HOME | REACH US  
 



.com .net .org .info .mobi
.biz .us .co.uk .in
.eu .ws .bz .cc .tv Etc.
Domain Names

Website Development
Web Hosting
Email Hosting
Digital Certificate Etc.

@ Best Prices From
www.DomainsUAE.com
Neutron
   
Google
 
Web libraryoflibrary.com
This article is about the subatomic particle. For other uses, see Neutron (disambiguation).
This article is a discussion of neutrons in general. For the specific case of a neutron found outside the nucleus, see free neutron.
Neutron

The quark structure of the neutron.
Classification: Baryon
Composition: one up, two down
Family: Fermion
Group: Quark
Interaction: Gravity,Weak, Strong
Antiparticle: Antineutron
Discovered: James Chadwick[1] (1932)
Symbol: n, n0, N0
Mass: 1.67492729(28)×10-27 kg
939.56556(81) MeV/c2
1.008664915(6) u[2]
Mean lifetime: 885.7(8) s (free)
Electric charge: 0 C
Spin: ½
The Feynman diagram of the neutron beta decay process
The Feynman diagram of the neutron beta decay process

The neutron is a subatomic particle with no net electric charge and a mass slightly larger than that of a proton.

The nuclei of most atoms consist of protons and neutrons, which are therefore collectively referred to as nucleons. The number of protons in a nucleus is the atomic number and defines the type of element the atom forms. The number of neutrons determines the isotope of an element. For example, the carbon-12 isotope has 6 protons and 6 neutrons, while the carbon-14 isotope has 6 protons and 8 neutrons.

Contents

Neutron stability and beta decay

Outside the nucleus, free neutrons are unstable and have a mean lifetime of 885.7±0.8 s (about 15 minutes), decaying by emission of a negative electron and antineutrino to become a proton:[3]

n0 ? p+ + e- + ?e

This decay mode, known as beta decay, can also transform the character of neutrons within unstable nuclei.

Bound inside a nucleus, protons can also transform via beta decay into neutrons. In this case, the transformation may occur by emission of a positron (antielectron) and neutrino (instead of an antineutrino):

p+ ? n0 + e+ + ?e

The transformation of a proton to a neutron inside of a nucleus is also possible through electron capture:

p+ + e- ? n0 + ?e

Positron capture by neutrons in nuclei that contain an excess of neutrons is also possible, but is hindered because positrons are repelled by the nucleus, and quickly annihilate when they encounter negative electrons.

When bound inside of a nucleus, the instability of a single neutron to beta decay is balanced against the instability that would be acquired by the nucleus as a whole if an additional proton were to participate in repulsive interactions with the other protons that are already present in the nucleus. As such, although free neutrons are unstable, bound neutrons are not necessarily so. The same reasoning explains why protons, which are stable in empty space, may transform into neutrons when bound inside of a nucleus.

Beta decay and electron capture are types of radioactive decay and are both governed by the weak interaction.

Detection

Main article: neutron detection

The common means of detecting a charged particle by looking for a track of ionization (such as in a cloud chamber) does not work for neutrons directly. Neutrons that elastically scatter off atoms can create an ionization track that is detectable, but the experiments are not as simple to carry out; other means for detecting neutrons, consisting of allowing them to interact with atomic nuclei, are more commonly used.

A common method for detecting neutrons involves converting the energy released from such reactions into electrical signals. The nuclides 3He, 6Li, 10B, 233U, 235U, 237Np and 239Pu are useful for this purpose. A good discussion on neutron detection is found in chapter 14 of the book Radiation Detection and Measurement by Glenn F. Knoll (John Wiley & Sons, 1979).

Uses

The neutron plays an important role in many nuclear reactions. For example, neutron capture often results in neutron activation, inducing radioactivity. In particular, knowledge of neutrons and their behavior has been important in the development of nuclear reactors and nuclear weapons. The fissioning of elements like uranium-235 and plutonium-239 is caused by their absorption of neutrons.

Cold, thermal and hot neutron radiation is commonly employed in neutron scattering facilities, where the radiation is used in a similar way one uses X-rays for the analysis of condensed matter. Neutrons are complementary to the latter in terms of atomic contrasts by different scattering cross sections; sensitivity to magnetism; energy range for inelastic neutron spectroscopy; and deep penetration into matter.

The development of "neutron lenses" based on total internal reflection within hollow glass capillary tubes or by reflection from dimpled aluminum plates has driven ongoing research into neutron microscopy and neutron/gamma ray tomography.[4][5][6]

One use of neutron emitters is the detection of light nuclei, particularly the hydrogen found in water molecules. When a fast neutron collides with a light nucleus, it loses a large fraction of its energy. By measuring the rate at which slow neutrons return to the probe after reflecting off of hydrogen nuclei, a neutron probe may determine the water content in soil.

Sources

Because free neutrons are unstable, they can be obtained only from nuclear disintegrations, nuclear reactions, and high-energy reactions (such as in cosmic radiation showers or accelerator collisions). Free neutron beams are obtained from neutron sources by neutron transport. For access to intense neutron sources, researchers must go to specialist facilities, such as the ISIS facility in the UK, which is currently the world's most intense pulsed neutron and muon source.[citation needed]

Neutrons' lack of total electric charge prevents engineers or experimentalists from being able to steer or accelerate them. Charged particles can be accelerated, decelerated, or deflected by electric or magnetic fields. However, these methods have no effect on neutrons except for a small effect of a magnetic field because of the neutron's magnetic moment.

Discovery

In 1930 Walther Bothe and H. Becker in Germany found that if the very energetic alpha particles emitted from polonium fell on certain light elements, specifically beryllium, boron, or lithium, an unusually penetrating radiation was produced. At first this radiation was thought to be gamma radiation, although it was more penetrating than any gamma rays known, and the details of experimental results were very difficult to interpret on this basis. The next important contribution was reported in 1932 by Irène Joliot-Curie and Frédéric Joliot in Paris. They showed that if this unknown radiation fell on paraffin or any other hydrogen-containing compound it ejected protons of very high energy. This was not in itself inconsistent with the assumed gamma ray nature of the new radiation, but detailed quantitative analysis of the data became increasingly difficult to reconcile with such a hypothesis. Finally, in 1932 the physicist James Chadwick in England performed a series of experiments showing that the gamma ray hypothesis was untenable. He suggested that in fact the new radiation consisted of uncharged particles of approximately the mass of the proton, and he performed a series of experiments verifying his suggestion.[7]

These uncharged particles were called neutrons, apparently from the Latin root for neutral and the Greek ending -on (by imitation of electron and proton).

Anti-neutron

Main article: anti-neutron

The antineutron is the antiparticle of the neutron. It was discovered by Bruce Cork in the year 1956, a year after the antiproton was discovered.

CPT-symmetry puts strong constraints on the relative properties of particles and antiparticles and, therefore, is open to stringent tests. The fractional difference in the masses of the neutron and antineutron is 9±5×10-5. Since the difference is only about 2 standard deviations away from zero, this does not give any convincing evidence of CPT-violation.[2]

Current developments

Electric dipole moment

Main article: Neutron electric dipole moment

The Standard Model of particle physics predicts a tiny separation of positive and negative charge within the neutron leading to a permanent electric dipole moment. The predicted value is, however, well below the current sensitivity of experiments. From several unsolved puzzles in particle physics, it is clear that the Standard Model is not the final and full description of all particles and their interactions. New theories going beyond the Standard Model generally lead to much larger predictions for the electric dipole moment of the neutron. Currently, there are at least four experiments trying to measure for the first time a finite neutron electric dipole moment.

Tetraneutrons

Main article: tetraneutron

The existence of stable clusters of four neutrons, or tetraneutrons, has been hypothesised by a team led by Francisco-Miguel Marqués at the CNRS Laboratory for Nuclear Physics based on observations of the disintegration of beryllium-14 nuclei. This is particularly interesting because current theory suggests that these clusters should not be stable.

Protection

Exposure to free neutrons can be hazardous, since the interaction of neutrons with molecules in the body can cause disruption to molecules and atoms, and can also cause reactions which give rise to other forms of radiation (such as protons). The normal precautions of radiation protection apply: avoid exposure, stay as far from the source as possible, and keep exposure time to a minimum. Some particular thought must be given to how to protect from neutron exposure, however. For other types of radiation, e.g. alpha particles, beta particles, or gamma rays, material of a high atomic number and with high density make for good shielding; frequently lead is used. However, this approach will not work with neutrons, since the absorption of neutrons does not increase straightforwardly with atomic number, as it does with alpha, beta, and gamma radiation. Instead one needs to look at the particular interactions neutrons have with matter (see the section on detection above). For example, hydrogen rich materials are often used to shield against neutrons, since ordinary hydrogen both scatters and slows neutrons. This often means that simple concrete blocks or even paraffin-loaded plastic blocks afford better protection from neutrons than do far more dense materials. After slowing, neutrons may then be absorbed with an isotope which has high affinity for slow neutrons without causing secondary capture-radiation, such as lithium-6.

Hydrogen-rich ordinary water effects neutron absorption in nuclear fission reactors: usually neutrons are so strongly absorbed by normal water that fuel-enrichement with fissionable isotope, is required. The deuterium in heavy water has a very much lower absorption affinity for neutrons than does protium (normal light hydrogen). Deuterium is therefore used in CANDU-type reactors, in order to slow ("moderate") neutron velocity, so that they are more effective at causing nuclear fission, without capturing them.

See also

Neutron capture nucleosynthesis

Fields concerning neutrons

.

Types of neutrons

.

Objects containing neutrons

  • The nuclei of atoms with the exception of protium, the most common isotope of hydrogen
    (and as a result, all ordinary matter with the exception of hydrogen)

Neutron sources

Processes involving neutrons

References

  1. ^ 1935 Nobel Prize in Physics
  2. ^ a b Particle Data Group's Review of Particle Physics 2006
  3. ^ Particle Data Group Summary Data Table on Baryons
  4. ^ Kumakhov, M. A.; Sharov, V. A. (1992). "A neutron lens". Nature 357: 390–391. doi:10.1038/357390a0. 
  5. ^ Physorg.com, "New Way of 'Seeing': A 'Neutron Microscope'"
  6. ^ NASA.gov: "NASA Develops a Nugget to Search for Life in Space"
  7. ^ Chadwick, James (1932). "Possible Existence of a Neutron". Nature 129: 312. doi:10.1038/129312a0. 
v  d  e
Particles in physics
Elementary particles
Fermions:  Quarks: u · d · c · s · t · bLeptons: e- · e+ · µ- · µ+ · t- · t+ · ?e · ?µ · ?t · ?e · ?µ · ?t
Bosons:  Gauge bosons: ? · g · W± · Z 
Other:  Ghosts
Composite particles
Hadrons:  Baryons/Hyperons/Nucleons: p+ · n0 · ? · ? · S · ? · OMesons/Quarkonia: p · K · ? · J/? · ?
Other:  Atomic nucleiAtomsExotic atoms: Positronium · Muonium · OniaMolecules
Hypothetical elementary particles
Hypothetical composite particles
Quasiparticles
Lists



Index Of Related Pages



All pages | Previous page (Neustadt (Hessen)) | Next page (Nevada (1997 film))
Neutron
Neutron, thermal
Neutron-degenerate matter
Neutron-induced swelling
Neutron-star oscillation
Neutron-star oscillations
Neutron (DC Comics)
Neutron (Imperial Guard)
Neutron (Linus)
Neutron (Marvel Comics)
Neutron (comic book)
Neutron (comics)
Neutron (disambiguation)Neutron (game)
Neutron Absorbtion
Neutron Absorption
Neutron Activation Analysis
Neutron Bomb
Neutron Capture
Neutron Dance
Neutron Dance (D:TNG episode)
Neutron Dance (song)
Neutron Detection
Neutron Jack
Neutron Jammer
Neutron Jammer Canceller
Neutron Jammer canceller
Neutron Moderator
Neutron Probe
Neutron Reflectometry
Neutron Science LaboratoryNeutron Solstice
Neutron Stampeder
Neutron Star
Neutron Star (story)Neutron Tide
Neutron absorber
Neutron absorbtion
Neutron absorption
Neutron activationNeutron activation analysisNeutron backscattering
Neutron bombNeutron capture
Neutron chain reaction
Neutron cross-section
Neutron cross section
Neutron crystallography
Neutron decay
Neutron degeneracy pressure
Neutron depth profiling
Neutron detection
Neutron detector
Neutron diffraction
Neutron drip lineNeutron economy
Neutron edm
Neutron electric dipole momentNeutron emission
Neutron energies
Neutron energy
Neutron fluence
Neutron flux
Neutron generator
Neutron halo
Neutron howitzer
Neutron interferometer
Neutron interferometry
Neutron magnetic moment
Neutron mass
Neutron matter
Neutron moderation
Neutron moderator
Neutron moderators
Neutron multiplication factor
Neutron number
Neutron poison
Neutron poisoning
Neutron probeNeutron radiationNeutron reflector
Neutron scannerNeutron scatteringNeutron source
Neutron spectrum
Neutron spin echoNeutron star
Neutron star kicks
Neutron star oscillation
Neutron star spin-up
Neutron stars
Neutron stars in fictionNeutron supermirror
Neutron temperatureNeutron time-of-flight scatteringNeutron transport
Neutron triple-axis scattering
Neutron triple-axis spectrometry
Neutron triple-axis spectroscopy
Neutronic poison
Neutronica
Neutronics
Neutronium
Neutrons
Neutropaenia
Neutropenia
Neutropenic
Neutropenic fever
Neutropenic sepsis
Neutrophil
Neutrophil activating peptide-2
Neutrophil collagenase
Neutrophil cytosolic factor 4Neutrophil elastase
Neutrophil extracellular trapsNeutrophil granulocyte
Neutrophil granulocytes
Neutrophil leucocytosis
Neutrophil leukocytosis
Neutrophil respiratory burst
NeutrophileNeutrophilia
Neutrophilic
Neutrophilic myelocyte
Neutrophill
Neutrophils
Neutrophyl
Neutrophyle
Neutropils
Neutrosophic logic
Neutrosophy
Neutrospec
Neutsky
Neutstadl
Neutz-Lettewitz
Neutzsky
Neutzsky-Wulff
Neutzsky-wulff
Neuva Germania
Neuva Granada
Neuva ring
Neuve
Neuve-Chapelle
Neuve-Chappelle
Neuve-MaisonNeuve-Église
Neuve Chapelle
Neuvecelle
Neuvelle-les-Cromary
Neuvelle-les-la-Charite
Neuvelle-lès-CromaryNeuvelle-lès-VoiseyNeuvelle-lès-la-Charité
Neuves-Maisons
Neuveville
Neuveville, La
NeuvicNeuvic, CorrèzeNeuvic, Dordogne
Neuvic-Entier
Neuvic-Sur-L'Isle
Neuvicq
Neuvicq-le-ChâteauNeuvillalaisNeuville
Neuville, CorrèzeNeuville, Puy-de-DômeNeuville, Quebec
Neuville-BoscNeuville-BourjonvalNeuville-Coppegueule
Neuville-DayNeuville-FerrièresNeuville-Saint-Amand
Neuville-Saint-RémyNeuville-Saint-Vaast
Neuville-St.-Vaast
Neuville-St Vaast
Neuville-St Vaast German war cemeteryNeuville-Vitasse
Neuville-au-BoisNeuville-au-CornetNeuville-au-Plain
Neuville-aux-BoisNeuville-de-PoitouNeuville-en-Avesnois
Neuville-en-BeaumontNeuville-en-FerrainNeuville-en-Verdunois
Neuville-les-Dames
Neuville-les-Loeuilly
Neuville-lez-Beaulieu
Neuville-lès-DecizeNeuville-lès-Loeuilly
Neuville-lès-Lœuilly
Neuville-lès-ThisNeuville-lès-VaucouleursNeuville-près-Sées
Neuville-sous-MontreuilNeuville-sur-AiletteNeuville-sur-Ain
Neuville-sur-AuthouNeuville-sur-BrenneNeuville-sur-Escaut
Neuville-sur-MargivalNeuville-sur-OiseNeuville-sur-Ornain
Neuville-sur-Saone: Debarquement du congres des photographes a Lyon
Neuville-sur-SartheNeuville-sur-Saône
Neuville-sur-Saône: Débarquement du congrès des photographes à Lyon
Neuville-sur-SeineNeuville-sur-Touques
Neuville-sur-Vannes
Neuville de Poitou
Neuville de poitou
Neuviller-la-RocheNeuviller-lès-BadonvillerNeuviller-sur-Moselle
Neuvillers-sur-FaveNeuvilletteNeuvillette, Aisne
Neuvillette, SommeNeuvillette-en-CharnieNeuvilley
NeuvillyNeuvilly-en-ArgonneNeuvireuil
Neuvizy
Neuvou riche
Neuvusia alabamensis
NeuvyNeuvy, AllierNeuvy, Loir-et-Cher
Neuvy, MarneNeuvy-BouinNeuvy-Deux-Clochers
Neuvy-GrandchampNeuvy-Pailloux
Neuvy-Saint-Sepulchre
Neuvy-Saint-Sepulcre
Neuvy-Saint-Sépulchre
Neuvy-Saint-Sépulcre
Neuvy-SautourNeuvy-au-HoulmeNeuvy-en-Beauce
Neuvy-en-ChampagneNeuvy-en-DunoisNeuvy-en-Mauges
Neuvy-en-SulliasNeuvy-le-BarroisNeuvy-le-Roi
Neuvy-sur-BarangeonNeuvy-sur-LoireNeuvéglise
Neuwaldegg Palace
Neuwaukum River
Neuwedell
NeuweilerNeuwerkNeuwied
Neuwied's lancehead
Neuwied, Germany
Neuwied (district)
Neuwied district
NeuwiediaNeuwilen
NeuwillerNeuwiller-lès-SaverneNeuwirth
Neuwittenbek
Neuymin
Neuza Silva
Neuzeit SNeuzelle
Neuzelle, Germany
Neuzelle (Amt)Neuzeller Kloster Brewery
Neuzen
NeuzinaNeuötting
Neuötting displaced persons camp
Nev ChandlerNev Fountain
Nev the Bear
Nev the bear
Neva
Neva, WI
Neva, Wisconsin
Neva (Russian warship)
Neva (disambiguation)
Neva (ship)Neva AbelsonNeva Again
Neva Battle
Neva BoydNeva Dell Hunter
Neva DinovaNeva Dinova (album)Neva Eva
Neva GerberNeva Get EnufNeva Get Enuff (album)
Neva GilbertNeva Have 2 WorryNeva Jane Langley
Neva Krysteva
Neva Martin Abelson
Neva Masquerade
Neva PattersonNeva PilgrimNeva River
Neva Shoal
Neva Shoals
Neva Small
Neva SurrendaNeva Yacht Club
Neva river
NevadaNevada's 1st congressional districtNevada's 2nd congressional district
Nevada's 2nd congressional district election, 2006Nevada's 3rd congressional district
Nevada's At-Large Congressional District
Nevada's At-large congressional districtNevada's congressional districts
Nevada's congressional elections, 2006
Nevada, IA
Nevada, IndianaNevada, Iowa
Nevada, MO
Nevada, Missoura
Nevada, Missouri
Nevada, OH
Nevada, Ohio
Nevada, TX
Nevada, Texas
Nevada, United States
Nevada-California-Oregon Railroad
Nevada-California-Oregon Railway
Nevada-Tan
Nevada-chan
Nevada-class battleship
Nevada-tan
Nevada (1944 film)

Previous page (Neustadt (Hessen)) | Next page (Nevada (1997 film))


BUILD YOUR WEB SITE WITH www.DomainsUAE.com