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e + p n + v e ,

In this process, the proton emits a W + and is converted into a neutron (b). The W + then combines with the electron, forming a neutrino. Other electroweak interactions are considered in the exercises.

Figure a shows four arrows. One arrow, labeled n, points up and its tip meets the base of another arrow going up and left, labeled p. To the right of this is an arrow labeled e minus pointing up. Its base is connected to the base of another arrow going up and right. This is labeled v bar subscript e. The two junctions on the graph are connected by a wavy line labeled W minus. This points up and right. Figure b shows four arrows. One arrow, labeled p, points up  and right. Its tip meets the base of another arrow going up and left, labeled n. To the right of this is an arrow labeled e minus pointing up and left. Its tip meets the base of another arrow going up and right. This is labeled v subscript e. The two junctions on the graph are connected by a wavy line labeled W plus. This points up and right.
Feynman diagram of particles interacting through the exchange of a W boson: (a) beta decay; (b) conversion of a proton into a neutron.

The range of the weak nuclear force can be estimated with an argument similar to the one before. Assuming the uncertainty on the energy is comparable to the energy of the exchange particle by ( E m c 2 ) , we have

Δ t h m c 2 .

The maximum distance d that the exchange particle can travel (assuming it moves at a speed close to c ) is therefore

d c Δ t = h m c .

For one of the charged vector bosons with m c 2 80 GeV = 1.28 × 10 −8 J , we obtain m c = 4.27 × 10 −17 J · s / m . Hence, the range of the force mediated by this boson is

d 1.05 × 10 −34 J · s 4.27 × 10 −17 J · s/m 2 × 10 −18 m .

Strong nuclear force

Strong nuclear interactions describe interactions between quarks. Details of these interactions are described by QCD. According to this theory, quarks bind together by sending and receiving gluons. Just as quarks carry electric charge [either ( + 2 / 3 ) e or ( −1 / 3 ) e ] that determines the strength of electromagnetic interactions between the quarks, quarks also carry “color charge” (either red, blue, or green) that determines the strength of strong nuclear interactions. As discussed before, quarks bind together in groups in color neutral (or “white”) combinations, such as red-blue-green and red-antired.

Interestingly, the gluons themselves carry color charge. Eight known gluons exist: six that carry a color and anticolor, and two that are color neutral ( [link] (a)). To illustrate the interaction between quarks through the exchange of charged gluons, consider the Feynman diagram in part (b). As time increases, a red down quark moves right and a green strange quark moves left. (These appear at the lower edge of the graph.) The up quark exchanges a red-antigreen gluon with the strange quark. (Anticolors are shown as secondary colors. For example, antired is represented by cyan because cyan mixes with red to form white light.) According to QCD, all interactions in this process—identified with the vertices—must be color neutral. Therefore, the down quark transforms from red to green, and the strange quark transforms from green to red.

Figure a shows 8 circles in a row. The last two circles are white. The top and bottom halves of each of the first six circles are different in color. The top halves are labeled color and the bottom halves are labeled anticolor. The top and bottom halves of each circle from left to right are as follows: first: red labeled R and magenta labeled G bar, second: green labeled G and cyan labeled R bar, third: blue labeled B and cyan labeled R bar, fourth: red labeled R and yellow labeled B bar, fifth: green labeled G and yellow labeled B bar, sixth: blue labeled B and magenta labeled G bar. Figure b is a graph of t versus x. An arrow going up and right is labeled R. Its tip meets the base of arrow G, which points up and left. The junction is labeled from R to R plus R G bar. To the right of these is an arrow G pointing up and left. Its tip meets the base of arrow R. The junction is labeled from RG bar plus G to R. The two junctions are connected by an arrow pointing right. Along the arrow is a circle labeled RG bar.
(a) Eight types of gluons carry the strong nuclear force. The white gluons are mixtures of color-anticolor pairs. (b) An interaction between two quarks through the exchange of a gluon.

As suggested by this example, the interaction between quarks in an atomic nucleus can be very complicated. [link] shows the interaction between a proton and neutron. Notice that the proton converts into a neutron and the neutron converts into a proton during the interaction. The presence of quark-antiquark pairs in the exchange suggest that bonding between nucleons can be modeled as an exchange of pions.

At the top left of the figure is a circle labeled neutron. Within it are three smaller circles labeled d, u, d. At the top right corner is a circle labeled proton. Within it are three circles labeled u, d, u. At the bottom right is a circle labeled neutron. Within it are three circles labeled d, d, u. At the bottom left is a circle labeled proton. Within it are three circles labeled d, u, u. Lines from d, and u in the bottom left proton connect to the d and u in the top left neutron. Lines from the d and u in the bottom right neutron connect to those in the top right proton. A line from the u in the bottom left proton connects to the u in the top right proton. In the middle of this connecting line, the u pairs with another circle, which is labeled d bar. This pair is labeled pi plus. Pointing to the circle labeled d bar from the left is an arrow, whose base is labeled d plus d bar created. A line from the base of the arrow connects to the d in the top left neutron. To the right of the circle labeled d bar is a line, the endpoint of which is labeled d plus d bar annihilate. A line connects the d in the bottom right neutron to it. Wavy lines are shown between all connecting lines.
A Feynman diagram that describes a strong nuclear interaction between a proton and a neutron.

In practice, QCD predictions are difficult to produce. This difficulty arises from the inherent strength of the force and the inability to neglect terms in the equations. Thus, QCD calculations are often performed with the aid of supercomputers. The existence of gluons is supported by electron-nucleon scattering experiments. The estimated quark momenta implied by these scattering events are much smaller than we would expect without gluons because the gluons carry away some of the momentum of each collision.

Practice Key Terms 5

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Source:  OpenStax, University physics volume 3. OpenStax CNX. Nov 04, 2016 Download for free at http://cnx.org/content/col12067/1.4
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