Neutrinos: status, models, string theory expectations Introduction Neutrino preliminaries and status Models String embeddings Intersecting brane The Z 3 heterotic orbifold Embedding the Higgs triplet Outlook
Neutrino mass Nonzero mass may be first break with standard model Enormous theoretical effort: GUT, family symmetries, bottom up Majorana masses may be favored because not forbidden by SM gauge symmetries GUT seesaw (heavy Majorana singlet). Usually ordinary hierarchy. Higgs triplets ( type II seesaw ), often assuming GUT, Left- Right relations
Models and spectra Weyl fermion Minimal (two-component) fermionic degree of freedom ψ L ψr c by CPT Active Neutrino (a.k.a. ordinary, doublet) in SU(2) doublet with charged lepton normal weak interactions ν L νr c by CPT Sterile Neutrino (a.k.a. singlet, right-handed) SU(2) singlet; no interactions except by mixing, Higgs, or BSM N R NL c by CPT Almost always present: Are they light? Do they mix?
Dirac Mass Connects distinct Weyl spinors (usually active to sterile): (m D ν L N R + h.c.) 4 components, L = 0 I = 1 2 Higgs doublet Why small? HDO? LED? Variant: couple active to antiactive, e.g., m D ν el ν c µr L e L µ conserved; I = 1 ν L h N R v = φ m D = hv
Majorana Mass Connects Weyl spinor with itself: 1 2 (m T ν L νr c + h.c.) (active); 1 2 (m S N L cn R + h.c.) (sterile) 2 components, L = ±2 Active: I = 1 triplet or seesaw Sterile: I = 0 singlet or bare mass Mixed Masses Majorana and Dirac mass terms ν L ν c R ν L ν L Seesaw for m S m D Ordinary-sterile mixing for m S and m D both small and comparable (or m S m d (pseudo-dirac))
3 ν Patterns Solar: LMA (SNO, KamLAND) 10 0 KARMEN2 LSND NOMAD NOMAD CDHSW CHORUS NOMAD CHORUS m 2 8 10 5 ev 2, nonmaximal Atmospheric: m 2 Atm 2 10 3 ev 2, near-maximal mixing Reactor: U e3 small m 2 [ev 2 ] 10 3 10 6 Cl Ga Bugey K2K CHOOZ Super-K+SNO +KamLAND SNO BNL E776 SuperK PaloVerde KamLAND Super-K 10 9 ν e ν X ν µ ν τ ν e ν τ ν e ν µ 10 12 10 4 10 2 10 0 tan 2 θ 10 2 http://hitoshi.berkeley.edu/neutrino
Mixings: let ν ± 1 2 (ν µ ± ν τ ): ν 3 ν + ν 2 cos θ ν sin θ ν e ν 1 sin θ ν + cos θ ν e 3 2 1 Hierarchical pattern Analogous to quarks, charged leptons ββ 0ν rate very small 2 1 3 Inverted quasi-degenerate pattern ββ 0ν if Majorana SN1987A energetics (if U e3 0)? May be radiative unstable
Degenerate patterns Motivated by CHDM (no longer needed) Strong cancellations needed for ββ 0ν if Majorana May be radiative unstable
4 ν Patterns LSND: m 2 LSND > 1 ev 2 Z lineshape: 2.984(9) active ν s lighter than M Z /2 fourth sterile ν S 2 + 2 patterns 3 + 1 patterns 2 + 2 3 + 1 Pure (ν µ ν s ) excluded for atmospheric by SuperK, MACRO Pure (ν e ν s ) excluded for solar by SNO, SuperK More general admixtures possible, but very poor global fits Additional sterile (e.g., 3 + 2) fit better but may have cosmological difficulties
Outstanding issues Dirac or Majorana? degenerate. (Observation?) Distinguish by ββ 0ν, at least for inverted, Scale of neutrino masses: 0.05 ev < m ν < O(0.3 ev). Probe by β decay (KATRIN), cosmology, ββ 0ν Hierarchy: ββ 0ν, matter effects in long baseline, supernova U e3, leptonic CP : reactor, long baseline LSND? New (sterile) ν s which mix with active: MiniBooNE. New interactions or nonstandard Solar effects as perturbations: need precise experiments, e.g. MINOS, future Solar Leptogenesis? Connection with top-down, especially strings
The minimal seesaw Active (sterile) neutrinos ν L (N R ) (3 flavors each) L = 1 2 ( νl N L) ( c m T m D m T D m S ) ( ) ν c R N R + hc m T = m T T = triplet Majorana mass matrix (Higgs triplet) m D = Dirac mass matrix (Higgs doublet) m S = m T S = singlet Majorana mass matrix (Higgs singlet)
Ordinary (type I) seesaw: m T = 0 and (eigenvalues) m S m D : m eff ν = m Dm 1 S mt D diagonalized by U ν, with U P MNS = U e U ν To achieve large mixings, most models assume either U e I in basis with manifest symmetries for m D,S need large mixings in U ν (requires clever m D, m S collaboration) Large U e mixings from lopsided m e in basis with m D,S diagonal (harder to achieve in SO(10) than SU(5)) SO(10) models, combined with family symmetries, often large Higgs representations (e.g., 126-plet); typically, m S 10 14 GeV
Extended (TeV) Seesaw m ν m p+1 /m p S, p > 1 (e.g., m 100 MeV, m S 1 TeV for p = 2) ν L, N R, N R (3 flavors each) L = 1 ( νl N c L 2 N 0 m D m D L) c m T D 0 m SS m T D m T SS 0 νc R N R N R + hc or L = 1 2 ( νl N c N L L) c 0 m D 0 m T D 0 m SS 0 m T SS m S νc R N R N R + hc
Triplet models Introduce Higgs triplet T = (T ++ T + T 0 ) T with weak hypercharge Y = 1 Majorana masses m T generated from L ν = λ T ij L it L j if T 0 0 Old Gelmini-Roncadelli model: T 0 EW scale with spontaneous L violation Excluded by Z Majoron + scalar (equivalent to N ν = 2) Modern triplet models (type II seesaw) break L explicity by T HH couplings, giving large Majoron mass Often considered in SO(10) or LR context, with both ordinary and triplet mechanisms competing and with related parameters, but can consider independently.
Dirac Masses Can achieve small Dirac masses (neutrino or other) by higher dimensional operators L ν ( S M P l ) p LN c L H 2, S M P l m D ( S M P l ) p H 2 Large p S close to M P l (e.g., anomalous U(1) A ) Small p intermediate scale M P l Similar HDO may give light steriles and ordinary/sterile mixing
Other Models Large extra dimensions (suppressed Dirac Yukawa couplings) R-parity violation in supersymmetry TeV scale loops with new ad hoc scalars Ad hoc flavor symmetries, textures, anarchic models Anthropic considerations (string landscape)
Neutrino Mass in Strings Very little work from string constructions, even though may be Planck scale effect Key ingredients of most bottom up models forbidden in known constructions (heterotic or intersecting brane) (Due to string symmetries or constraints, not simplicity or elegance) Right-handed neutrinos may not be gauge singlets Large representations difficult to achieve (bifundamentals, singlets, or adjoints) GUT Yukawa relations broken String symmetries/constraints severely restrict couplings, e.g., Majorana masses, or simultaneous Dirac and Majorana masses
Quasi-realistic string constructions Two classes of quasi-realistic: intersecting D-brane, heterotic Intersecting D-brane (review: R. Blumenhagen, M. Cvetic, P.L., G. Shiu, hep-th/0502005) Closed strings (gravitons) and open strings ending on D-branes D6-branes: fill ordinary space and 3 of the 6 extra dimensions Stringy implementation of brane world ideas
Gauge interactions from strings beginning/ending on stack of parallel branes (one for each group factor) Chiral matter: strings at intersection of branes, e.g., SU(N) SU(M) bifundamental (N, M) a Gauge bosons in adj. U(1) W U(1) b W + Chiral matter in (N, M)
Family replication from multiple intersections on compactified geometry Yukawa interactions exp( A ijk ) hierarchies Existing models: conserved L; no diagonal (Majorana) triangles However, no realistic model with large enough A for small Dirac neutrino masses (more generic geometries?) (1, 1) (1,3) (1, 1) (1,2) (1,0) (1,1) T 2 T 2 T 2 H Q 3 L U 3 SU(3) Q 2 L U2 Q 1 L SU(3) SU(2) U U(1) 1 SU(3)
The E 8 E 8 Heterotic String Dirac masses Can achieve small Dirac masses (neutrino or other) by higher dimensional operators L ν ( S M P l ) p LN c L H 2, S M P l m D ( S M P l ) p H 2 Recent variant: N c L is a modulus (Bouchard, Cvetič, Donagi, hepth/0602096)
Majorana masses Can one generate large effective m S from S q+1 S q+1 W ν c ij N i N j (m S ) ij c ij, M q P l consistent with D and F flatness? M q P l Can one have such terms simultaneously with Dirac couplings, consistent with flatness and other constraints? Are bottom-up model assumptions for relations to quark, charged lepton masses maintained?
The Z 3 Heterotic Orbifold (J. Giedt, G. Kane, P.L., B. Nelson, hepth/0502032) Systematically studied large class of vacua Is minimal seesaw common? If rare, possibly guidance to model building Clues to textures, etc. Several models from each of 20 patterns; W through degree 9; huge number of D flat directions reduced greatly by F -flatness Only two patterns had Majorana mass operators S 1 S n 2 NN/M n 3 PL None had simultaneous Dirac operators S 1 S d 3 NLH u/m d 3 PL leading to m 2 > 10 10 ev 2 (one apparent model ruined by offdiagonal Majorana) Feature of Z 3 orbifold? Or more general?
Systematic searches in other constructions important (Is seesaw generic? Rare? Alternatives?) Consider alternatives seriously Small Dirac masses from high degree terms (very common in constructions) (could also give light sterile ν s and mixing) Extended seesaws, m ν m 2+k D /M 1+k, with k 1 and low (e.g., TeV) scale M Higgs triplet models: non-trivial to embed in strings (higher level), but very predictive (e.g., inverted hierarchy with nearly bi-maximal mixing) (B. Nelson, PL, hep-ph/0507063)
Triplet models Introduce Higgs triplet T = (T ++ T + T 0 ) T with weak Y = 1 Majorana masses m T generated from L ν = λ T ij L it L j if T 0 0 General SUSY case W ν = λ T ij L it L j + } λ 1 H 1 T H 1 {{ + λ 2 H 2 T H } 2 needed to avoid Majoron +M T T T + µh 1 H 2 T, T are triplets with Y = ±1, M T 10 12 10 14 GeV. Typically, T 0 λ 2 H 0 2 2 /M T m ν ij = λt ij λ 2 v 2 2 M T Most previous models: GUT/LR symmetry, ordinary hierarchy
String constructions Expect λ T ij = 0 for i = j (off-diagonal) mν ii = 0 Also, need multiple Higgs doublets H 1,2 with λ 1,2 off diagonal Partial explanation: SU(2) triplet with Y 0 requires higher level embedding, e.g., of SU(2) SU(2) SU(2) (Have Z 3 constructions with some but not all of the features, B. Nelson, PL, hep-ph/0507063) W λ T 1j L 1(2, 1)T (2, 2)L j (1, 2), j = 2, 3 yields m ν = 0 a b a 0 0 b 0 0 Typical string case: a = b
A special texture The L e L µ L τ conserving texture m ν 0 a b a 0 0 b 0 0 has been considered phenomenologically by many authors New aspects Strong string motivation Motivation for special case a = b Can perturb by HOT No reason for U e = I in this basis
Yields inverted hierarchy, with eigenvalues 0, ± a 2 + b 2 Diagonalization: tan θ Atm = b/a need b = a for maximal If U e = I: θ = π 4 (maximal) (experiment: π 4 θ = 0.19 +0.05 0.06, 2σ) Comparable to Cabibbo angle, θ C 0.23 Perturbations on m ν cannot give both m 2 and π 4 θ 0.19 (cf θ C 0.23) without fine-tuning between terms, e.g., m 2 2 m 2 Atm π (m ν 23 + mν 11 ) 1 43 4 θ 1 4 (mν 23 mν 11 ) 0.19
However, U e I with small angles (comparable to CKM) can give agreement with experiment U e 1 se 12 0 s e 12 1 0 0 0 1 yields π 4 θ se 12 s e 12 0.27+0.07 0.08 2 U e3 2 (se 12 )2 2 (0.017 0.059), 2σ (exp : < 0.032) m ββ m 2 (cos 2 θ sin 2 θ ) 0.018 ev
Outlook Neutrino mass likely due to large or Planck scale effects, but little work in string context Specific orbifold string constructions (heterotic, intersecting brane) not consistent with common GUT and bottom up assumptions for m ν No examples of minimal seesaw in large class of heterotic Z 3 orbifold vacua Small Dirac, extended seesaw, Higgs triplet (inverted hierarchy in string context) should be seriously considered