The Higgs mechanism and the Beginning of the Universe

In summary: False vacuum expansion would be so rapid that any magnetic monopoles would be swept beyond the particle horizon and we would not observe any. I am not saying that is the way it happened...Guth is not so specific and does not mention the Higgs field nor scalar field nor any field at all...but that is the way I would have done it...I think.In summary, the Higgs mechanism is a component of the Standard Model of Particle Physics that assigns mass to matter made of Fermions and Bosons. This mechanism is thought to have first switched on in the early universe during a phase-change
  • #1
Paulibus
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The Higgs mechanism and the Beginning of the Universe

Now that the excitement about the discovery of the Higgs particle has made the Higgs
mechanism justly famous, could someone please clarify for me the implications of
incorporating this component of the Standard Model of Particle Physics into the Standard
Model of Cosmology?

As (hopefully) I understand it, the Higgs mechanism is thought to be instrumental in assigning mass to stuff, firstly to matter made of Fermions, which do have a rest-mass (mass measured at rest relative to an inertial observer) and secondly to Bosons, that don’t have a rest mass and are therefore, according to special relativity that rules locally, always traveling at light-speed, c. But Bosons do carry energy and so acquire relativistic mass, which has inertia, gravitates and qua mass, must also be assigned by the Higgs mechanism. Is this correct?

I also understand that the Higgs mechanism is thought to have first switched on suddenly, as it were, in the cooling and expanding very-early-indeed universe, when a phase-change was caused by the spontaneous symmetry breaking of a specific potential. Before this instant, in what I’d like to call the dawn universe, mass had not yet emerged into existence as something that could be measured, even in principle by imaginary inertial observers. Indeed, in such a dawn universe the presumably entirely inertia- and mass-less (but today massive) particles/waves that comprise the material universe, namely Fermions and Bosons, must then have all been (locally) traveling at c. It seems to me that the time dilation of special relativity tells us that time itself, as we know it, must then have been on hold, as it were, and that it could not then have existed as a locally measurable parameter for local physics, even in principle.

If all this is not mistaken perhaps Eternal Dawn would be a more appropriate description of
the Beginning than Big Bang.
 
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  • #2


Things are speculative at this point. I will quote an excerpt from a post I wrote yesterday in another thread:
==quote==
Higgs inflation in Loop cosmology is the topic of a new paper that just appeared and impressed me as potentially important. It's by Tom Pawlowski, a postdoc at Warsaw, and two PhD students there: Andrea Dapor and Michal Artymowski.
It puts inflation in a new light for me. So I expect some rapid development in this area:
http://arxiv.org/abs/1207.4353
Inflation from non-minimally coupled scalar field in loop quantum cosmology
Michal Artymowski, Andrea Dapor, Tomasz Pawlowski
(Submitted on 18 Jul 2012)
The FRW model with non-minimally coupled massive scalar field has been investigated in LQC framework. Considered form of the potential and coupling allows applications to Higgs driven inflation. The resulting dynamics qualitatively modifies the standard bounce paradigm in LQC in two ways: (i) the bounce point is no longer marked by critical matter energy density, (ii) the Planck scale physics features the "mexican hat" trajectory with two consecutive bounces and rapid expansion and recollapse between them. Furthermore, for physically viable coupling strength and initial data the subsequent inflation exceeds 60 e-foldings.
14 pages, 5 figures
Here are links to earlier papers by Bezrukov and Shaposhnikov
http://arxiv.org/abs/0710.3755 (209 cites)
The Standard Model Higgs boson as the inflaton
http://arxiv.org/abs/0904.1537 (78 cites)
Standard Model Higgs boson mass from inflation: two loop analysis
The latter was cited by ADP...
==endquote==
Loop cosmology is one approach to understanding the early universe that is being worked on a lot and may in future be tested by observations.
In this model, time extends back before the start of expansion. There is a collapsing phase that rebounds due to quantum effects ("big bounce").
There is a brief episode of superinflation caused by the bounce and then ordinary inflation might take over--possibly driven by the Higgs field. That is the possibility that these authors Artymowski Dapor Pawlowski (ADP) are studying. At the end they offer some ideas as to how the type of bounce and expansion they are talking about could be TESTED by looking for specific traces of it in the cosmic background radiation. This work is clearly preliminary and speculative. I expect to hear more about it in the coming months.
 
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  • #3


Paulibus:
It seems there are dozens of 'Higgs fields" to accompany dozens of particle characteristics. My limited understanding is that IF CERN has discovered a Higgs particle they don't know which 'one' [or ones] yet. Higgs fields get stuck in the Standard Model by hand...slick mathematical tools to create desired, observed characteristics. Like the rest of the Standard Model, lots of pieces but exactly why they fit is not so clear and there are still lots of pieces that have to be added ad hoc to match what we observe.

I happen to be reading Alan Guth's THE INFLATIONARY UNIVERSE at the moment and he describes what he did, how he got there, and the available information when he 'invented' the cosmological 'inflation', exponential expansion, that has become so popular. Guth and his main collaborator [Henry Tye] were working on the magnetic monopole problem...why we observe none. John Preskill beat them defining the problem mathematically with his paper and so Guth decided to work on a method to theoretically avoid magnetic monopoles. The issue was "why are so many magnetic monopoles predicted yet we observe none?"

What circumstances would be compatible with a hot big bang?... and avoid magnetic monopoles...fast symmetry breaking did not make magnetic monopoles to disappear...but some appropriate expansion would...hmmm...He knew about phase transitions and spontaneous symmetry breaking in 1979 and from Sidney Colemans 1977 paper THE FATE OF THE FALSE VACUUM'. [False meaning temporarily at an elevated vacuum energy density ] He knew from GR that such a false vacuum leads to gravitational repulsion. It seems he also rediscovered the de Sitter solution to EFE before later finding that Lemaitre had already done that in 1925...skunked again!...BUT all was not lost...he had all these pieces hanging around...[reminds me of all the pieces Einstein had when developing SR [ether?, fixed speed of light?, Lorentz contraction, Fitzgerald time dilation, etc...]

Anyway, a false Higgs vacuum, as a scalar field would give him the characteristic delay he needed to allow expansion to continue long enough to give him the expansion he sought to dissipate magnetic monoples from existence...gluing these pieces together, Volia! inflationary expansion was born! After realizing this and confirming with some calculations, THEN he realizes such extended rapid expansion also solves the flatness problem he had heard about a year before in a talk he attend given by Dicke...Apparently he had not known about THAT issue peviously but was smart enough to realize it 'fit' his expansionary ideas...but his model had not planned to incorporate that fantastic and necessary result...it was a 'freebe'.

I still find it amazing that nature fits some of our math.
 
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  • #4


Naty1 said:
Paulibus:
It seems there are dozens of 'Higgs fields" to accompany dozens of particle characteristics. My limited understanding is that IF CERN has discovered a Higgs particle they don't know which 'one' [or ones] yet. Higgs fields get stuck in the Standard Model by hand...slick mathematical tools to create desired, observed characteristics. Like the rest of the Standard Model, lots of pieces but exactly why they fit is not so clear and there are still lots of pieces that have to be added ad hoc to match what we observe. ...

The Standard Model of particle physics points to one Higgs which they call the "Standard Model Higgs". It looks to me as if they've found that one. A lot of people seem to think this is probably what the particle is, that they found. But details are being carefully checked, to make sure.

This is the simplest outcome, there ARE other possible Higgs or Higgs-like fields which if they had NOT found this one they could now be theorizing about and looking for.
Matt Strassler's blog "Of Particular Significance" has several tutorials about this.

But it's highly probable that the situation has begun to simplify. What LHC found probably is indeed the SM Higgs.

Guth was born February 1947, so he turned 65 a few months ago. How he happened on the inflation hypothesis around 1980 is an interesting human interest story!

My hunch is that we are entering a new phase of understanding the early universe --- inflation scenarios in particular. This 2007 paper could be a key one:
Bezrukov and Shaposhnikov
http://arxiv.org/abs/0710.3755 (209 cites)
The Standard Model Higgs boson as the inflaton

Back in 1980 Guth and Linde were talking about a dreamed up inflaton field and a lot features of the scenario were based on exotic made up stuff that nobody had ever seen. Now we have a possibility of modeling inflation with a particle we actually know about and have seen at CERN.

But notice that the Pawlowski paper gets a more general result. They explicitly say they're good with Loop bounce-followed-by-inflation for a wide range of scalar fields. If it is this 125 GeV Standard Model Higgs fine and dandy! But it would work with a bunch of other similar fields (non-minimally coupled massive scalar), if that one somehow drops out of the picture and LHC finds something else.

http://arxiv.org/abs/1207.4353
Inflation from non-minimally coupled scalar field in loop quantum cosmology
Michal Artymowski, Andrea Dapor, Tomasz Pawlowski
(Submitted on 18 Jul 2012)
The FRW model with non-minimally coupled massive scalar field has been investigated in LQC framework. Considered form of the potential and coupling allows applications to Higgs driven inflation. The resulting dynamics qualitatively modifies the standard bounce paradigm in LQC in two ways: (i) the bounce point is no longer marked by critical matter energy density, (ii) the Planck scale physics features the "mexican hat" trajectory with two consecutive bounces and rapid expansion and recollapse between them. Furthermore, for physically viable coupling strength and initial data the subsequent inflation exceeds 60 e-foldings.
14 pages, 5 figures
===quote from page 1 of ADP paper===
At this point it is worth noting that the type of the potential considered, while usually associated with the models of Higgs inflation, is not restricted just to this particular field. In fact, our studies can be easily (generalized and) applied to the analysis of the inflation driven by any non-minimally coupled scalar field with realistic values of ξ and λ.
==endquote==
 
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  • #5


Paulibus said:
But Bosons do carry energy and so acquire relativistic mass, which has inertia, gravitates and qua mass, must also be assigned by the Higgs mechanism. Is this correct?

No. There are bosons with mass (the W and Z particles). The Higgs mechanism was to allow you to have massive bosons. There's no real mystery in assigning mass to fermions, you just say that they have mass.

The problem is that you have bosons without mass (i.e. photons). Bosons with mass (the W and Z particle). You would *like* to get photons and W/Z particles into the same "beautiful" theory. In order to do that, if you assume that the Higgs field exists and interacts with W and Z particles but not photons, then you end up with a nice elegant theory.

Note, here that we are talking all about "rest masses". "Relativistic mass" is a way of explaining special relativity that turns out to cause more confusing than anything else. Since Higgs is a nice mechanism for giving W and Z particles mass, people sort of assume that the same mechanism would work for all particles, but that's not been established yet.

I also understand that the Higgs mechanism is thought to have first switched on suddenly, as it were, in the cooling and expanding very-early-indeed universe, when a phase-change was caused by the spontaneous symmetry breaking of a specific potential. Before this instant, in what I’d like to call the dawn universe, mass had not yet emerged into existence as something that could be measured, even in principle by imaginary inertial observers.

Don't know if this is true.

It seems to me that the time dilation of special relativity tells us that time itself, as we know it, must then have been on hold, as it were, and that it could not then have existed as a locally measurable parameter for local physics, even in principle.

Time is just a coordinate.

If all this is not mistaken perhaps Eternal Dawn would be a more appropriate description of
the Beginning than Big Bang.

Probably not. The big bang happens at energies, far, far higher than the Higgs particle. The thing about Higgs is that it happens at energies you can simulate on Earth (i.e. which is what we did). There are much higher energies.
 
  • #6


Naty1 said:
It seems there are dozens of 'Higgs fields" to accompany dozens of particle characteristics.

This is something that we have to figure out next. It's possible that there are lots of Higgs fields. Possible that there is just one.

that has become so popular. Guth and his main collaborator [Henry Tye] were working on the magnetic monopole problem...why we observe none. John Preskill beat them defining the problem mathematically with his paper and so Guth decided to work on a method to theoretically avoid magnetic monopoles. The issue was "why are so many magnetic monopoles predicted yet we observe none?"

The funny thing is that this is one of those situations where someone stumbles on the right answer for maybe the wrong reasons. In 1980, we thought we were closer to a "theory of everything" that we do today. We have the "Higgs trick" that unified weak and electromagenetic forces. It seemed pretty straight-forward to apply that to strong forces. Only problem is that you have lots of monopoles.

Today, I don't think that people believe that inflation really solves the monopole problem because it's not clear that there is a monopole problem to begin with. Now there are *other* reasons for thinking that inflation exists, and one of the stronger results for thinking that there is inflation (i.e. gaussian flucutations) is something that no one who thought of inflation originally had thought of.

Anyway, a false Higgs vacuum, as a scalar field would give him the characteristic delay he needed to allow expansion to continue long enough to give him the expansion he sought to dissipate magnetic monoples from existence...gluing these pieces together, Volia! inflationary expansion was born! After realizing this and confirming with some calculations, THEN he realizes such extended rapid expansion also solves the flatness problem he had heard about a year before in a talk he attend given by Dicke...Apparently he had not known about THAT issue peviously but was smart enough to realize it 'fit' his expansionary ideas...but his model had not planned to incorporate that fantastic and necessary result...it was a 'freebe'

Except that it turns out not to work. The basic problem with the original inflation model is that there is no way of stopping it, and right now all we have is some magic scalar field. No idea what that magic scalar field is.
.
I still find it amazing that nature fits some of our math.

I'm not. You toss a hundred theories at nature and one of them is bound to work. Sometimes, you stumble on the right answer for the wrong reasons. For example, it's clear that Pluto is not Planet X, and that people just got the mass of Uranus wrong.

And then there is Christopher Columbus and America. For that matter one of the major discoveries made at CERN was the world wide web.
 
  • #7


Here is another paper

http://arxiv.org/pdf/1003.2635.pdf

The interesting thing about this paper is that it explains why most people for the longest time assumed that the Higgs field could *not* be the inflation field.

Trying to translate this into English. The original result is that if you assume that the Higgs particle causes inflation then the Higgs field is strong enough so that you can't get it to work without assuming quantum gravity effects. What the new papers are saying is "well, let's make some lemonade, assume that the Higgs particle causes inflation and then assume some things about quantum gravity."
 
  • #8


The basic problem with the original inflation model is that there is no way of stopping it, and right now all we have is some magic scalar field.

I had forgotten about that issue...I,too, have read that...
But the story Guth tells so far in his book and I attempted to capsulize above includes a 'false Higgs vacuum' decay which does provide a plausible end to inflation. I haven't finished the book yet so there may be more to the story. According to his recollection of this effort so far, he had to do some calculations to verify the phase transition delay was long enough to smear out monopoles...turns out it he thought so ...
 
  • #9


The Standard Model of particle physics points to one Higgs which they call the "Standard Model Higgs".

THAT's interesting!
I had recently read somewhere the CERN team was not sure which Higgs particle they had discovered and it would be some months before they figured that out so I have not being paying any attention so far. But I imagine they are being especially cautious after the recent 'faster than light discovery' proved otherwise.
 
  • #10


Thanks, Marcus, for the references. And for the comment "My hunch is that we are entering a new phase of understanding the early universe --- inflation scenarios in particular." I agree and hope you're right. And thank you, Naty1, for your posts and remarks about multiple Higgs'. I hope you are overly pessimistic!

I'll reply specifically to your kind detailed and specific clarifications, and corrections about W and Z, twofish-quant:
twofish-quant said:
...The Higgs mechanism was to allow you to have massive bosons...

...here .. we are talking all about "rest masses". "Relativistic mass" is a way of explaining special relativity that turns out to cause more confusing than anything else. Since Higgs is a nice mechanism for giving W and Z particles mass, people sort of assume that the same mechanism would work for all particles, but that's not been established yet...

In this context I still prefer to distinguish between rest mass (usually just called mass) and the mass equivalent of motion or intrinsic energy content (say via E = h x nu = mc^2 for photons), that (I agree confusedly) has been called relativistic mass. I did and do still assume that it is now accepted that the Higgs mechanism is the origin also of the inertia and of gravitational interaction associated with both quantities, whatever they may be called . Otherwise how would photons in superconductors acquire mass (P.W.Anderson) and generate the Meissner effect via the forerunner of the Higgs mechanism?

But perhaps I'm wrong, and in that case I'd like to be corrected.

About the implications for cosmology of the newly discovered Higgs, the one CERN's Heuer announced on July 4: definitely profound; imagine running the evolution of the universe as a movie backwards (dynamics is time-symmetric, remember) until one comes to the proposed instant when the Higgs mechanism (and possibly inflation?) switched on at an appropriate and inconceivably high temperature. Suddenly, no more mass/energy, inertia or gravity! I suggest that here local time loses its meaning as a useful parameter with which to describe reality, which is the task of physics. Hence the end (or rather the beginning) of our subject. Perhaps a universe-wide time could still exist, to be measured from the black-body temperature of radiation, as we run the movie even further back?

The scope for speculation here has enormous potential to keep shoals of theoretical physicists employed far into the future! I vote for Anderson, Higgss and CERN as the next three recipients of the Nobel prize.
 
  • #11


Paulibus said:
I did and do still assume that it is now accepted that the Higgs mechanism is the origin also of the inertia and of gravitational interaction associated with both quantities, whatever they may be called.

It's not. "Relativistic mass" comes from a coordinate transform. Also "relativistic mass" doesn't generate inertia. The way that "relativistic mass" interacts with gravity is different enough from "rest mass" that it's a bad idea to confuse the two.

The Higgs mechanism is solely to generate "rest mass". It's got nothing to do with generating inertia in general or gravity.

Otherwise how would photons in superconductors acquire mass (P.W.Anderson) and generate the Meissner effect via the forerunner of the Higgs mechanism?

What happens in superconductors is that that the Higgs mechanism makes photons behave as if they had "rest mass."

one comes to the proposed instant when the Higgs mechanism (and possibly inflation?) switched on at an appropriate and inconceivably high temperature. Suddenly, no more mass/energy, inertia or gravity!

Nope. Higgs mechanism just gives particles rest mass. Nothing much to do with energy, inertia, and gravity. Also, at high temperatures, the rest mass of the particles is going to be an insignificant fraction of the total energy and interacting with each other, so the particles will act as if they had close to zero rest mass anyway.

One way of thinking of "symmetry breaking" is to imagine an 1 kg of apple and 1 kg of glass of water and 1 kg of lead. They act pretty differently. Now if you heat the apple and glass of water to 5000 celsius, they are going to start behaving the same way. If you heat them to 10 million celsius, they are going to behave exactly the same. At 10 million celsius apples, water, and lead just become particle plasma with exactly the same characteristics.

Similarly W,Z and photons are very different at low temperatures. Heat it up to GUT temperatures and they act the same. If you heat apples to extremely high temperatures, there will be some temperatures at which the characteristics of the apples change, but this doesn't cause any "weird stuff" to happen with time and space. The energy at which we expect "something weird" to happen with time and space is much, much hotter than the Higgs symmetry breaking temperatures.

The scope for speculation here has enormous potential to keep shoals of theoretical physicists employed far into the future! I vote for Anderson, Higgss and CERN as the next three recipients of the Nobel prize.

Sure, but the Higgs in some sense is "just another particle". It's not the ultimate key to time and space.
 
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  • #12


Naty1 said:
I haven't finished the book yet so there may be more to the story.

I'm pretty sure that the book ends before the end of the story. There have been some interesting papers written in the last several *months*.
 
  • #13


Thanks for this clear and definite reply, twofish-quant. Seems as if I've been harbouring delusions. Just one last delusion to be considered, perhaps.

I thought that gravitational mass, inertial mass and energy were all truly and fully equivalent; for example that a hot gas weighed more than the same gas cold, because the mass equivalent of the extra particle kinetic energy gravitated, and likewise that a stretched spring weighed more than the same spring unstretched, because its stored elastic energy gravitated.

Also that the hot gas and stretched spring would both be accelerated less by the firing of identical standardised rockets attached to them, than would their cold and unstretched counterparts, with less mass and therefore less inertia.

You seem to be telling me that this is wrong. Is it? I feel sand shifting below my feet!
 
  • #14


Paulibus said:
I thought that gravitational mass, inertial mass and energy were all truly and fully equivalent; for example that a hot gas weighed more than the same gas cold, because the mass equivalent of the extra particle kinetic energy gravitated, and likewise that a stretched spring weighed more than the same spring unstretched, because its stored elastic energy gravitated.

Yes. However, none of that has anything to do with the Higgs field. The thing is that if you take a gas and then cool it so that there is zero "external" energy, you'll find that the particles have some rest mass that are the result of there just being particles.

It's the "particle rest mass" that is generated from the Higgs field. The other ways that you can get gravity and inertia have nothing to do with Higgs.

And yes this means that "particle rest mass" is "different".

Also that the hot gas and stretched spring would both be accelerated less by the firing of identical standardised rockets attached to them, than would their cold and unstretched counterparts, with less mass and therefore less inertia.

Yup.

You seem to be telling me that this is wrong. Is it? I feel sand shifting below my feet!

No what you said was right. However, it's got nothing to do with Higgs. Higgs gives rest mass to certain particles.

Also, if you aren't the curious sort, you *could* say that particles have mass "just because". However that looks messy to physicists, so they want to put the known particles into a nice symmetric theory. So you write the equations for the Higgs field which are nice and symmetric and short.

When you lower the temperature and then the equations get messy, but you end up with "rest mass" for the weak bosons and a particle with zero rest mass which is the photon. You also get several other particle interactions that we can observe.

One other way of thinking about this. There is particle behavior that you get from things moving around. This is "easy" to write a simple equation for. If you had zero mass particles moving around, and all of the inertia and gravitation came from "energy of motion" there wouldn't be any need to add a Higgs field. The trouble is that if you take a particle and then just freeze it, some of them still have "mass" and then you just end up adding random things to your equations. By adding one Higgs field, you end up with an equation that gives you "rest mass" without saying "just because."
 
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  • #15


Thanks for the prompt reply. I'm becoming more and more reminded of 1984 in which George Orwell coined the word doublespeak, despite your kind and valiant attempts to explain to simple me in simple language what the Higgs does for rest mass, but not for mass in the form of energy. Some mass is more equal than other mass? (shades of Orwell again). eems to me a strange proposal .

You've said:
"Relativistic mass" comes from a coordinate transform. Also "relativistic mass" doesn't generate inertia. The way that "relativistic mass" interacts with gravity is different enough from "rest mass" that it's a bad idea to confuse the two.

The Higgs mechanism is solely to generate "rest mass". It's got nothing to do with generating inertia in general or gravity.
and again that:
It's the "particle rest mass" that is generated from the Higgs field. The other ways that you can get gravity and inertia have nothing to do with Higgs.

What you say is quite clear but, with respect, I'm just not persuaded that the theoretical ratiocination you describe makes sense; it seems that the Higgs is a mathematical device that fits much less easily into well-established physics, namely SR and GR, than I had imagined. What Lewis Carroll wrote in 1871 shouldn't be part of physics:
"When I use a word," Humpty Dumpty said in rather a scornful tone, "it means just what I choose it to mean — neither more nor less."
"The question is," said Alice, "whether you can make words mean so many different things."
"The question is," said Humpty Dumpty, "which is to be master— that's all."
I do hope the Higgs proves in the end to have a sound physical foundation
 
  • #16
What are you talking about? The Higgs field generates the rest mass of particles by interacting with them (called a Yukawa interaction). In SR, observers disagree on the amount of mass of an object due to Lorentz transformations. Where do you see a contradiction?
 
  • #17


Mark M: No contradiction seen. What happens if the Higgs hadn't yet operated, as in the very early universe before the Higgs scalar field symmetry was spontaneously broken? No rest mass, no mass for observers to disagree about? Read the rest of the thread before you rush to post a two-liner, please.
 
  • #18
Paulibus said:
Mark M: No contradiction seen.
Really? You stated earlier:
it seems that the Higgs is a mathematical device that fits much less easily into well-established physics, namely SR and GR, than I had imagined. What Lewis Carroll wrote in 1871 shouldn't be part of physics:
I do hope the Higgs proves in the end to have a sound physical foundation
I think that qualifies as 'seeing a contradiction'.
What happens if the Higgs hadn't yet operated, as in the very early universe before the Higgs scalar field symmetry was spontaneously broken?
Then particles have no rest mass. However, they have relativistic mass in the same sense that a photon does. Read this:

http://math.ucr.edu/home/baez/physics/ParticleAndNuclear/photon_mass.html
Read the rest of the thread before you rush to post a two-liner, please.
I did. You aren't making any sense.
 
  • #19


Paulibus said:
Thanks for the prompt reply. I'm becoming more and more reminded of 1984 in which George Orwell coined the word doublespeak, despite your kind and valiant attempts to explain to simple me in simple language what the Higgs does for rest mass, but not for mass in the form of energy. Some mass is more equal than other mass? (shades of Orwell again).

This is why particle physicists hate the term "relativistic mass". It confuses things. A lot of this can be make a lot clearer when you write the equations. The messy part is when you try to convert the equations into "plain English" since "plain English" really isn't designed to talk about particle physics.

Also "rest mass" can be converted to energy (E=mc^2). The division is between "mass-energy due to momentum" and "intrinsic mass-energy".

What you say is quite clear but, with respect, I'm just not persuaded that the theoretical ratiocination you describe makes sense; it seems that the Higgs is a mathematical device that fits much less easily into well-established physics, namely SR and GR

The way that it works is that special relativity and general relativity both establish restrictions on what are possible theories. Mass and energy have to behave in a certain way (and there is a specific mathematical form that equations have to take). The technical term for this is "Lorenz covariant". Having a set of equations that are "Lorenz covariant" is a basic requirement of any physical theory, and if it's not, then you can toss it out.

Now SR establishes some restrictions on what form a theory can take, but it doesn't completely specify the theory. For example, a universe in which you had ten different types of electrons or in which protons were massless would work fine with special relativity. If photons had mass and electrons didn't, that would also work with special relativity. So special relativity by itself isn't enough to describe the universe.

So in order to figure out why the universe is the way it is you have to add some "extra rules."

One way of doing this is to specify a "symmetry principle". Then you run into a problem of how do you have massive particles be "symmetric" with massless ones, and it's figuring out how to do this that got people Noble prizes...

Now if you aren't afraid of some Greek symbols...

http://en.wikipedia.org/wiki/Electroweak_interaction#Lagrangian

There are two equations in that section. One is nice, short, and symmetric.

The other one is nasty, long and ugly. It turns out that they are the same equation and you can get from one to the other though a bit of algebra.

Also both are consistent with special relativity. Basically what you can do is to do some transformations (i.e. replace one variable with another one) and then SR says that the equation has to behave in a certain way. If you say change the equations so that your reference frame moves at 0.5c, that shouldn't change the basic form of your equation.

Now the "L_g" part of the "short equation" is the part that has the "energy of momentum" and you see that in both the short and long form of the equation. The part that pops out if you do your algebra is the L_k, part that has "m"'s in front. That's the "intrinsic mass" part of the equation
 
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  • #20


twofish-quant said:
This is why particle physicists hate the term "relativistic mass". It confuses things. A lot of this can be make a lot clearer when you write the equations. The messy part is when you try to convert the equations into "plain English" since "plain English" really isn't designed to talk about particle physics.

Yes. I have indeed been confused by thinking of "relativistic mass" instead of focusing on relativistic kinetic energy, defined as total energy minus rest-mass energy. The usual practice of writing just "mass"' when meaning rest-mass hasn't helped, either. Thanks a lot for your patience in tolerating my obtuseness.

I'll see if I can understand the electroweak article you pointed me to. It'll keep me quiet for a while!

Then you did say :

...The Higgs mechanism was to allow you to have massive bosons... Since Higgs is a nice mechanism for giving W and Z particles mass, people sort of assume that the same mechanism would work for all particles, but that's not been established yet...
and I confess I've been carried away too far by this hyperbolic guess.

If it were true, however, then the pre-Higgs universe (if it ever did exist) would be a universe in which all particles moved at c; one in which I can't see how time could be measured, or even exist as a useful parameter, in which case eternal dawn still seems to me an appropriate name for such a totally alien place.
 
  • #21


Paulibus said:
If it were true, however, then the pre-Higgs universe (if it ever did exist) would be a universe in which all particles moved at c

One thing to remember is that at the temperatures we are talking about, the expected velocities of the particles are going to be close to C any way.

one in which I can't see how time could be measured, or even exist as a useful parameter, in which case eternal dawn still seems to me an appropriate name for such a totally alien place.

There are levels of weird, and the world of Higgs symmetry breaking really isn't that weird. Things are whizzing at the speed of light, but you can think of it is just a type of gas and gases aren't that weird. The thing about the Higgs energies is that you can still write equations involving "time" and you can use "time" to measure things like particle reaction rates, heating and cooling.

The thing about Higgs energies is that "energy curves space" and the about of curvature that you get at Higgs energies isn't that huge, so time is still time and space is still space. We are at 10^4 GeV. That's out of the village into the edge of the forest, but we aren't in the land of Oz.

Now if you get to 10^18 GeV then things really get weird, at those energies the amount of energy is enough to get "black hole" levels of gravity, and at that point "time is no longer time and space is no longer space" and we get a weird mess that no one knows what to deal with. *That's* where the really weird stuff happens.
 
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  • #22


twofish-quant said:
The thing about Higgs energies is that "energy curves space" and the about of curvature that you get at Higgs energies isn't that huge, so time is still time and space is still space. We are at 10^4 GeV. That's out of the village into the edge of the forest, but we aren't in the land of Oz.
Nicely put. And as you say, everything at this energy is racketing about very close to c, anyway, even if everything was equipped with rest mass. I hadn't grasped this. But then the time dilation effect of SR, even for any imaginable-in-principle observer, means that Time for all that she could observe would be slowed drastically (slightly reminiscent of H.G. Wells's time traveller at the end of his journeying). Such a situation is pretty weird to describe as involving any sort of sudden event, like a Bang, which I'm now even more firmly convinced is an amazingly inappropriate description. Even Genesis 1.3 sounds better, somewhat to my dismay.
 
  • #23
It seems that the Higgs does indeed have a sound physical foundation. I apologise for having been so sceptical. Recent announcements at CERN have convinced me.

In the meantime, via a roundabout path necessitated by my substantial ignorance, I've come to wonder if the suggested switching-on of the Higgs Mechanism via some sort phase change didn't mark the very beginning of the universe's history, or time-line story.

Reading Lisa Randall's recent book "Knocking on Heaven's Door" led me to wonder if the time dimension existed at all before the phase change, when the strange scenario may have prevailed of a universe in which all particles, then unbound constituents of a supremely energetic hot plasma, were "zipping around at light speed", as Lisa Randall put it.

I can't see how time, even remotely imaginably-observable time, could have existed in such a universe. I don't know if anyone else has a similar difficulty. I have a thread currently running in the High Energy Particle Physics forum, now inappropriately called Higgs --- interactions and forces; distinction between these? and there, or here, I'd welcome clarification by cosmology-savvy folk of my rather muddled thinking.
 
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1. What is the Higgs mechanism?

The Higgs mechanism is a theoretical explanation for how particles acquire mass. It proposes that there is a field, called the Higgs field, which permeates the universe and interacts with particles, giving them mass.

2. How does the Higgs mechanism relate to the beginning of the universe?

The Higgs mechanism is thought to have played a crucial role in the early moments of the universe. During the Big Bang, the Higgs field would have been in an unstable state, causing the universe to expand rapidly. As the universe cooled and the Higgs field stabilized, particles began to acquire mass, allowing them to interact and form the structures we see today.

3. What evidence do we have for the Higgs mechanism?

The Higgs mechanism was first proposed in the 1960s, but it wasn't until 2012 that the existence of the Higgs field and its associated particle, the Higgs boson, was confirmed by experiments at the Large Hadron Collider. This discovery provided strong evidence for the Higgs mechanism and its role in giving particles mass.

4. Can the Higgs mechanism be tested or observed?

Yes, the Higgs mechanism can be tested and observed through experiments at particle accelerators such as the Large Hadron Collider. By colliding particles at high energies, physicists can study the behavior of the Higgs field and its associated particle, the Higgs boson, to gain a better understanding of the mechanism.

5. Are there any other theories that explain the beginning of the universe?

Yes, there are several other theories that attempt to explain the beginning of the universe, such as inflation theory, string theory, and loop quantum gravity. These theories propose different mechanisms for the rapid expansion of the universe and the formation of structures, but the Higgs mechanism remains a key component in many of these theories.

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