Overview of magnetic and electric dipole moments and the Standard Model values of a e and a μ Thomas Teubner Introduction & motivation, overview EDMs and.

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Overview of magnetic and electric dipole moments and the Standard Model values of a e and a μ Thomas Teubner Introduction & motivation, overview EDMs and MDMs SM prediction of a e and a μ a μ HVP : status/puzzles/outlook Lepton Moments 2014, Centerville, Cape Cod, MA 21 st July 2014

Introduction & motivation: EDMs and MDMs SM `too’ successful, but incomplete: ν masses (small) and mixing point towards some high-scale (GUT) physics, so LFV in neutral sector established, but no Charged LFV & EDMs seen so far Need to explain dark matter Not enough CP violation in the SM for matter-antimatter asymmetry And: a μ EXP – a μ SM at 3.x σ Is there a common New Physics (NP) explanation for all these puzzles? Uncoloured leptons are particularly `clean’ probes to establish and constrain/distinguish NP, complementary to high energy searches at the LHC No direct signals for NP from LHC so far: - some models like CMSSM are in trouble already when trying to accommodate LHC exclusion limits and to solve muon g-2 - is there any TeV scale NP out there? Or new low scale physics? Low energy observables may provide the key

Large g-2  Large CLFV G. Isidori, F. Mescia, P. Paradisi, and D. Temes, PRD 75 (2007) Flavour physics with large tan β with a Bino-like LSP Excluded by MEG deviation from SM (g-2) g-2 (BNL E821) Motivation: SUSY in CLFV and DMs [From Tsutomu Mibe] MEG limit now even:

Introduction: Lepton Dipole Moments Dirac equation (1928) combines non-relativistic Schroedinger Eq. with rel. Klein- Gordon Eq. and describes spin-1/2 particles and interaction with EM field A μ (x): with gamma matrices and 4-spinors ψ(x). Great success: Prediction of anti-particles and magnetic moment with g = 2 (and not 1) in agreement with experiment. Dirac already discussed electric dipole moment together with MDM: but discarded it because imaginary. 1947: small deviations from predictions in hydrogen and deuterium hyperfine structure; Kusch & Foley propose explanation with g s = ±

Introduction: Lepton Dipole Moments 1948: Schwinger calculates the famous radiative correction: that g = 2 (1+a), with a = (g-2)/2 = α/(2π) = This explained the discrepancy and was a crucial step in the development of perturbative QFT and QED `` If you can’t join ‘em, beat ‘em “ The anomaly a (Anomalous Magnetic Moment) is from the Pauli term: This is a dimension 5 operator, non-renormalisable and hence not part of the fundamental (QED) Lagrangian. But it occurs through radiative corrections and is calculable in perturbation theory. Similarly, an EDM can come from a term

Introduction: Lepton Dipole Moments General Lorentz decomposition of spin-1/2 electromagnetic form factor: with q = p’-p the momentum transfer. In the static (classical) limit we have: Dirac FF F 1 (0) = Qe electric charge Pauli FF F 2 (0) = a Qe/(2m) AMM F 3 (0) = d Q EDM F 2 and F 3 are finite (IR+UV) and calculable in (perturbative) QFT, though they may involve (non-perturbative) strong interaction effects. F A (q 2 ) is the parity violating anapole moment, F A (0)=0. It occurs in electro-weak loop calculations and is not discussed further here.

Lepton Dipole Moments: complex formalism The Lagrangian for the dipole moments can be re-written in a complex formalism (Bill Marciano): and with the right- and left-handed spinor projections and the chirality-flip character of the dipole interaction explicit. Then and the phase Φ parametrises the size of the EDM relative to the AMM and is a measure for CP violation. Useful also to parametrise NP contributions. Note: Dirac was wrong. The phase can in general not be rotated away as this would lead to a complex mass. The EDM is not an artifact.

Lepton Dipole Moments & CP violation Transformation properties under C, P and T: now: and so a MDM is even under C, P, T, but an EDM is odd under P and T, or, if CPT holds, for an EDM CP must be violated. In the SM (with CP violation only from the CKM phase), lepton EDMs are tiny. The fundamental d l only occur at four+ -loops: Khriplovich+Pospelov, FDs from Pospelov+Ritz d e CKM ≈ O( ) e cm However: …

Lepton EDMs: measurements vs. SM expectations Precision measurement of EDM requires control of competing effect from μ is large, hence need extremely good control/suppression of B field to O(fG), or a big enhancement of  eEDM measurements done with atoms or molecules (see TH talks of Adam Ritz and Rob Timmermans) Equivalent EDM of electron from the SM CKM phase is then d e equiv ≤ e cm Could be larger up to ~ O( ) due to Majorana ν’s (d e already at two-loop), but still way too small for (current & expected) experimental sensitivities, e.g. |d e | < 8.7 × e cm from ACME Collab. using ThO [Science 343(2014) 6168] Muon EDM: in SM expect, but may be broken by NP. Best limit on μEDM from BNL: d μ < 1.8 × e cm [PRD 80(2009) ] New g-2 experiments at FNAL and J-PARC hope to bring this down significantly τ EDM: < 5 × e cm [BELLE PLB 551(2003)16]

Complementary! 22 14m diameter BNL/Fermilab Approach J-PARC Approach [From Naohito Saito] EDM & AMM at BNL/FNAL vs J-PARC

Lepton EDMs: d μ vs. a μ One more reason to push for best possible muon EDM measurement: μEDM could in principle fake muon AMM `The g-2 anomaly isn’t’ (Feng et al 2001)  Less room than there was before E821 improved the limit. E821 exclusion (95% C.L) G.W. Benett et. al, PRD80 (2009) E821 exclusion (95% C.L) G.W. Benett et. al, PRD80 (2009) Δa μ x d μ x (e cm)

EDMs. Strong CP violation In principle there could be large CP violation from the `theta world’ of QCD: is P- and T-odd, together with non-perturbative strong instanton effects, Θ≠0 could lead to strong CP violation and n and p EDMs, d n ≈ 3.6× θ e cm. However, effective θ ≤ from limits on nEDM. Limits on pEDM from atomic eEDM searches; in SM expect |d N | ≈ e cm. Ideally want to measure d n and d p to disentangle iso-vector and iso-scalar NEDM (strong CP from θ predicts iso-vector, d n ≈-d p, in leading log, but sizeable corrections) See Yannis Semertzidis for new proposal to measure the pEMD at a storage ring For up-to-date limits and measurements of EDMs see the specific talks later this week Any non-zero measurement of a lepton or nucleon EDM would be a sign for CP violation beyond the SM and hence NP.

Left - Right other SUSY Multi Higgs MSSM eEDM (e.cm) Standard Model Slide thanks to Ed Hinds (from his 2013 talk in Liverpool) The interesting region of sensitivity Theoretical estimates of eEDM Insufficient CP to make universe of matter ee  selectron

Left - Right other SUSY Multi Higgs MSSM eEDM (e.cm) We are starting to explore this region Standard Model d e < 1 x e.cm New excluded region Slide thanks to Ed Hinds (from his 2013 talk in Liverpool) `We’ is Ed Hinds and the experiment at ICL using YbF (ytterbium monofluoride), see talk by Ben Sauer on Tuesday

d(muon) < 1.9× d e.cm Current status of EDMs d(proton) < 5× d(electron) < 1× neutron : Left-Right MSSM Multi Higgs electron: d(neutron) < 3× YbF Slide thanks to Ed Hinds (from his 2013 talk in Liverpool)

LDMs: Punchline Flavour Conserving: Interaction with E and B fields: g-2: EDM: is CP-violating and very small within the SM (from quark CKM in 4-loop diagrams, larger from Maj. ν's) Flavour Violating: Also and `conversion’, all procs. have similar diagrams EDM or CLFV measurement ≠ 0 would be a clear signal for NP EDM or CLFV measurement ≠ 0 would be a clear signal for NP

Magnetic Moments g-factor = 2(1+a) for spin-½ fermions anomaly calculable in PT for point-like leptons and is small as α/π suppressed, Schwinger’s leading QED contribution For nucleons corrections to g=2 come from sub-structure and are large, can be understood/parametrised within quark models Experimental g values: (g>2  spin precession larger than cyclotron frequency) e: (56) [ Harvard 2008] μ: (13) [ BNL E821] τ: g compatible with 2, < a τ < [DELPHI at LEP2, [similar results from L3 and OPAL, ] p: (46) n: (90) Let’s turn to the TH predictions for a e and a μ (SM, BSM covered by Dominik Stoeckinger)

Magnetic Moments: a e vs. a μ a e EXP more than 2000 times more precise than a μ EXP, but for e - loop contributions come from very small photon virtualities, whereas muon `tests’ higher scales dimensional analysis: sensitivity to NP (at high scale Λ NP ):  μ wins by for NP, but a e provides best determination of α a e = (0.28) [0.24ppb] a μ = (63) [0.54ppm] Hanneke, Fogwell, Gabrielse, PRL 100(2008) Bennet et al., PRD 73(2006) one electron quantum cyclotron

Magnetic Moments: a e SM General structure: Weak and hadronic contributions suppressed as induced by particles heavy compared to electron, hence a e SM dominated by QED  Kinoshita-san’s review a e SM = (77) × [Aoyama+Hayakawa+Kinoshita+Nio, PRL 109(2012)111807] including 5-loop QED and using α measured with Rubidium atoms [α to 0.66 ppb] [Bouchendira et al., PRL106(2011)080801; Mohr et al., CODATA, Rev Mod Phys 84(2012)1527] Of this only a e had, LO VP = 1.875(18) × [or our newer 1.866(11) × ] a e had, NLO VP = (5) × [or our newer (1) × ] a e had, L-by-L = 0.035(10) × a e weak = (5) × , whose calculations are a byproduct of the μ case which I will discuss in a bit more detail. In turn a e EXP and a e SM can be used to get the most precise determination of α, to 0.25 ppb, consistent with Rubidium experiment and other determinations.

Magnetic Moments: a μ g-2 history plot and book motto from Fred Jegerlehner: `The closer you look the more there is to see’

a μ : Charge from new EXPs for the TH prediction Future picture: - if mean values stay and with no a μ SM improvement: 5σ discrepancy - if also EXP+TH can improve a μ SM `as expected’ (consolidation of L-by-L on level of Glasgow consensus, about factor 2 for HVP): NP at 7-8σ - or, if mean values get closer, very strong exclusion limits on many NP models (extra dims, new dark sector, xxxSSSM)…

a μ SM : overview and SM status

a μ QED Kinoshita et al: g-2 at 5-loop order T. Aoyama, M. Hayakawa, T. Kinoshita, M. Nio (PRLs, 2012) A triumph for perturbative QFT and computing!

a μ QED Schwinger 1948: 1-loop a = (g-2)/2 = α/(2π) = × loop graphs: 72 3-loop and loop diagrams … Kinoshita et al. 2012: 5-loop completed numerically (12672 diagrams) Some graphs known analytically (Laporta; Aguilar et al.) Recently several independent checks of specific 4-loop and 5-loop diagrams: Steinhauser et al. [ ] and Baikov et al. [NPB 877 (2013) 647] confirm Kinoshita’s results Ongoing attempt to check all 4-loop graphs independently So far no surprises, QED very accurate and stable: ✓

a μ Electro-Weak Electro-Weak 1-loop diagrams: a μ EW(1) = 195× known to 2-loop (1650 diagrams, the first EW 2-loop calculation): Czarnecki, Krause, Marciano, Vainshtein; Knecht, Peris, Perrottet, de Rafael agreement, a μ EW relatively small, 2-loop relevant: a μ EW(1+2) = (154±2)× Higgs mass now known, update by Gnendiger+Stoeckinger+S-Kim, PRD88(2013) a μ EW(1+2) = (153.6±1.0)× ✓ compared with a μ QED = (80) ×10 -11

a μ SM : overview; hadronic Light-by-Light QED: Kinoshita et al. 2012: 5-loop completed (12672 diags) [some 4-l checks] ✓ EW: 2-loop (and Higgs mass now known) ✓ Hadronic: non-perturbative, the limiting factor of the SM prediction ✗ L-by-L: - so far use of model calculations, form-factor data will help improving, - also lattice QCD, and - new dispersive approach  talks by Vainshtein, Vanderhaegen, Blum

a μ SM : Hadronic Light-by-Light (I) Hadronic: the limiting factor in the SM prediction L-by-L: non-perturbative, impossible to fully measure ✗ so far use of model calculations, based on large N c limit, Chiral Perturbation Theory, plus short distance constraints from OPE and pQCD meson exchanges and loops modified by form factor suppression, but with limited experimental information: in principle off-shell form-factors (π 0, η, η ’, 2π  γ * γ * ) needed at most possible, experimentally: π 0, η, η ’, 2π  γγ * additional quark loop, double counting? theory not fully satisfying conceptually 

a μ SM : Hadronic Light-by-Light (II) Status: Not as bad as sometimes claimed… several independent evaluations, different in details, but good agreement for the leading N c (π 0 exchange) contribution, differences in sub-leading bits Mostly used recently: - `Glasgow consensus’ by Prades+deRafael+Vainshtein: a μ had,L-by-L = (105 ± 26) × compatible with Nyffeler’s a μ had,L-by-L = (115 ± 40) × also agrees with several constituent-quark based estimates (no room for a much larger contribution) calculations based on Dyson-Schwinger methods indicate possibility for increased L-by-L contribution, but so far no complete result and method regarded as problematic by many (`exact’ but after specific truncation to ladder-like diagrams)

a μ SM : Hadronic Light-by-Light (III) Prospects: difficult to predict, but… Transition FFs can be measured by KLOE-2 and BESIII using small angle taggers: + better π 0  γγ life-time measurements (also from PrimEx at JLab),  will lead to better model constraints, New dispersive approach promising (see talk Vanderhaegen) Ultimately: `First principles’ full prediction from lattice QCD+QED - first results encouraging, proof of principle (Blum et al.) - several groups: USQCD, UKQCD, ETMC, … much increased effort and resources - within 3-5 years a 10% estimate may be possible, 30% would already be useful Conservative prediction: we will at least be able to defend/confirm the error estimate of the Glasgow consensus, but possibly bring it down significantly. ✓

a μ SM : overview; Hadronic Vacuum Polarisation QED: ✓ EW: ✓ Hadronic: the limiting factor of the SM prediction ✗ HVP: - most precise prediction by using e + e - hadronic cross section (+ tau) data and a dispersion integral - done at LO and NLO (see graphs) - recently even at NNLO [Steinhauser et al, ] a μ HVP, NNLO = × alternative: lattice QCD, but: need also QED corrections; systematics?

a μ SM : overview, numbers Several groups have produced hadronic compilations over the years. Here: Hagiwara+Liao+Martin+Nomura+T Many more precise data in the meantime and more expected for near future At present HVP still dominates the SM error

Hadronic Vacuum Polarisation, essentials: Use of data compilation for HVP: How to get the most precise σ 0 had ? e + e - data: Low energies: sum ~ 25 exclusive channels, 2π, 3π, 4π, 5π, 6π, KK, KKπ, KKππ, ηπ, …, use iso-spin relations for missing channels Above ~1.8 GeV: can start to use pQCD (away from flavour thresholds), supplemented by narrow resonances (J/Ψ, Υ) Challenge of data combination (locally in √s): from many experiments, in different energy bins, errors from different sources, correlations; sometimes inconsistencies/bias σ 0 had means `bare’ σ, but WITH FSR: RadCorrs [ HLMNT: δa μ had, RadCor VP+FSR = 2 × !] traditional `direct scan’ (tunable e + e - beams) vs. `Radiative Return’ [+ τ spectral functions]

Aside: Hadronic VP for running α(q 2 )

HVP: Data `puzzle’ in the π + π - channel Radiative Return data in the combined fit of HLMNT 11 Note: a μ ππ, w/out Rad Ret = ± 3.3 BUT a μ ππ, with Rad Ret = ± 3.0  i.e. a shift of +5.5 in HLMNT [DHMZ: a μ ππ even higher by 2.1 units] 2π fit: overall χ 2 min /d.o.f. ~ 1.5 needs error inflation, limited gain in error New KLOE12 data confirm this tension   More in talk of Achim Denig

Another `puzzle’: Use of tau spectral function data? Use CVC (iso-spin symmetry) to connect spectral functions to but have to apply iso-spin corrections Early calculations by Alemany, Davier, Hoecker: use of τ data complementing e + e - data originally resulted in an improvement w.r.t. use of e + e - data alone; discrepancy smaller with tau data; later increased tension between e + e - and τ Recent compilation by Davier et al (Fig. from PRD86, ) : Jegerlehner+Szafron: crucial role of γ-ρ mixing: They found discrepancy gone but τ data improves e + e - analysis only marginally Analyses by Benayoun et al: combined fit of e + e - and τ based on Hidden Local Symmetry (HLS): no big tension betw. e + e - and τ, but w. BaBar, hence not used; increased Δa μ: of >≈ 4.5σ Davier+Malaescu refute criticism, claim fair agreement betw. BaBar and their τ comp. HLMNT: stick to e + e - (and do not use τ data). With e + e - (incl. BaBar) discrepancy of 3-3.5σ

σ had at higher energies; 2011 status to be improved soon Exclusive data better now mainly due to many Radiative Return data from BaBar Latest BES data (blue markers) in perfect agreement w. pQCD; data-based a μ incl > a μ pQCD Different data and data vs. pQCD choices give slightly different a μ (within errors) Inclusive vs. sum of exclusive Inclusive data or perturbative QCD R(s) More from BESIII soon! More from SND, CMD3, Belle, BaBar, BESIII

a μ HVP, LO different comps. a μ SM status: Recent `history’ Fair agreement between different e + e - analyses, including recent updates: (all numbers in ) HLMNT (11): ± 3.7 (exp) ± 2.1 (rad) Jegerlehner (11): ± 4.7 Davier et al (11): ± 4.2 The `extremes’ (both with τ data): Davier et al (11): ± 4.7 (+ ~ 1.5 shift from their 2013 τ re-analysis ) Benayoun et al (12): ± 4.5 New data available already do not shift the mean value strongly, but are incrementally improving the determination of a μ HVP

σ had : recent new data KLOE π + π - data with σ μμ normalisation: confirm previous KLOE measurements will not decrease tension with BaBar once included in next round of `global’ σ had compilations, but slightly increase significance of KLOE Open question: Why are BaBar’s data so different from KLOE’s? Are there any issues with the MCs or analysis techniques used? PLB720(2013)336

σ had : recent new data: K + K - (γ) from BaBar PRD 88(2013)3, a μ = ± 0.18 ± 0.22 up to 1.8 GeV vs ± 0.27 ± 0.68 for combined previous data significant shift up, error down?! may need to use mass shifts or ΔE for best combination; m φ = ? Comp. plots BaBar vs Novosibirsk:

σ had : recent new data: 2π + 2π - (γ) from BaBar PRD85(2012) shift of +0.3 × for a μ error down to a third combination?

σ had : recent new data from Novosibirsk CMD-3 6π charged, PLB723(2013)82 solid black: CMD-3, open green: BaBar full analysis will include 2(π + π - π 0 ) SND ωπ 0, PRD88(2013) many more analyses reported with preliminary results, incl. 3π, 4π(2n) looking forward to rich harvest from SND and CMD-3

Future improvements for a μ HVP : Most important 2π: - close to threshold important; possible info also from space-like - better and more data - understand discrepancy between sets, especially `BaBar puzzle’ - possibility of direct scan & ISR in the same experiment(s) √s > 1.4 GeV: higher energies will improve with input from SND, CMD-3, BESIII, BaBar With channels more complete, test/replace iso-spin corrections Very good prospects to significantly squeeze the dominant HLO error! Pie diagrams from HLMNT 11: Can expect significant improvements: 2π: error down by about 30-50% subleading channels: by factor 2-3 √s > 2 GeV: by about a factor 2  I believe we can half the HVP error in time for the new g-2

Extras

HVP: Data `puzzle’ in the π + π - channel Radiative Return (ISR) data compared to 2π fit w/out them New KLOE12 data confirm this tension Note: a μ ππ, w/out Rad Ret = ± 3.3 BUT a μ ππ, with Rad Ret = ± 3.0

Data combination in π + π - : an elephant’s weight Weighting factors from Davier et al. [DHMZ EPJC71(2011)1515]

π + π - : HLS fit-based results from M Benayoun et al. Results for g-2 and the discrepancy as presented by Benayoun at the Mainz meeting April 2014 MB: Preferred fits discard BaBar 2pi data (red framed)

π + π - : big difference betw. HLMNT & Benayoun et al. Taking only direct scan as baseline: Benayoun et al: -3.1 from HLS-based fit, -4.3 from KLOE10+12 HLMNT: +5.5 from KLOE and BaBar (compared to scan only) So the big difference (~13×10 -10, 3.3  5σ) comes to a big part from the data input, i.e. if BaBar’s 2π is used or not. (If used: error relatively poor despite stats due to inflation) Future SND, CMD-3, BELLE and BESIII 2π data may dilute the strong significance of BaBar [also more data from BaBar to be analysed!] Ideally find out why the different data sets are not consistent. If this could be achieved the 2π channel would be great!

Channels with biggest errors. PQCD at 2 GeV?