TY - BOOK N2 - Everything around us is made of 'stuff', from planets, to books, to our own bodies. Whatever it is, we call it matter or material substance. It is solid; it has mass. But what is matter, exactly? We are taught in school that matter is not continuous, but discrete. As a few of the philosophers of ancient Greece once speculated, nearly two and a half thousand years ago, matter comes in 'lumps', and science has relentlessly peeled away successive layers of matter to reveal its ultimate constituents. N2 - "Albert Einstein once claimed that without belief in the inner harmony of our world, there could be no science. But modern science has revealed that the inner harmony of some of the simplest phenomena can be startlingly beautiful in its complexity. This is certainly true of matter, and its most commonplace property, mass. We have come a long way since the conjectures of the Greek atomists. We know for sure that atoms exist, and we also know that they're divisible. They consist of electrons, orbiting nuclei of protons and neutrons. We know that protons and neutrons are in turn composed of quarks. And we have found that elementary particles inside atoms behave like waves: mysterious phantoms of probability. We have identified several families of subatomic particles, and now recognize that 'empty' space fizzes with virtual particles. we think now of mass in terms of the energies of interactions. Elementary particles gain mass by interacting with the Higgs field, revealed by the discovery of the Higgs boson, but we still don't understand why some particles interact more strongly than others. As Jim Baggott explains in this absorbing account that takes us from atoms to quarks, gluons, and quantum chromodynamics, we have journeyed far, but we have yet to fully understand the fundamental nature of mass."--Jacket. AB - Everything around us is made of 'stuff', from planets, to books, to our own bodies. Whatever it is, we call it matter or material substance. It is solid; it has mass. But what is matter, exactly? We are taught in school that matter is not continuous, but discrete. As a few of the philosophers of ancient Greece once speculated, nearly two and a half thousand years ago, matter comes in 'lumps', and science has relentlessly peeled away successive layers of matter to reveal its ultimate constituents. AB - "Albert Einstein once claimed that without belief in the inner harmony of our world, there could be no science. But modern science has revealed that the inner harmony of some of the simplest phenomena can be startlingly beautiful in its complexity. This is certainly true of matter, and its most commonplace property, mass. We have come a long way since the conjectures of the Greek atomists. We know for sure that atoms exist, and we also know that they're divisible. They consist of electrons, orbiting nuclei of protons and neutrons. We know that protons and neutrons are in turn composed of quarks. And we have found that elementary particles inside atoms behave like waves: mysterious phantoms of probability. We have identified several families of subatomic particles, and now recognize that 'empty' space fizzes with virtual particles. we think now of mass in terms of the energies of interactions. Elementary particles gain mass by interacting with the Higgs field, revealed by the discovery of the Higgs boson, but we still don't understand why some particles interact more strongly than others. As Jim Baggott explains in this absorbing account that takes us from atoms to quarks, gluons, and quantum chromodynamics, we have journeyed far, but we have yet to fully understand the fundamental nature of mass."--Jacket. T1 - Mass :the quest to understand matter from Greek atoms to quantum fields / AU - Baggott, J. E., ET - First Edition. CN - QC171.2 CN - QC171.2 ID - 798527 KW - Mass (Physics) KW - Matter KW - Quantum field theory. KW - Field theory (Physics) KW - Particles (Nuclear physics) SN - 9780198759713 SN - 0198759711 TI - Mass :the quest to understand matter from Greek atoms to quantum fields / ER -