1. Tony Liss Saturday Physics for Everyone November 9, 2013 (With debts to Chris Quigg, Leonard Susskind, Hitoshi Murayama)

2. Mass is stuff Mass is the stuff that gravity acts on r Mass is stuff that resists you when you push it Mass is rest energy

4. Ordinary Matter

5. A proton is made of u u dAdd an electron to make a hydrogen atom A neutron is made of d d u Now you have all the building blocks of the periodic table.

6. According to theory, the Higgs boson gives these particles their mass..511 MeV/c 2 ~2.3 Mev/c 2 ~4.8 Mev/c 2 ~173000 Mev/c 2

7. Hydrogen: One proton, one electron M H c 2 = 938.890124 MeV M H /(M P +M e ) = 0.999999986 Helium: Two protons, two neutrons, two electrons M He c 2 =3,728.398128 MeV M He / (2M P +2M N +2M e ) = 0.9927 Iron: 26 protons, 30 neutrons, 26 electrons M Fe c 2 = 52,019 MeV M Fe /(26M P +30M N +26M e )=0.9909

8. No! Proton: Two up quarks and a down quark (2M u +M d )c 2 < 10 MeV M P c 2 = 938 MeV ! Neutron: Two down quarks and an up quark (2M d +M u )c 2 ~12 MeV M N c 2 = 940 MeV ! The mass of neutrons and protons is due (mostly) to the strong force (QCD) that holds them together:.511 MeV/c 2 ~2.3 Mev/c 2 ~4.8 Mev/c 2 ~173000 Mev/c 2

9. The mass of atoms is the sum of the mass of their parts (with very small corrections) – protons+neutrons+electrons The mass of protons and neutrons is not the sum of the mass of their parts (quarks) It is mostly from the energy in the strong force (QCD) binding the quarks together. Therefore, the mass of periodic table and the visible universe comes not from the masses of the fundamental particles, but from QCD!

10. Consider the proton & neutron masses The proton is electrically charged & therefore surrounded by its own electric field. The neutron is electrically neutral. You would guess that the proton is heavier than the neutron. But

11. M down > M up M neutron > M proton The heavier neutron “beta decays” in about 15 minutes into a proton plus an electron and a neutrino

12. If the quarks had no mass, then M P > M N The proton would beta decay into a neutron No hydrogen atom If the electron had no mass… No atoms at all No me No you

13. The Higgs ‘potential’

14. Atoms Force carriers Interactions Electroweak force

15. http://www.philica.com/display_article.php?article_id=126 duddud duuduu W–W– e –e – Beta decay

16. In the 1960s, the electromagnetic & weak interactions were unified into a single framework based on electroweak symmetry. The symmetry principle requires the carriers of the electromagnetic and weak forces to have zero mass. Quarks and leptons also have no mass. Electroweak symmetry must be hidden. But this isn’t true. Only the photon has no mass. Weak interactions are very short-ranged, implying that the carriers, W & Z bosons, are very massive.

17. I first saw this demo in a talk by Chris Quigg

18. ?

19. Energy of field 0 Strength of field All other fields The Higgs field The minimum energy has a non-zero Higgs field! http://commons.wikimedia.org/wiki/File:Mexican_hat_potential_polar_with_details.svg

20. + - H H O H H O Water molecules: Electrically neutral, but with a ‘dipole moment’ H H O H H O + - (Thanks to Leonard Susskind)

23. It is certainly A Higgs boson Therefore we know It is responsible for at least some of the W and Z mass (strong evidence). It is probably responsible for at least some of the fermion masses (evidence getting stronger). We don’t yet know: If it is the ONLY Higgs boson. Why it is so light.

24. Electric field lines around an electron We know the mass of the electron: This observed mass is an unobservable bare mass plus a correction due to the field energy This is fine tuning Hitoshi Murayama http://arxiv.org/abs/hep-ph/0002232 The energy in the electric field adds to the electron mass We know, then  m e c 2 ~ 10 GeV and 0.511 MeV = (-9999.489 + 10000.000) MeV

25. - -+-+ -+-+ -+-+ -+-+ -+-+ -+-+ -+-+ -+-+ -+-+ -+-+ -+-+ -+-+ -+-+ -+-+ -+-+ -+-+ -+-+ -+-+ -+-+ -+-+ -+-+ -+-+ -+-+ -+-+ -+-+ -+-+ -+-+ -+-+ -+-+ -+-+ -+-+ -+-+ -+-+ -+-+ -+-+ -+-+ Electron-positron pairs ‘pop’ out of the vacuum and shield the bare charge of the electron

26. The problem is,  is very very large (~10 38 GeV) if there is nothing else going on. This requires to be equally large in magnitude to cancel it and give

27. SUSY includes a partner to the top quark, the ‘stop quark’ or ‘top squark’ that nearly cancels the top quark loop But we haven’t found the stop quark yet. The more we don’t find it, the heavier it must be – if it exists at all…

28. Nature could be fine tuned. There is no law that forbids It’s just not very pleasing.

29. Since we are here, the fundamental constants must have values in the narrow range compatible with conscious life.

31.  Is there more than one Higgs boson? Supersymmetry, and many other ideas, include a family.  Does the Higgs boson give dark matter it’s mass?  Does the Higgs boson have anything to do with neutrino mass?  Is the anthropic principle correct?  What in the Universe is dark energy?