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Open Landscape David Mateos University of California at Santa Barbara (work with Jaume Gomis and Fernando Marchesano). An invitation for discussion:. Landscape ideas naturally lead to some anthropic reasoning And a warning for the skeptics: “A physicist talking about the landscape
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Open Landscape David Mateos University of California at Santa Barbara (work with Jaume Gomis and Fernando Marchesano)
An invitation for discussion: Landscape ideas naturally lead to some anthropic reasoning And a warning for the skeptics: “A physicist talking about the landscape is like a cleric talking about pornography: No matter how much you say you’re against it, some people will think you’re a little too interested! S. Weinberg
Plan Closed String Landscape Open String Landscape Discussion
String Theory • Achieves unification of GR and QM. • Has resolved important problems in quantum GR such as BH entropy, and contains many features of the SM. • However, not a single sharp prediction, and no real understanding of the basic facts of SM (gauge group, number of generations, MEW, particle masses) or of Cosmology ( 10-120 Mp).
X6 M4 The most basic fact of all: D=4 String theory predicts D=10, so traditional idea is: If SUSY: CY3 If homogeneous: dS, AdS or Mink
Low-energy physics in D=4 obtained from D=10 SUGRA: KK reduction yields V4D() for light fields (fluctuations). SUSY solutions M10= Mink4 CY3 have moduli problem: V4D() =0 If H=0 in X6
If H0 in X6 runaway potential V To stabilize moduli need `negative energy’ sources, e.g. orientifolds Vol(X6) V Vol(X6)
Many cycles in CY3 Many possible quantized values So turning on fluxes generically lifts moduli, but also leads to a huge number of vacua 10500 : Closed String Landscape
Anthropic implications? Eg. Cosmological Constant MPlanck MPlanck/Nvac Cf. Weinberg ‘87
Open strings are part of the spectrum Important for model building (eg SM fields live on D-branes) SU(3) SU(2) U(1) CY3 Generate non-perturbative effects (eg D-brane instantons) D-brane Generate large hierarchies (apps. to particle physics, cosmic strings,etc.) D-branes Essential to study SUSY D-branes in this setup because:
In the absence of fluxes, D-branes have geometric moduli (massless adjoints in D=4): CY3 D-brane We will see that all geometric moduli are generically lifted in presence of fluxes, and that an Open String Landscape appears.
A The combination that enters the action is: NS 2-form (potential for H ) [ A] Recall that on a D-brane there is a U(1) gauge field:
S4 is holomorphic and SUSY The SUSY conditions are formally the same w/ or w/o fluxes, but their solutions are very different For concreteness, consider a 4-cycle S4 (ie a D7 or a Euclidean D3): Consider a SUSY solution. There are h2,0(S4) holomorphic deformations Xi. Do they preserve anti-self-duality?
ai (S4‘) = 0 automatically if H=0 5 Generically solution is a set of isolated points: Open String Landscape -- N exp(h2,0) S4‘ S4 Under a deformation X: Generically ai (S4‘) = 0 constitute h2,0 equations for h2,0 would-be moduli
Reduced number of fermionic zero-modes New instantons may contribute to D=4 superpotential CY3 D-brane One immediate application: D-brane instantons Reduced number of bosonic zero-modes
Discussion Open Landscape appears on top of each Closed Vacuum Implications for phenomenology, model building, etc. How about Wilson Line Moduli? In T-dual picture Wilson Lines are stabilized. T-dual naturally leads to twisted tori. How about non-geometric flux compactitifcations? Important caveat: Closed Landscape far from established (cf. Tom Banks) Message: Scientific Issue, not taste
Conclusion “A physicist talking about the landscape is like a cleric talking about pornography: No matter how much you say you’re against it, some people will think you’re a little too interested!” S. Weinberg By now you’re all in trouble!