WebAug 14, 2014 · We now see that all such elements move in circles with radius x = 2 R sin ( θ 2). So the magnetic field due to all such elements will be pointing out of the plane. We also note that the velocity and x are always perpendicular. Therefore, the magnetic field due to that element at point P d B → = μ o 4 π d q v x 2 = μ o 4 π ω d q x WebThe geometry allows for a very uniform magnetic field to be established in the ring. Muon g − 2 (pronounced "gee minus two") is a particle physics experiment at Fermilab to measure the anomalous magnetic dipole moment of a muon to a precision of 0.14 ppm, [1] which will be a sensitive test of the Standard Model. [2]
8.4: Magnetic Properties and the Zeeman Effect
WebApr 7, 2024 · The magnet’s main components are a combination of iron chunks and superconducting coils that produce a vertical field inside the muon storage ring—a 45-m-long circular path tucked within the magnet’s metal structure. The field steers the muons along a circular path, while also causing their magnetic moments to wobble, or precess. http://hyperphysics.phy-astr.gsu.edu/hbase/magnetic/magmom.html research schedule 怎么写
Magnetic moment - Wikipedia
WebApr 7, 2024 · The basic idea of the Muon g − 2 experiment at Fermi National Accelerator Laboratory (Fermilab), Illinois, is to detect the wobbles of microscopic magnets traveling … Web460 GHz (electron), 700 MHz (1H) NMR. 250 GHz (electron), 380 MHz (1H) NMR. 140 GHz (electron), 211 MHz (1H) NMR. Pulsed EPR spectrometers: 140 GHz (electron) 9 GHz … WebThe problem is to prove that the magnetic dipole moment of a spherical ball of mass m and charge Q, whose charge is distributed uniformly only on its surface, rotating about its center, is equal to μ → = 5 Q 6 m L →. My reasoning is this: We know the formula for the dipole moment in terms of the surface charge density K, which is research.schmc.ac.kr