. May 1911
* Geiger H. & Marsden E. (1909). [http://dbhs.wvusd.k12.ca.us/webdocs/Chem-History/GM-1909.html "On a Diffuse Reflection of the α-Particles"]. Proceedings of the Royal Society, Series A 82: 495-500. {{doi|10.1098/rspa.1909.0054}}.


{{DEFAULTSORT:Rutherford Scattering}}
<!--Categories-->
[[Category:Scattering]]
[[Category:Black holes]]
[[Category:Foundational quantum physics]]
[[Category:Ernest Rutherford]]

Revision as of 17:44, 12 December 2013

Template:Properties of mass The Schwarzschild radius (sometimes historically referred to as the gravitational radius) is the radius of a sphere such that, if all the mass of an object is compressed within that sphere, the escape speed from the surface of the sphere would equal the speed of light. An example of an object smaller than its Schwarzschild radius is a black hole. Once a stellar remnant collapses below this radius, light cannot escape and the object is no longer visible.[1] It is a characteristic radius associated with every quantity of mass. The Schwarzschild radius was named after the German astronomer Karl Schwarzschild who calculated this exact solution for the theory of general relativity in 1916.

History

In 1916, Karl Schwarzschild obtained an exact solution[2][3] to Einstein's field equations for the gravitational field outside a non-rotating, spherically symmetric body (see Schwarzschild metric). Using the definition , the solution contained a term of the form ; where the value of making this term singular has come to be known as the Schwarzschild radius. The physical significance of this singularity, and whether this singularity could ever occur in nature, was debated for many decades; a general acceptance of the possibility of a black hole did not occur until the second half of the 20th century.

Parameters

The Schwarzschild radius of an object is proportional to the mass. Accordingly, the Sun has a Schwarzschild radius of approximately Template:Convert while the Earth's is only about 9.0 mm, the size of a peanut. The observable universe's mass has a Schwarzschild radius of approximately 10 billion light years.Template:Fact

(m) (g/cm3)
Universe 4.46Template:EPotter or Ceramic Artist Truman Bedell from Rexton, has interests which include ceramics, best property developers in singapore developers in singapore and scrabble. Was especially enthused after visiting Alejandro de Humboldt National Park. (~10B ly) 8Template:EPotter or Ceramic Artist Truman Bedell from Rexton, has interests which include ceramics, best property developers in singapore developers in singapore and scrabble. Was especially enthused after visiting Alejandro de Humboldt National Park. (9.9Template:E[4])
Milky Way 2.08Template:E (~0.2 ly) 3.72Template:E
Sun 2.95Template:E 1.84Template:E
Earth 8.87Template:E 2.04Template:E

An object whose radius is smaller than its Schwarzschild radius is called a black hole. The surface at the Schwarzschild radius acts as an event horizon in a non-rotating body (a rotating black hole operates slightly differently). Neither light nor particles can escape through this surface from the region inside, hence the name "black hole". The Schwarzschild radius of the supermassive black hole at our Galactic Center would be approximately 13.3 million kilometres.[5]

Formula for the Schwarzschild radius

The Schwarzschild radius is proportional to the mass with a proportionality constant involving the gravitational constant and the speed of light:

where:

is the Schwarzschild radius;
is the gravitational constant;
is the mass of the object;
is the speed of light in vacuum.

The proportionality constant, 2G/c2, is approximately Template:Val, or Template:Val.

An object of any density can be large enough to fall within its own Schwarzschild radius,

where:

is the volume of the object;


is its density.

Classification by Schwarzschild radius

Supermassive black hole

Assuming constant density, the Schwarzschild radius of a body is proportional to its mass, but the radius is proportional to the cube root of the volume and hence the mass. Therefore, as one accumulates matter at normal density (103 kg/m3, for example, the density of water), its Schwarzschild radius increases more quickly than its radius. At around 150 million (1.5 × 108) times the mass of the Sun, such an accumulation will fall inside its own Schwarzschild radius and thus it would be a supermassive black hole of 150 million solar masses. (Supermassive black holes up to 21 billion (2.1 × 1010) solar masses have been observed, such as NGC 4889.)[6] The supermassive black hole in the center of our galaxy (4.5 ± 0.4 million solar masses) constitutes observationally the most convincing evidence for the existence of black holes in general.

It is thought that large black holes like these don't form directly in one collapse of a cluster of stars. Instead they may start as a stellar-sized black hole and grow larger by the accretion of matter and other black holes. An empirical correlation between the size of supermassive black holes and the stellar velocity dispersion of a galaxy bulge[7] is called the M-sigma relation.

Stellar black hole

If one accumulates matter at nuclear density (the density of the nucleus of an atom, about 1018 kg/m3; neutron stars also reach this density), such an accumulation would fall within its own Schwarzschild radius at about 3 solar masses and thus would be a stellar black hole.

Primordial black hole

Conversely, a small mass has an extremely small Schwarzschild radius. A mass similar to Mount Everest has a Schwarzschild radius smaller than a nanometre. Its average density at that size would be so high that no known mechanism could form such extremely compact objects. Such black holes might possibly be formed in an early stage of the evolution of the universe, just after the Big Bang, when densities were extremely high. Therefore these hypothetical miniature black holes are called primordial black holes.

Other uses for the Schwarzschild radius

The Schwarzschild radius in gravitational time dilation

Gravitational time dilation near a large, slowly rotating, nearly spherical body, such as the earth or sun can be reasonably approximated using the Schwarzschild radius as follows:

where:

is the elapsed time for an observer at radial coordinate "r" within the gravitational field;
is the elapsed time for an observer distant from the massive object (and therefore outside of the gravitational field);
is the radial coordinate of the observer (which is analogous to the classical distance from the center of the object);
is the Schwarzschild radius.

The results of the Pound, Rebka experiment in 1959 were found to be consistent with predictions made by general relativity. By measuring Earth’s gravitational time dilation, this experiment indirectly measured Earth’s Schwarzschild radius.

The Schwarzschild radius in Newtonian gravitational fields

The Newtonian gravitational field near a large, slowly rotating, nearly spherical body can be reasonably approximated using the Schwarzschild radius as follows:

where:

is the gravitational acceleration at radial coordinate "r";
is the Schwarzschild radius of the gravitating central body;
is the radial coordinate;
is the speed of light in vacuum.

On the surface of the Earth:

The Schwarzschild radius in Keplerian orbits

For all circular orbits around a given central body:

where:

is the orbit radius;
is the Schwarzschild radius of the gravitating central body;
is the orbital speed;
is the speed of light in vacuum.

This equality can be generalized to elliptic orbits as follows:

where:

is the semi-major axis;
is the orbital period.

For the Earth orbiting the Sun:

Relativistic circular orbits and the photon sphere

The Keplerian equation for circular orbits can be generalized to the relativistic equation for circular orbits by accounting for time dilation in the velocity term:

This final equation indicates that an object orbiting at the speed of light would have an orbital radius of 1.5 times the Schwarzschild radius. This is a special orbit known as the photon sphere.

See also

Classification of black holes by type:

A classification of black holes by mass:

References

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  1. Chaisson, Eric, and S. McMillan. Astronomy Today. San Francisco, CA: Pearson / Addison Wesley, 2008. Print.
  2. K. Schwarzschild, "Über das Gravitationsfeld eines Massenpunktes nach der Einsteinschen Theorie", Sitzungsberichte der Deutschen Akademie der Wissenschaften zu Berlin, Klasse fur Mathematik, Physik, und Technik (1916) pp 189.
  3. K. Schwarzschild, "Über das Gravitationsfeld einer Kugel aus inkompressibler Flussigkeit nach der Einsteinschen Theorie", Sitzungsberichte der Deutschen Akademie der Wissenschaften zu Berlin, Klasse fur Mathematik, Physik, und Technik (1916) pp 424.
  4. WMAP- Content of the Universe
  5. http://www.thetimes.co.uk/tto/news/world/article1967154.ece
  6. Template:Cite web
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