Fundamental physics with antihydrogen and antiprotons at the AD. Michael Doser CERN

Fundamental physics with antihydrogen and antiprotons at the AD Michael Doser CERN

What measurements are we talking about? 1) Precise spectroscopic comparison between H and H tests of fundamental symmetry (CPT) 2) Measurement of the gravitational behavior of antimatter tests of the Weak Equivalence Principle 3) other measurements in antihydrogen(-like) systems positronium, protonium, antiprotonic helium,...

Experiments at the AD (antiprotons and antihydrogen) Spectroscopy Gravity ALPHA ASACUSA AEgIS GBAR ATRAP ACE Matter-Antimatter interactions BASE... Symmetries... Antimatter manipulations

ATRAP & BASE DiSciacca, J. et al. One-particle measurement of the antiproton magnetic moment. Phys. Rev. Lett. 110, 130801 (2013) S. Ulmer. et al. Nature 524,196 199 (13 August 2015) All measured antiproton-to-h cyclotron frequency ratios as a function of time spin line cyclotron line. (q/m) p /(q/m) p 1 = 1(69) x 10-12 μp/μp = 1.000 0000.000 005 (factor 6 improvement by BASE in 2017)

ASACUSA results (phe+ spectroscopy) rmation Energy (a.u.) + He p By comparing the calculated and experimental phe+ frequencies, the ratio Mp/me can in principle be determined to a fractional precision of <1 10 10 ++ Ionized phe I0 = 0.90 a.u. (24.6 ev) He capture Auger decay - e p 38 Stark mixing ++ He 0 He 37 3.0 35 Radiative 33 e He Nuclear absorption & Annihilation Energy (a.u.) 2.0 39 40 41 42 M *~ 38 n0 = m e 36 34 + 2.0 32 31 characteristics of both atom and molecule 0(s) transitions + Neutral phe l M.n Hori et al., Science 04 Nov 2016: Vol. 354, Issue 6312, pp. 610-614 DOI: 10.1126/science.aaf6702 30 ++ Ionized phe I0 = 0.90 a.u. (24.6 ev) Auger decay 38 Stark mixing 0 He 39 37 36 35 Radiative 3.0 34 33 Nuclear absorption & Annihilation 41 42 M *~ 38 n0 = m e n 32 31 0(s) transitions + Neutral phe 40 l 30 example: antiprotonic helium 52 Combining with ATRAP/BASE: Δ(mp,mp), Δ(qp,qp) < 5 10 10 (90% CL)

Beam formation ASACUSA beam (2014) H ground state hyperfine splitting: N. Kuroda et al., Nature Communications 5, Article number: 3089 (2014) doi:10.1038/ncomms4089 Rate: few atoms/hour p e+ Rydberg states? Many still in n>29 Velocity? T~ 100K-1000K? Cusp trap Microwave Sextupole Cavity Magnet H Det. 2. A conceptual experimental setup for the ground-state transition M. Diermaier et hyperfine al., In-beam measurement of the hydrogen hyperfine splitting ents of H atoms with the cusp trap (see the text for more details). (a) TBR: Formation Guiding coils - towards antihydrogen spectroscopy https://arxiv.org/abs/1610.06392 3D track Focusing detector of low-field. det p a seekers r H t sp cu r lato u cum + ac e p tra (b) Under reasonable assumptions & measuring both transitions to extrapolate to zero field H superconducting -9) appears possible measurement to O(10 cusp magnet (with a rate of ~ 1Hz of ground-state atoms)

Antihydrogen production processes 5 7 10 ~10 p 8 10 10 ~10 e+ radiative recombination γ TBR: 3-body recombination e + RCE: Resonant charge exchange e - Ps* very low rate

Antihydrogen production processes TBR: RCE: 3-body recombination e + ALPHA ATRAP AEgIS GBAR Resonant charge exchange e - Ps* ASACUSA p e + Temperature (Te+) Rate ~ Rate (trappable) n (if trapped) Temperature Tp Rate ~ Rate (nps,vps) n (if trapped or slow)

ALPHA results (trapping, 1s-2s spectroscopy) G. B. Andresen et al., Nature 468, 673 676 (02 December 2010) M. Ahmadi et al., Nature 541, 506 510 (26 January 2017) surviving fraction: 58% 6% further results: microwave transitions in GS H q(h) < 0.71 x 10-9 e trapping of ~ 10 H simultaneously (similar for ATRAP)

alternative antihydrogen production method: RCE AEgIS TH ~ Tp GBAR e + TPs ~ 100 K Ep ~ 5 kv e + Ps* + p H * + e - cold H * Ps + p H + e - + Ps + H H + e - hot H +

Schematic overview: pulsed horizontal beam of H Schematic overview production: beam charge formation: exchange Stark acceleration measurement: deflectometer e + H* Ps* Ps positronium converter Ps Ps* H* laser excitation H beam [M. K. Oberthaler et al., Phys. Rev. A 54 (1996) 3165] [A. Kellerbauer et al., Phys. Rev. A 54 (1996) 3165] grating 1 grating 2 L L position-sensitive detector H* antiproton trap accelerating electric field atomic beam L L σ a 0 n 4 3 F = - n k E 2 Physics time-of-flight: goals: measurement pulsed of the production gravitational interaction between matter and antimatter, H spectroscopy, beam divergence: ultra-cold p...

Two main challenges: more / colder antiprotons Antiproton decelerator ( 10 13 p @ 26 GeV/c 2 ) AEGIS BASE ALPHA extraction at 5.3 MeV

Two main challenges: more / colder antiprotons current methods for trapping them are quite inefficient ELENA to the rescue GBAR BASE ATRAP I & II ASACUSA space for future (anti)atomic physics experiments ALPHA AEgIS extraction at 100 kev

ELENA is a tiny new decelerator that: dramatically slows down the antiprotons from the AD increases the antiproton trapping efficiency x 100 allows 4 experiments to run in parallel allows new experiments to come in commissioning started in Nov. 2017

Two main challenges: more / colder antiprotons Ultra-cold (~1 µk) Antihydrogen spectroscopy gravity for gravity measurement current lowest p temperature (4.2K) current lowest H temperature (0.5K) (light atom, short wavelength) H atoms in trap @ 8 mk using pulsed Lyman-α I.D.Setija et al., PRL 70 (1993) 2257 1S 2P laser cooling: cw Lyman-α source Eikema, Walz, Hänsch, PRL 86 (2001) 5679

Temperature of produced H 2016 (critical for trapping, gravity measurements) TBR: fraction trapped out of fraction made ~ 10-4 challenge inherent in TBR: e + plasma physics trade-off between # and temperature possible increase in cold H rate by laser-cooling Be + to sympathetically cool e + but is cooling efficient enough to counteract heating through p injection? Outlook: 10 s ~ 100 s of trapped H (through stacking)

very long-term goals: gravity, spectroscopy in sub-mk traps sympathetic cooling to the rescue GBAR experiment cooling of H + Anion cooling for AEgIS: Os, La, C2 cooling of p J.Walz and T. Hänsch, Gen. Rel. and Grav. 36 (2004) 561 formation of H + (binding energy = 0.754 ev) how? perhaps through Ps(2p)+H(1s) H + + e - Roy & Sinha, EPJD 47 (2008) 327 sympathetic cooling of H + e.g. In + 20 μk Warring et al, PRL 102 (2009) 043001 Fischer et al, PRL 104 (2010) 073004 = f 1162.74706(16) nm more than two order 11meV photodetachment at ~6083 cm -1 very weak cooling gravity measurement via TOF TOD best to start at ~ 4K and cool arrow linewidt T D 0.24 µk using the Lyma to Doppler limit ( ) should allow reaching same precision on g as with atoms (10-6 or better)

absolute accuracy (GeV) 10 10 10 10 10 10 10 10 10 10 H-H HFS H-H 1S-2S 0 0 K - K mass p-p mass p-p charge/mass p-p magnetic moment -27-24 -21-18 -15-12 -9-6 -3 0 2013 e mass e charge Motivation: CPT CPT test of EM interaction ATRAP ASACUSA μ g-factor e g-factor d-d mass 3 3 He- He mass 10-27 10-24 10-21 10-18 10-15 10-12 10-9 relative accuracy 10-6 10-3 10 0 CPT test of strong interaction Inconsistent definition of figure of merit: comparison difficult Pattern of CPT violation unknown (P: weak interaction; CP: mesons) Absolute energy scale: standard model extension (Kostelecky)

absolute accuracy (GeV) 10 10 10 10 10 10 10 10 10 10 H-H HFS H-H 1S-2S 0 0 K - K mass p-p mass p-p charge/mass p-p magnetic moment -27-24 -21-18 -15-12 -9-6 -3 0 μ g-factor e g-factor 2015 e mass e charge d-d mass 3 3 He- He mass 10-27 10-24 10-21 10-18 10-15 10-12 10-9 relative accuracy 10-6 10-3 10 0 Inconsistent definition of figure of merit: comparison difficult Pattern of CPT violation unknown (P: weak interaction; CP: mesons) Absolute energy scale: standard model extension (Kostelecky) Motivation: CPT ALPHA ATRAP

absolute accuracy (GeV) 10 10 10 10 10 10 10 10 10 10 H-H HFS H-H 1S-2S 0 0 K - K mass p-p mass p-p charge/mass p-p magnetic moment -27-24 -21-18 -15-12 -9-6 -3 0 μ g-factor e g-factor 2016 e mass e charge d-d mass 3 3 He- He mass 10-27 10-24 10-21 10-18 10-15 10-12 10-9 relative accuracy 10-6 10-3 10 0 Inconsistent definition of figure of merit: comparison difficult Pattern of CPT violation unknown (P: weak interaction; CP: mesons) Absolute energy scale: standard model extension (Kostelecky) Motivation: CPT ASACUSA BASE & ATRAP

absolute accuracy (GeV) 10 10 10 10 10 10 10 10 10 10 H-H HFS H-H 1S-2S 0 0 K - K mass p-p mass p-p charge/mass p-p magnetic moment -27-24 -21-18 -15-12 -9-6 -3 0 μ g-factor e g-factor 2017 e mass e charge d-d mass 3 3 He- He mass 10-27 10-24 10-21 10-18 10-15 10-12 10-9 relative accuracy 10-6 10-3 10 0 Inconsistent definition of figure of merit: comparison difficult Pattern of CPT violation unknown (P: weak interaction; CP: mesons) Absolute energy scale: standard model extension (Kostelecky) Motivation: CPT ALPHA

other measurements with antihydrogen-like atoms & ions... H: charge neutrality... Ps, muonium: gravity (lepton sensitivity) µp: gravity (2 nd generation), antiproton charge radius pp, pd: ions: H + gravity (baryon sensitivity) - Rydberg protonium gravity, CPT (ultra-cold H) ions: H2 +, resp. H2 proton-electron mass ratio μ pn: trapped p + radioisotopes = PUMA

Trapping of antihydrogen: ATRAP and ALPHA: large progress in last years main challenge now: enough cold enough constituents small numbers of antihydrogen atoms in the ground state trapped in 2010 first measurement of 1s-2s to 10-10 in 2016 assuming 1 mk: 1s-2s spectroscopy to ~ 10-12 (perhaps in a few years) Beams of antihydrogen: ASACUSA: continuous beam (ground state atoms!) and phe + AEGIS: working towards pulsed sub-k beam main challenge now: formation mechanisms and rates, cold enough p low precision gravity measurement and in-flight spectroscopy of HFS to 200 Hz (10-6 ) Trapped antiprotons: to summarize the situation... BASE: conceivable reach: (q/m) p /(q/m) p to 10-12, μp/μp to 10-9 From 2017, new low energy p accelerator ELENA: new experiments, experimental opportunities for many years