We have finally reached the stage where we can explain the Higgs mechanism.
In part 3 of this series, I said that the complete set of elementary particles consisted of six quarks, six leptons, six ‘gauge bosons’ (particles that are the agents of the four fundamental forces), and the Higgs particle. In part 7, I said that there were patterns among the 18 non-Higgs particles, apart from some anomalies. (For previous posts in this series, click on the Higgs folder just below the blog post title.)
It was noticed that the observed patterns among the quarks and leptons would be even more striking if they did not have mass. In order to explain those patterns (or ‘symmetries’), physicists invented a class of theories called ‘gauge theories’. These gauge theories predicted the existence of the force particles (which is why they are called ‘gauge bosons’) and that was satisfying. The catch was that if the symmetries were exact, then the quarks, leptons, and gauge bosons should all be massless, which they are clearly not, except for the graviton, gluon, and photon. So we say that these symmetries are ‘broken’ (i.e., not exact) and physicists looked for a way in which broken symmetries lead to masses.
When it comes to particles that are the source of forces, the rule of thumb is that the smaller the mass of the force particle, the longer the range of the force, with the forces mediated by massless particles being of infinite range. This is true for gravity and electromagnetism for which the corresponding graviton and photon are massless and the forces have infinite range. But while the gluons are also massless, the strong nuclear force acts only over a very short range. This can be explained by the fact that the strong nuclear forces are very strong and prevent the quarks and gluons from becoming free, resulting in them being permanently confined inside composite particles such as the proton and neutron.
The main anomaly was with the weak nuclear force. While the gravity, electromagnetic, and strong nuclear forces each had one force particle associated with them (graviton, photon, and gluon respectively), the remaining weak nuclear force had three particles W+, W–, and Z. While the number of weak interaction particles was predicted by the gauge theories, the weak nuclear force is, as you might expect from the name, extremely weak so the particles associated with those forces cannot be confined within other particles. Hence if those force particles were also massless like the other gauge particles, the weak nuclear force would be of infinite range like gravity and electromagnetism. But we know that the weak nuclear force, like the strong nuclear force, is of extremely short range. The reason is that these particles have mass, and large ones at that. They have been measured to be W+= W–=80.4 GeV; and Z=91.2 GeV, or roughly 100 times the mass of a proton.
How is it that just these three gauge force particles acquired masses? The answer lies with the Higgs mechanism.
In part 10, I described how the average value of the Higgs field was zero just after the Big Bang when the universe was in an extremely hot state but as it cooled slightly, we had the phenomenon of a ‘phase transition’ due to ‘spontaneous symmetry breaking’, in which the average value of the Higgs field in the vacuum abruptly acquired a non-zero value. This happened very quickly after the Big Bang, after about one-trillionth of a second (10-12s).
So what was the state of play before that phase transition occurred? Before that, the 18 quarks, leptons, and gauge bosons were all massless. The bad news is that at that time, there were actually four Higgs fields present, with correspondingly four Higgs particles (and you thought one was bad enough!). All the Higgs fields had an average value of zero in the vacuum, just like the other fields.
But when the universe cooled past the phase transition point, the so-called Higgs mechanism kicked in, ‘mixing up’ (in a complicated mathematical way) the four original Higgs fields with the four fields that would later become the fields of the three weak interaction particles and the photon. The net result of this mixing process is that three of the four original Higgs fields got ‘absorbed’ (in some sense) by the other four fields, thus disappearing from the picture entirely for the rest of the universe’s life, leaving the one remaining Higgs field taking on the non-zero value it has now.
What happened to those three Higgs fields that lasted for such a short time? It turns out that the particles corresponding to those fields nobly sacrificed their lives in order to give masses to three particles, the W+, W–, and Z, so that those particles got the masses that they have now. So in this process of mixing, the number of fields were reduced from eight (four Higgs, four electroweak) to five (one Higgs, three weak, one electromagnetic), with the particles corresponding to the three weak interaction fields acquiring masses in the process. It is this sequence of events that gave rise to the masses of the W+, W–, and Z that is referred to as the Higgs mechanism.
So to summarize, as a result of spontaneous symmetry breaking via the Higgs mechanism, we end up after the electroweak phase transition with three massive particles that are excited states of the three weak interaction fields and that give rise to the short-range weak nuclear force, a massless photon that is an excited state of the long-range electromagnetic field that gives rise to the electromagnetic force, and the Higgs particle that does not give rise to any force but is an excited state of the Higgs field. Of all the fields, it is only the Higgs field that has a non-zero average value in the vacuum.
Next: How quarks and leptons acquire masses
Not sure if you mentioned this before, but the April issue of Scientific American has an interesting article about neutrinos. One of the things they look at is why neutrinos have such tiny masses. As an interested layman (which is the target audience of SA) I found it to be an interesting read.
Thanks for the tip abut the SA article which I will look up. The neutrino masses are a bit of a puzzle. There is a split between those who think that all the quarks and leptons get their masses in the same way and those who think that there is something else at work in generating the masses of the electrically neutral leptons (i.e., the three kinds of neutrinos).
I’d only add that, although the number of particle fields has been reduced, the number of particle states is the same. A massless gauge boson (e.g. a photon) has only two polarization states, both transverse. A massive gauge boson can have a longitudinal polarization as well, so in a sense, the three “disappeared” Higgs particles become the longitudinal components of the three weak bosons.
This article explains the polarization states of the gauge bosons.
Yes, that’s right. I have avoided bringing in spin and polarization states as it would make it a little more complicated while not necessarily adding to the main storyline.
I think it adds to it as it explains at least what is meant by absorption of 3 of the original 4 Higgs fields.
Also you talked about symmetry breaking and the different states that particles could exist in (stick on a pivot attached to a table), isn’t polarization similar to this as there are only a certain number of degrees of freedom that a particle can spin?
Fair enough.
I need an explanation for this:
If these weak nuclear force particles and the 2 up quarks and 1 down quarks make up the proton how is the proton mass only 938 MeV? Is it because the mass of the proton is based on the average mass of its components, with the W+, W- and Z all being short lived, or is there some other explanation?
The weak vector bosons are not constituents of hadrons (which include the proton). Hadrons are composed of quarks (three for baryons, quark+antiquark for mesons). Most of the hadron mass comes from kinetic energy of the quarks and the strong force binding energy.
I think the mass of the proton or neutron will depend on the mass of the quarks and the energy of interaction of the gluons as explained in part 3:
The W+, W- and Z particles are bosons for the weak nuclear force so they don’t play a role in the mass of the proton or neutron. I am guessing they play a role in the total mass of the nucleus? Am I correct Dr. Singham?
You are right that the W+, W--, and Z do not play any role in the mass of a proton or neutron, but neither do they play a role in the mass of nuclei. The mass of nuclei is very close to, but slightly less than, the sum of the masses of the protons and neutrons that make up the nucleus. The roles that W+, W--, and Z play is as very short-lived intermediate states when a particle decays via the weak interaction.
Take for example, the decay of a neutron. It will initially decay into a proton and a W--, and then almost immediately the W-- will decay into an electron and an electron antineutrino. During the intermediate state there is a huge violation of energy conservation since the mass of the W-- is about 100 times the mass of the neutron and that is why the W-- lasts for such a very short time and hence why the weak force is of such short range.