14–15 Mar 2024
Okayama University
Asia/Tokyo timezone

Magnetic field studies using electron plasmas for gravitational experiments with antihydrogen

15 Mar 2024, 11:05
25m
Lecture Hall (OUX)

Lecture Hall

OUX

Speaker

Adam Powell (University of Calgary)

Description

"The hydrogen atom has been studied extensively throughout history and provides the most precisely measured systems in physics. Antihydrogen has a significantly shorter history of study but no less potential for precision physics measurements. Comparisons between hydrogen and antihydrogen then offer the possibility to test fundamental symmetries such as charge, parity, time (CPT) invariance at high precision.

The antihydrogen laser physics apparatus (ALPHA) at CERN produces and traps antihydrogen atoms in a magnetic minimum for study and testing of fundamental symmetries. The latest venture for the ALPHA collaboration has been a new experiment, ALPHAg, aiming to observe the motion of antimatter in Earth’s gravitational field for the first time. As CPT makes no assertion about the motion of antimatter in Earth’s gravitational field this is a test of the equivalence principle.

Antihydrogen atoms are confined in a vertical magnetic minimum trap, the trapping potential is then different between the top and bottom of the trap by -mgΔh, where m is the antihydrogen mass, g is the gravitational acceleration and h is the height. When the vertical confining field is then removed during a slow magnetic release, antihydrogen escape in a direction favouring the gravitational acceleration. The difference in trapping potential is equivalent to a magnetic field difference of approximately 4× 10^(-4) T. The magnetic field is changed from 1.7 T to 1 T over 20 seconds during the release, it is therefore necessary to control and measure the magnetic fields at the ends of the magnetic trap to a higher precision than the gravitational potential difference.

I will discuss the systematic studies of these magnetic fields using electron plasmas [1] in ALPHAg that enabled the first determination of the gravitational acceleration of antihydrogen, a_g ̅ = (0,75 ± 0,13 (stat. + syst.) ± 0,16 (simulation))g where g = 9.81 m/s2 [2].

[1] Electron cyclotron resonance (ECR) magnetometry with a plasma reservoir, E. D. Hunter ; A. Christensen ; J. Fajans ; T. Friesen ; E. Kur ; J. S. Wurtele Phys. Plasmas 27, 032106 (2020)

[2] Observation of the effect of gravity on the motion of antimatter, The ALPHA collaboration, Nature volume 621, pages716–722 (2023)"

Presentation materials