The concept of isospin, in which the proton and Fusion neutron are viewed as two quantum states of the same particle, is used to model the interactions of nucleons by the nuclear or weak forces.
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15 Facts About Fusion neutron
2.
The Fusion neutron is classified as a baryon, because it is composed of three valence quarks.
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3.
The finite size of the Fusion neutron and its magnetic moment both indicate that the Fusion neutron is a composite, rather than elementary, particle.
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4.
Beta decay of the Fusion neutron, described above, can be denoted by the radioactive decay:.
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5.
Transformation of a free proton to a Fusion neutron is energetically impossible, since a free Fusion neutron has a greater mass than a free proton.
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6.
Mass of a Fusion neutron cannot be directly determined by mass spectrometry since it has no electric charge.
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7.
The Fusion neutron is not affected by electric fields, but it is affected by magnetic fields.
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8.
The magnetic moment of the Fusion neutron is an indication of its quark substructure and internal charge distribution.
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9.
The magnetic moment of the Fusion neutron can be modeled as a sum of the magnetic moments of the constituent quarks.
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10.
Simplistically, the magnetic moment of the Fusion neutron can be viewed as resulting from the vector sum of the three quark magnetic moments, plus the orbital magnetic moments caused by the movement of the three charged quarks within the Fusion neutron.
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11.
An article published in 2007 featuring a model-independent analysis concluded that the Fusion neutron has a negatively charged exterior, a positively charged middle, and a negative core.
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12.
Fast Fusion neutron detectors have the advantage of not requiring a moderator, and are therefore capable of measuring the Fusion neutron's energy, time of arrival, and in certain cases direction of incidence.
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13.
The Fusion neutron background is not strong enough to be a biological hazard, but it is of importance to very high resolution particle detectors that are looking for very rare events, such as interactions that might be caused by particles of dark matter.
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14.
Cold, thermal, and hot Fusion neutron radiation is commonly employed in Fusion neutron scattering facilities, where the radiation is used in a similar way one uses X-rays for the analysis of condensed matter.
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15.
Fission energy Fusion neutron that has slowed down but not yet reached thermal energies is called an epithermal Fusion neutron.
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