I disagree a bit with the view expressed above that the Higgs boson is nonsense because it isn’t falsifiable science. It’s a vital connection between quantum gravity and the standard model, and although the latter isn’t the final model of particle physics:

* some quantized Higgs field is needed that can supply charges with various masses for generation, e.g. explaining differences between electrons, muons, and tauons

* the Higgs field creates massive weak gauge bosons that somehow can only interact with left-handed charges

The handedness of the weak isospin charge is the most amazing thing about particle physics. Does the mechanism which gives mass to weak gauge bosons, give them the property of simply not interacting with right-handed particles at all? Or is it a case that weak gauge bosons only exist with one handedness in the first place?

Most of the papers on the subject are focussed on the role of the Higgs field not to explaining these problems, but to

[...snip... Nigel kindly will provide the continuation of his thoughts on his blog.... -cvj]

(-:

-cvj

“Judging the basis of brief blog statements without having considered their scientific backing (which I can assure you, you have not) is unscientific behaviour.”

That may well be, but it is just plain irrelevant here, since I made no judgment about your work. I know for a fact that you (and in fact nobody else) do not know whether there is a Higgs or not since nobody has done the experiment. Therefore I am free to question the certainty in your statement made here and in several other places that there is no Higgs. I have made no judgments about your work, which I have not seen, but simply your assertion that you know the outcome of the experiments in advance of their having been done.

To save you scrolling up, I repeat your comment here:

“Do you think people will call it the ‘God Particle’ when they find out it doesn’t exist?”

Even though you had a “when” and not an “if”, and despite the fact that you’ve been making similar remarks in the past, I actually originally answered your comment with the benefit of the doubt and some of the spirit of possible humour (to copy you: Gee, do I have to point that out?), and you chose to interpret otherwise, so your parenthetical “Gee…” nonsense is just plain silly.

“In general, a good scientist reserves judgement about ALL things on which he/she is uninformed.”

Excellent advice that I urge you (and all of us) to follow.

-cvj

The usual technique in physics is to glom on to the first reasonable explanation for known experiments, and then to hang on to that explanation come hell or high water as long as is logically possible. It turns out that “as long as is logically possible” amounts to the same things as “till death do us part”. Physics moves forward as the old generation, and their old ideas, die off.

And the ideas extend to things that have never been observed in experiment. Along with the Higgs, there’s also gravitons. And aether.

Cheers,

-cvj

Hi, Clifford. As it happens, I believe it is the professional duty of a good theorist to have an educated opinion about the outcome of experiments BEFORE they are done. That’s how science works. And yes, no doubt I will keep posting such comments until either (a) I am proved incorrect by the discovery of a Higgs particle, or (b) the development of the theory forces me to change my mind.

I think the quickest thing to do is to simply google (as I did) for “Higgs Mechanism”. You find umpteen perfectly good explanations of the Higgs mechanism for the level you requested. Theres no need to type it all out again. The best thing to focus on for reliability are explanation pages that are written by people at labs like CERN, Fermilab, etc. I also found one of the more popular diagrammatic motivations (popular person walking through a crowded room interacting with everyone) on a PPARC website, the funding agency for UK particle physics. Read a few of those, I recommend.

The key way to think about it is that particles start out in our current models of particle physics as all massless. We did not choose that…. this is what works: Without mass, the model -and our universe- is much more symmetric than we see now. Masses spoil (or hide) that symmetry. So mass in the standard model is not a fundamental thing put in by hand, it arises from interaction. The interaction in question is with some other particle, called the Higgs (or at least some setup that mimics the effect of the Higgs), and the result is that we observe the effect of the interaction with the Higgs as mass, even when we do not see the Higgs directly itself. Remarkably, you can determine that a lot of the masses and interactions or the particles that we’ve already determined by experiments fit very tightly with the existence of a Higgs or (Higgs-like sector). It is not just some random thing we made up. Internal quantum mechanical consistency plus what we’ve already measured constrains what you can do a great deal.

So we know that there is some sector of physics that must be there to give the masses, etc, that we have already measured. Whether it is a simple Higgs particle or something cleverer remains to be determined by experiment, not declarations such as those made (in jest, I hope) by Kea above.

We (the particle physics community, as it were) won’t really localize Higgs particles in the way you’re thinking. What we will do in the collider experiments is explore (for example) new decay channels which will appear at the energies in question in the collisions. The varieties of signals we will see (once explored and enumerated) combined with the rules of quantum mechanics, will allow us to infer what sorts of particles must have appeared in the decays. We wlll be at high enough energies to probe directly the regime where the Higgs -or whatever Higgs-like interaction- must have been included in the decays. We will never see it directly, just its decay products via interaction with all the particles we know and love (and have well studied). We know how well the decay properties of everything that we already have identified, and so we should be able to pick out new objects by their patterns of decay by seeing how things have changed in the new regime of physics we are exploring.

Best,

-cvj

Cheers,

-cvj

It would be very interesting to find this odd particle. Many of us would appreciate a good middle-brow grounded explanation of why there needs to be a particle like the Higgs to provide “mass” (not just inertia, but equivalent energy too!) to other particles. I mean, why can’t mass just be “fundamental”? BTW if we can actually localize Higgs particles at all, then what happens if more are in the region of a given particle? Is it more massive then? How does the quantum field fluctuation issue affect particle masses: they vary a bit moment by moment? (I mean, over and above the energy-time uncertainty, which shouldn’t (?) affect the base rest mass-energy of particles with fixed masses, like electrons.)

It’s funny, since for comparison many physicists think “time” isn’t really fundamental in itself. (Well, “flowing time” can’t be defined in strictly logical terms, only “spaces” with various contents can be. Not many notice that “matter” can’t be logically defined either, as substantive clothing over and above the structural content of model universes in the platonic mindscape.) Thanks for any illumination provided.