The discussion centers on the relationship between matter and energy, specifically the theoretical and practical aspects of creating matter from energy. Participants reference Einstein's equation E=mc², highlighting processes such as electron-positron pair production and annihilation as real-world examples of energy converting to matter and vice versa. The conversation also touches on the nature of mass and energy, with some arguing that mass is not a fundamental property but rather an emergent quantity arising from interactions. Ultimately, the dialogue emphasizes that while matter and energy are interconnected, they are not interchangeable in a straightforward manner.
PREREQUISITESPhysicists, students of quantum mechanics, and anyone interested in the fundamental principles of matter and energy conversion.
Graybass, your comments are pretty speculative. String theory is not 'energy vibrating' and 'creating matter from energy'. Einstein's equation E=mc^2 of course tells us the 'currency' conversion between mass (what is usually referred to as matter) and energy. Good examples of how this conversion actually manifests itself in nature are electron/positron pair production and annihilation. Processes exist in which photons (energy) are converted to electron/positron pairs (matter). The reverse of this process also occurs in nature: electrons and positrons can annihilate to form photons. Of course, as alvarogs mentions, nuclear reactions are also a nice place to find examples of the conversion of matter to energy.graybass said:If the physical universe all around us is the result of E=MC squared, then is not all matter the living breathing example of energy vibrating (string theory) therefore creating matter from energy in the form of everything, including you and me.
Therefore matter is constantly being created from energy right in front of our eyes, nano second to nano second.
My math sucks, but I'm talking big picture here. :)
bapowell said:Graybass, your comments are pretty speculative. String theory is not 'energy vibrating' and 'creating matter from energy'. Einstein's equation E=mc^2 of course tells us the 'currency' conversion between mass (what is usually referred to as matter) and energy. Good examples of how this conversion actually manifests itself in nature are electron/positron pair production and annihilation. Processes exist in which photons (energy) are converted to electron/positron pairs (matter). The reverse of this process also occurs in nature: electrons and positrons can annihilate to form photons. Of course, as alvarogs mentions, nuclear reactions are also a nice place to find examples of the conversion of matter to energy.
That doesn't work. Conservation laws prevent doing anything more drastic than rearranging protons and electrons, as those are the lowest-mass particles with their atomic numbers.Bandoo said:Have we ever "dissolved" mass to convert to energy for practical uses so far? What we get is in reality the binding energy released by breaking a big atom on one side of periodic table or by "gluing" four nucleons (so to say) together on the other side.
So do you consider photons matter?Chalnoth said:Energy is a property of matter.
Yes. They are not fundamentally different from electrons or quarks. They just have different quantum numbers.bapowell said:So do you consider photons matter?
OK. It sounds like this is largely a discussion of semantics. Has anyone in this thread defined what they mean by the term matter? I don't find it to be an overly helpful concept if virtually anything of substance is matter. Traditionally, matter was contrasted with other forms of energy in that it had mass. Chalnoth, you seem to disagree with this view.Chalnoth said:Yes. They are not fundamentally different from electrons or quarks. They just have different quantum numbers.
Very much so, because mass doesn't appear to be a fundamental property of any matter: if you attempt to give particles mass as a fundamental property in quantum field theory, it quickly leads to a contradiction. So in the standard model of quantum physics, mass arises due to interactions.bapowell said:Traditionally, matter was contrasted with other forms of energy in that it had mass. Chalnoth, you seem to disagree with this view.
Right, I agree with this. I agree that mass is certainly an 'emergent' quantity in gauge theory -- spontaneous symmetry breaking merely 'dresses' massless excitations. So, I guess the original question still remains. What is the point of talking about 'matter' if it is really not (operationally) any different from energy.Chalnoth said:Very much so, because mass doesn't appear to be a fundamental property of any matter: if you attempt to give particles mass as a fundamental property in quantum field theory, it quickly leads to a contradiction. So in the standard model of quantum physics, mass arises due to interactions.
The largest distinction between photons (and other force carriers) and normal matter (e.g. protons, neutrons, electrons) is that normal matter is made up of fermions, while force carriers are made up of bosons. But even that's a bit tenuous of a distinction, as normal matter can also pair up to behave in a bosonic manner.
Matter is a description of a quantum field, whereas energy is a property of that field.bapowell said:What is the point of talking about 'matter' if it is really not (operationally) any different from energy.