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Compelling Scientific Questions The International Linear Collider will answer key questions about matter, energy, space and time We sample some of these questions in more detail here The Terascale terrain Increasing energy of particle collisions in accelerators corresponds to earlier times in the universe, when phase transitions from symmetry to asymmetry occurred, and structures like protons, nuclei and atoms formed. The Terascale (Trillion electron volts), corresponding to 1 picosecond after the Big Bang, is special. We expect dramatic new discoveries there. The ILC and Large Hadron Collider (LHC) are like telescopes that view the earliest moments of the universe. The Terascale terrain The Standard Model requires a Higgs field pervading the universe to unify the Electromagnetic and Weak forces, and to give mass to the quarks and leptons. Its mass should be in the sub-Teravolt range. The Standard Model is surely incomplete; holding the Higgs mass at the terascale requires a miracle of ‘fine tuning’. New phenomena should exist (supersymmetry, technicolor, extra spatial dimensions etc.). Each has observable consequences – new particles or new forces – at the terascale. Dark Matter seems to be a particle (or particles) left over from the Big Bang, whose mass is in the teravolt range. The clues to unification of forces will lie at the terascale. The Quantum Universe Questions The “Quantum Universe” report gives nine key questions in three major areas. I. Einstein’s dream 1. Undiscovered principles, new symmetries? 2. What is dark energy? 3. Extra space dimensions? 4. Do all forces become the same? II. The particle world III. Birth of universe 5. New particles 8. 6. What is dark matter? How did the universe start? 7. What do neutrinos tell us? 9. Where is the antimatter? The ILC will provide answers for at least eight of these. Examples of the ILC scientific program follow. Revealing the Higgs The Higgs field pervades all of space, interacting with quarks, electrons etc. These interactions slow down the particles, giving them mass. The Higgs field causes the Electromagnetic (long range) and Weak (short range) forces to differ at low energy. It provides at least one unseen particle (the Higgs boson) that has yet to be found. Different theories predict different types of Higgs bosons with different properties. The Higgs boson is somewhat like the Bunraku puppeteers, dressed in black to be ‘invisible’, manipulating the players in the drama. Revealing the Higgs If the Higgs decays to visible particles, the LHC will see it and measure its mass. But the LHC will not determine its properties (intrinsic spin, etc.) and will not accurately measure the strength of its interactions with other particles. interaction rate Curves denote different Higgs boson spins; ILC data cleanly discriminate. collision energy The ILC can ‘see’ the Higgs boson even if it decays to invisible particles, and determine its quantum number properties, and thus point to the theory explaining it. Revealing the Higgs The ILC can measure the fractions of the Higgs decays into quarks, leptons, gluons and bosons. These decay fractions are the signatures that reveal the origin of the Higgs field. The pattern of deviations from the standard model expectations tells us about the underlying theory. Two possible examples: supersymmetry baryogenesis Standard model values Understanding the Higgs could give insight into Dark Energy Decoding Supersymmetry Supersymmetry overcomes inconsistencies in the standard model by introducing a new kind of space-time. But this requires that every known particle has a supersymmetric counterpart at the terascale. Thus the partner of the spin ½ electron is a spinless ‘selectron’. All quarks also have their partners, as do the W and Z bosons, etc. Decoding Supersymmetry The LHC is guaranteed to see the effects of supersymmetry, assuming SUSY has relevance for fixing the standard model. The counterparts of quarks and gluons will be produced copiously, but the LHC will not be sensitive to the partners of leptons, the photon, or of the W/Z bosons. The ILC can produce the lepton, photon, and W/Z partners, and determine their masses and quantum properties. If the matter-antimatter asymmetry in the universe arises from supersymmetry, the ILC can prove this to be the case. Decoding Supersymmetry There are hundreds of variants of SUSY theories and only detailed measurement of quantum numbers and masses of SUSY particles can show us which one is true. The measured partner-particle masses can be extrapolated to high energy to reveal the theory at work. These plots show how the superpartner masses vary with energy for two theories – quite different patterns for each Understanding dark matter Our own and other galaxies are gravitationally bound by unseen dark matter, predominating over ordinary matter by a factor of five. Its nature is unclear, but it is likely to be due to very massive new particles created in the early universe. Supersymmetry provides a very attractive candidate particle, the neutralino. All supersymmetric particles decay eventually to a neutralino. At the LHC the neutralino cannot be directly observed. Understanding dark matter e+ e- g,Z ~ m+ ~ m- ILC would copiously produce the partners of leptons. These decay to an ordinary lepton plus neutralino, from which the neutralino mass and spin can be deduced. The sharp edges in the lepton energy distribution pin down the neutralino mass to 0.05% accuracy. Understanding dark matter An aside: at the LHC, the mass of the neutralino and its heavier cousin (called c20) are entangled. LHC can’t measure either accurately. c20 mass c20 mass error with ILC help c20 mass error with no ILC help neutralino mass The precise ILC neutralino mass measurement allows the LHC to pin down the other particle mass accurately – an example of the synergy of the ILC and LHC. Understanding dark matter ILC and satellite experiments WMAP and Planck provide complementary views of dark matter. The ILC will identify the dark matter particle and measures its mass; Planck will be sensitive just to the total density of dark matter. Together they establish the nature of dark matter. Maybe ILC agrees with Planck; then the neutralino is likely the only dark matter particle. Maybe ILC disagrees with Planck; this would tell us that there are different forms of dark matter. Finding extra spatial dimensions String theory requires at least 6 extra spatial dimensions (beyond the 3 we already know). The extra dimensions are curled up like lines on a mailing tube. If their radius is ‘large’ (~1 attometer = billionth of an atomic diameter), they could unify all forces (including gravity). Finding extra spatial dimensions If a particle created in an energetic collision goes off into the extra dimensions, it becomes invisible in our world and the event shows missing energy and total momentum imbalance. There are many possibilities for the number of large extra dimensions, their size, and which particles can move in them. LHC and ILC see complementary processes that will help pin down these attributes. Finding extra spatial dimensions collision energy (TeV ) → Different curves are for different numbers of extra dimensions production rate The ILC with fixed (but tuneable) energy of electronpositron collisions can provide a separate measure that tells us both the size and number of dimensions. → The LHC collisions of quarks span a range of energies, and therefore measure the size and number of the ‘large’ extra dimensions separately. Finding extra spatial dimensions The ILC can measure the two ways this particle interacts with electrons. The colored regions indicate the expectation of three possible theories; the ILC can tell us which is correct! production rate axial coupling vector coupling Wavefunctions trapped inside a ‘box’ of extra dimensions yields a series of resonance states that decay into e+e- or m+m-. (But other new physical mechanisms could provide similar states.) LHC will not tell us what an observed new ‘resonance’ is. dimuon mass Is there a plot showing ILC errors? Seeking Unification At everyday energy scales, the 4 fundamental forces are quite distinct. At the Terascale, the Higgs field unifies the EM and Weak forces. LHC and ILC together will map the unified ‘Electroweak’ force. The Strong force may join the Electroweak at the Grand Unification scale. The ILC precision allows a view of this. We dream that at the Planck scale, gravity may join in. go here sense whats happening here force strength Seeking Unification energy g2 g3 g1 Present data show that the three forces (strong, EM, weak) have nearly the same strength at very high energy – indicating unification?? A closer look shows it’s a near miss! With supersymmetry, ILC and LHC can find force unification! g3 g2 g1 Seeking Unification Einstein’s greatest dream was finding unification of the forces. ILC will provide the precision measurements to tell us if grand unification of forces occurs. The ILC can provide a connection to the string scale where gravity may be brought in. Precision measurements at the ILC provide the telescope for charting the very high energy character of the universe instants after the Big Bang. Conclusions We know the terascale is fertile ground for new discoveries about matter, energy, space and time. We strongly believe new phenomena will be seen there, but don’t know yet which they will be. The ILC allows precision measurements that will tell us the true nature of the new phenomena. The ILC and the LHC together provide the binocular vision needed to see the new physics in perspective and view the terrain at much higher energies, and thus earlier times in the universe.