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Proton


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For other uses, see Proton (disambiguation) .
/*Proton*/

Quark structure proton.svg 

The quark structure of the proton. (The color assignment of individual
quarks is not important, only that all three colors are present.)

*Classification:* 	Baryon 
*Composition:* 	2 up quarks , 1 down quark

*Particle statistics :* 	Fermionic

*Group:* 	Hadron 
*Interaction :* 	Gravity ,
Electromagnetic , Weak
, Strong 
*Symbol(s):* 	p, p^+ , N^+
*Antiparticle :* 	Antiproton 
*Theorized:* 	William Prout  (1815)
*Discovered:* 	Ernest Rutherford  (1919)
*Mass :* 	1.672621637(83)×10^−27  kg 
938.272013(23) MeV//c/^2 
1.00727646677(10) u ^[1] 
*Mean lifetime :* 	>2.1×10^29  yr (stable)
*Electric charge :* 	+1 /e/ 
1.602176487(40)×10^−19  C ^[1] 
*Charge radius
:* 	0.877 fm
^[1] 
*Electric dipole moment :* 	<5.4×10^−24  e·cm
*Electric polarizability
:* 	1.20(6)×10^−3  fm^3
*Magnetic moment :* 	2.792847351(28) μ_N

*Magnetic polarizability
:* 	1.9(5)×10^−4  fm^3
*Spin :* 	^1 ⁄_2
*Isospin :* 	^1 ⁄_2
*Parity :* 	+1
*Condensed:* 	/I /(/J /^/P
/ ) = ^1 ⁄_2 (^1 ⁄_2 ^+ )

The *proton* is a subatomic particle  with an
electric charge  of +1 elementary charge
. It is found in the nucleus
of each atom , along with neutrons
, but is also stable by itself and has a second identity
as the hydrogen ion , H^+ . It is composed of three
fundamental particles : two up quarks
and one down quark .^[2]



Contents

[hide ]

* 1 Description 
* 2 Stability 
* 3 Quarks and the mass of the proton

* 4 The proton in chemistry 
o 4.1 Atomic number 
o 4.2 Hydrogen as proton 
* 5 History 
* 6 Exposure 
* 7 Antiproton 
* 8 See also 
* 9 References 
* 10 External links 


[edit ] Description

Protons are spin-½ fermions and are composed of three quarks ,^[3] making
them baryons (a sub-type of hadrons ). The two up quarks and one down
quark of the proton are held together by the strong force , mediated by
gluons .^[2] The proton has an approximately exponentially decaying
positive charge distribution with a mean square radius of about 0.8
fm.^[4]


Protons and neutrons are both nucleons , which may be bound by the nuclear
force into atomic nuclei . The nucleus of the most common isotope of the
hydrogen atom is a lone proton. The nuclei of the heavy hydrogen isotopes
deuterium and tritium contain one proton bound to one and two neutrons,
respectively. All other types of atoms are composed of two or more protons
and various numbers of neutrons. The number of protons in the nucleus
determines the chemical properties of the atom and thus which chemical
element is represented; it is the number of both neutrons and protons in a
nuclide which determine the particular isotope of an element.


[edit ] Stability

Main article: Proton decay

Protons are observed to be stable and their empirically observed half-life
is at least 6.6×10^35 yr.^[5] Grand unified theories generally predict
that proton decay should take place, although experiments so far have only
resulted in a lower limit of 10^33 years for the proton's lifetime. In
other words, proton decay has never been witnessed and the experimental
lower bound on the mean proton lifetime (2.1×10^29 yr) is given by the
Sudbury Neutrino Observatory .^[6]

However, protons are known to transform into neutrons through the process
of electron capture (also called inverse beta decay). For free protons
this process does not occur spontaneously but only when energy is
supplied. The equation is:

\mathrm{p}^+ + \mathrm{e}^- \rightarrow\mathrm{n} + {\nu}_\text{e} ,

where /p/ is a proton, /e/ is an electron , /n/ is a neutron, and /ν/_e
is an electron neutrino .

The process is reversible; neutrons can convert back to protons through
beta decay , a common form of radioactive decay . In fact, a free neutron
decays this way with a mean lifetime of about 15 minutes.


[edit ] Quarks and the mass of the proton

In quantum chromodynamics , the modern theory of the nuclear force, most
of the mass of the proton and the neutron is explained by special
relativity. The mass of the proton is about eighty times greater than the
sum of the rest masses of the quarks that make it up, while the gluons
have zero rest mass. The extra energy of the quarks and gluons in a region
within a proton, as compared to the energy of the quarks and gluons in the
QCD vacuum , accounts for over 98% of the mass.

The internal dynamics of the proton are complicated, because they are
determined by the quarks exchanging gluons, and interacting with various
vacuum condensates. Lattice QCD provides a way of calculating the mass of
the proton directly from the theory to any accuracy, in principle. The
most recent calculations^[7] ^[8] claim that the mass is determined to
better than 4% accuracy, arguably accurate to 1% (see Figure S5 in Dürr
/et al./^[8] ). These claims are still controversial, because the
calculations cannot yet be done with quarks as light as they are in the
real world. This means that the predictions are found by a process of
extrapolation , which can introduce systematic errors.^[9] It is hard to
tell whether these errors are controlled properly, because the quantities
that are compared to experiment are the masses of the hadrons , which are
known in advance.

These recent calculations are performed by massive supercomputers, and, as
noted by Boffi and Pasquini: “a detailed description of the nucleon
structure is still missing because ... long-distance behavior requires a
nonperturbative and/or numerical treatment..." ^[10] More conceptual
approaches to the structure of the proton are: the topological soliton
approach originally due to Tony Skyrme and the more accurate AdS/QCD
approach which extends it to include a string theory of gluons, various
QCD inspired models like the bag model and the constituent quark model ,
which were popular in the 1980s, and the SVZ sum rules which allow for
rough approximate mass calculations. These methods don't have the same
accuracy as the more brute force lattice QCD methods, at least not yet.


[edit ] The proton in chemistry


[edit ] Atomic number

In chemistry the number of protons in the nucleus of an atom is known as
the atomic number , which determines the chemical element to which the
atom belongs. For example, the atomic number of chlorine is 17; this means
that each chlorine atom has 17 protons and that all atoms with 17 protons
are chlorine atoms. The chemical properties of each atom are determined by
the number of (negatively charged) electrons , which for neutral atoms is
equal to the number of (positive) protons so that the total charge is
zero. For example, a neutral chlorine atom has 17 protons and 17
electrons, while a negative Cl^− ion has 17 protons and 18 electrons for
a total charge of −1.

All atoms of a given element are not necessarily identical, however, as
the number of neutrons may vary to form different isotopes , and energy
level may differ forming different isomers . For example, there are two
stable isotopes of chlorine : 3517Cl and 3717Cl.


[edit ] Hydrogen as proton

Since the atomic number of hydrogen is 1, a positive hydrogen ion (H^+ )
has no electrons and corresponds to a bare nucleus with 1 proton (and 0
neutrons for the most abundant isotope 11H ). In chemistry and biology
therefore, the word "proton" is commonly used as a synonym for hydrogen
ion (H^+ ) or hydrogen nucleus in several contexts:

1. The transfer of H^+ in an acid-base reaction is referred to as "proton
transfer". The acid is referred to as a proton donor and the base as a
proton acceptor. 2. The hydronium ion (H_3 O^+ ) in aqueous solution
corresponds to a hydrated hydrogen ion. Often the water molecule is
ignored and the ion written as simply H^+ (aq) or just H^+ , and referred
to as a "proton". This is the usual meaning in biochemistry , as in the
term proton pump which refers to a protein or enzyme which controls the
movement of H^+ ions across cell membranes. 3. Proton NMR refers to the
observation of hydrogen nuclei in (mostly organic) molecules by nuclear
magnetic resonance . This method uses the spin of the proton, which has
the value one-half.


[edit ] History

The concept of a hydrogen-like particle as a constituent of other atoms
was developed over a long period. As early as 1815, William Prout proposed
that all atoms are composed of hydrogen atoms, based on a simplistic
interpretation of early values of atomic weights (see Prout's hypothesis
), which was disproved when more accurate values were measured.

In 1886 Eugen Goldstein discovered canal rays (also known as anode rays)
and showed that they were positively charged particles (ions) produced
from gases. However, since particles from different gases had different
values of charge-to-mass ratio (e/m), they could not be identified with a
single particle, unlike the negative electrons discovered by J. J. Thomson
.

Following the discovery of the atomic nucleus by Ernest Rutherford in
1911, Antonius van den Broek proposed that the place of each element in
the periodic table (its atomic number) is equal to its nuclear charge.
This was confirmed experimentally by Henry Moseley in 1913 using X-ray
spectra. In 1919 Rutherford proved that the hydrogen nucleus is present in
other nuclei, a result usually described as the discovery of the
proton.^[11] He noticed that when alpha particles were shot into nitrogen
gas, his scintillation detectors showed the signatures of hydrogen nuclei.
Rutherford determined that this hydrogen could only have come from the
nitrogen, and therefore nitrogen must contain hydrogen nuclei. The
hydrogen nucleus is therefore present in other nuclei as an elementary
particle, which Rutherford named the proton, after the neuter singular of
the Greek word for "first", πρῶτον.


[edit ] Exposure

The Apollo Lunar Surface Experiments Packages (ALSEP) determined that more
than 95% of the particles in the solar wind are electrons and protons, in
approximately equal numbers.^[12] ^[13]

Because the Solar Wind Spectrometer made continuous measurements, it was
possible to measure how the Earth's magnetic field affects arriving solar
wind particles. For about two-thirds of each orbit, the Moon is outside of
the Earth's magnetic field. At these times, a typical proton density was
10 to 20 per cubic centimeter, with most protons having velocities between
400 and 650 kilometers per second. For about five days of each month, the
Moon is inside the Earth's geomagnetic tail, and typically no solar wind
particles were detectable. For the remainder of each lunar orbit, the Moon
is in a transitional region known as the magnetosheath , where the Earth's
magnetic field affects the solar wind but does not completely exclude it.
In this region, the particle flux is reduced, with typical proton
velocities of 250 to 450 kilometers per second. During the lunar night,
the spectrometer was shielded from the solar wind by the Moon and no solar
wind particles were measured.^[12]

Research has been performed on the dose-rate effects of protons, as
typically found in space travel , on human health.^[13] ^[14] More
specifically, there are hopes to identify what specific chromosomes are
damaged, and to define the damage, during cancer development from proton
exposure.^[13] Another study looks into determining "the effects of
exposure to proton irradiation on neurochemical and behavioral endpoints,
including dopaminergic functioning, amphetamine -induced conditioned taste
aversion learning, and spatial learning and memory as measured by the
Morris water maze ."^[14] Electrical charging of a spacecraft due to
interplanetary proton bombardment has also been proposed for study.^[15]
There are many more studies which pertain to space travel, including
galactic cosmic rays and their possible health effects , and solar proton
event exposure.

The American Biostack and Soviet Biorack space travel experiments have
demonstrated the severity of molecular damage induced by heavy ions on
micro organisms including Artemia cysts.^[16]


[edit ] Antiproton

Main article: Antiproton

CPT-symmetry puts strong constraints on the relative properties of
particles and antiparticles and, therefore, is open to stringent tests.
For example, the charges of the proton and antiproton must sum to exactly
zero. This equality has been tested to one part in 10^8 . The equality of
their masses has also been tested to better than one part in 10^8 . By
holding antiprotons in a Penning trap , the equality of the charge to mass
ratio of the proton and the antiproton has been tested to one part in
6×10^9 .^[17] The magnetic moment of the antiproton has been measured
with error of 8×10^−3 nuclear Bohr magnetons , and is found to be equal
and opposite to that of the proton.


[edit ] See also

* Electron * Fermion field * Hydrogen * Hydron (chemistry)  * List of
particles * Neutron * Particle physics * Proton decay * Proton-proton
chain reaction * Proton therapy * Quark model * Subatomic particle


[edit ] References

1. ^ ^/*a*/ ^/*b*/ ^/*c*/ C. Amsler /et al./ (Particle Data Group )
(2008). "Review of Particle Physics". /Physics Letters B / *667*: 1. doi
:10.1016/j.physletb.2008.07.018 .  2. ^ ^/*a*/ ^/*b*/ W.N. Cottingham,
D.A. Greenwood (1986). /An Introduction to Nuclear Physics/. Cambridge
University Press . p. 19.  3. *^ * R.K. Adair (1989). /The Great Design:
Particles, Fields, and Creation/. Oxford University Press . p. 214.  4. *^
* J.-L. Basdevant, J. Rich, M. Spiro (2005). /Fundamentals in Nuclear
Physics/ . Springer . p. 155. ISBN 0-387-01672-4 .
http://books.google.com/books?id=OFx7P9mgC9oC&pg=PA375&dq=helium+%22nuclear+structure%22&lr=&as_brr=0#PPA155,M1.  
5. *^ * H. Nishino /et al./ (Kamiokande collaboration ) (2009). "Search
for Proton Decay via p → e^+ π^0 and p → μ^+ π^0 in a Large Water
Cherenkov Detector". /Physical Review Letters / *102*: 141801. doi
:10.1103/PhysRevLett.102.141801 .  6. *^ * S.N. Ahmed /et al./ (SNO
Collaboration ) (2004). "Constraints on nucleon decay via /invisible/
modes from the Sudbury Neutrino Observatory". /Physical Review Letters /
*92*: 102004. doi :10.1103/PhysRevLett.92.102004 .  7. *^ * See this news
report

and links 8. ^ ^/*a*/ ^/*b*/ S. Dürr, Z. Fodor, J. Frison, C. Hoelbling,
R. Hoffmann, S. D. Katz, S. Krieg, T. Kurth, L. Lellouch, T. Lippert, K.
K. Szabo, and G. Vulvert (21 November 2008). "/Ab Initio/ Determination of
Light Hadron Masses" . /Science/ *322 (5905)*: 1224. doi
:10.1126/science.1163233 .
http://www.sciencemag.org/cgi/data/322/5905/1224/DC1/1.  9. *^ * C. F.
Perdrisat, V. Punjabi, M. Vanderhaeghen (2007). "Nucleon Electromagnetic
Form Factors" . /Prog Part Nucl Phys/ *59*: 694–764.
http://arxiv.org/abs/hep-ph/0612014v2.  10. *^ * Sigfrido Boffi & Barbara
Pasquini (2007). "Generalized parton distributions and the structure of
the nucleon" . /Riv Nuovo Cim/ *30*. http://arxiv.org/abs/0711.2625v2.  
11. *^ * R.H. Petrucci, W.S. Harwood, and F.G. Herring (2002). /General
Chemistry/ (8th ed.). p. 41.  12. ^ ^/*a*/ ^/*b*/ "Apollo 11 Mission" .
Lunar and Planetary Institute . 2009.
http://www.lpi.usra.edu/lunar/missions/apollo/apollo_11/experiments/swc/.
Retrieved 2009-06-12.  13. ^ ^/*a*/ ^/*b*/ ^/*c*/ "Space Travel and Cancer
Linked? Stony Brook Researcher Secures NASA Grant to Study Effects of
Space Radiation" . Brookhaven National Laboratory . 12 December 2007.
http://www.bnl.gov/bnlweb/pubaf/pr/PR_display.asp?prID=07-X17. Retrieved
2009-06-12.  14. ^ ^/*a*/ ^/*b*/ B. Shukitt-Hale, A. Szprengiel, J.
Pluhar, B.M. Rabin, and J.A. Joseph. "The effects of proton exposure on
neurochemistry and behavior" . Elsevier /COSPAR .
http://biblioteca.universia.net/ficha.do?id=43176300. Retrieved
2009-06-12.  15. *^ * N.W. Green and A.R. Frederickson. "A Study of
Spacecraft Charging due to Exposure to Interplanetary Protons" . Jet
Propulsion Laboratory .
http://trs-new.jpl.nasa.gov/dspace/bitstream/2014/39501/1/05-0657.pdf.
Retrieved 2009-06-12.  16. *^ * H. Planel (2004). /Space and life: an
introduction to space biology and medicine/ . CRC Press . pp. 135–138.
ISBN 0415317592 .
http://books.google.ca/books?id=rnUFZ24RUdYC&pg=PA132&lpg=PA132&dq=space+colonization+proton+exposure&source=bl&ots=WJSg7OHZ7y&sig=BGHTwk38MHKN3oclFhe9e44TAz4&hl=en&ei=t_B6SpnmJYXMNZ_ooOUC&sa=X&oi=book_result&ct=result&resnum=8#v=onepage&q=&f=false.  
17. *^ * G. Gabrielse (2006). "Antiproton mass measurements".
/International Journal of Mass Spectrometry / *251* (2–3): 273–280.
doi :10.1016/j.ijms.2006.02.013 .


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