VOLUME 42, NUMBER 17 PHYSICAL REVIEW LETTERS 23 APRIL 1979 Effect of Earth's Rotation on the Quantum Mechanical Phase of the Neutron S. A. Werner and J . - L . Staudenmann Physics Department and Research Reactor Facility, University of Missouri-Columbia, Columbia, Missouri 65211 and R. Colella Physics Department, Purdue University, West Lafayette, Indiana 47907 (Received 6 February 1979) Using a neutron interferometer of the type first developed by Bonse and Hart for x rays, we have observed the effect of Earth's rotation on the phase of the neutron wave function. This experiment is the quantum mechanical analog of the optical interferometry observations of Michelson, Gale, and Pearson. In 1925 Michelson, Gale, and Pearson1 carried out a remarkable experiment designed to detect the effect of Earth's rotation on the speed of light. Using an interferometer in the form of a rectangle of the size 2010 ftx 1113 ft they were able to detect a retardation of light due to Earth's rotation corresponding to about i of a fringe, in agreement with the theory of relativity. An experiment demonstrating that angular rotation could be detected by optical interf erometry was carried out earlier by Sagnac.2 In view of the differences in the coordinate transformation properties of light waves and matter waves, it is not obvious that an analogous quantum mechanical effect should exist for neutrons. We find that it does. A schematic diagram of our experiment is shown in Fig. 1. We use a perfect-silicon-crystal interferometer of the type first developed for x rays by Bonse and Hart.3 The first demonstration that such a device could be used for neutrons was achieved by Rauch, Treimer, and Bonse.4 In this experiment a nominally monoenergetic neutron beam of wavelength X = 1.262 A is reflected vertically by a beryllium crystal. This beam passes through a collimator and subsequently through a 7-mm-diam cadmium aperture onto the interferometer. The beam incident on the interferometer is coherently split in the first Si-crystal slab at point A by Bragg reflection from the (220) lattice planes. The two resulting beams are coherently split again in the second Si slab near points B and C. Two of these beams are directed toward point D in the third Si slab, where they overlap and interfere. The outgoing interfering beams are detected in two 3He proportional detectors, labeled Cx and C2 in Fig. 1. If the beam traversing the path ACD is shifted in phase by an angle /3 relative to the beam traversing the path ABD, it can be shown5 that the expected intensi- ties observed at detectors Cx and C2 are I1 = a(l + cos/3) (la) and I2=y - a COS/3. (lb) The constants a and y depend on the incident flux. The perfect contrast predicted by these equations is never exactly realized in practice. In this experiment we have observed a phase shift /3 of the neutron wave function, which we will call j3Sagnac> resulting from the rotation of Earth. According to the theory developed below, this phase shift phase shifter collimator^] beam from L^ monochromator- V/ff/f ™] Be crystal FIG. 1. Schematic diagram of the apparatus. The drawing is not to scale. The collimator is approximately 1 m in length and the interferometer is approximately 8 cm long from point A to point D. The angle 6 of the phase-shifting slab is zero when it is parallel to the three interferometer slabs. © 1979 The American Physical Society 1103 VOLUME 42, NUMBER 17 PHYSICAL REVIEW LETTERS 23 APRIL 1979 should be given by 0 Sag n a c = ( 4 ^ &)£>• A, (2) where m{ is the inertial mass of the neutron, h is Planck's constant, oS is the angular rotation velocity of Earth, and A is the normal area of the parallelogram enclosed by the beam paths ABDCA in the interferometer. By turning the interferometer through an angle cp about the vertical incident beam direction AB, the dot product 3 • A will change, giving rise to a change in intensity prescribed by Eqs. (1). The formula (2) was obtained by Page6 using wave-optical arguments, and by Anandan7 and Stodolsky8 within the framework of general relativity. Because this experiment is done on the surface of rotating Earth, a noninertial frame, the Hamiltonian governing the neutron's motion will involve a third term in addition to the kinetic energy and the gravitational potential energy. According to standard classical mechanics, the appropriate Hamiltonian for the neutron is H=p2/2mi +mgg*r-<5* L, (3) where p is the canonical momentum of the neutron, L = f x p is the angular momentum of the neutron's motion about the center of Earth (r = 0), mg is the gravitational mass of the neutron, and g is the acceleration due to gravity. Using Hamilton's equations, one finds that the canonical momentum is p=mir+micoXr, (4) where r is the neutron velocity in a frame fixed to Earth. We now assume that (3) is also the correct quantum-mechanical Hamiltonian in the frame of rotating Earth, and that we can use (4) and the de Broglie relation p = /zk (5) to give the neutron wave properties specified by the wave vector £. Within the WKB approximation, the difference in phase accumulated on the path ACT) relative to ABD is then p=$£*dr = (l/K)f:p-dr. (6) This line integral along the path ABCDA around the interferometer gives two terms resulting from the two terms in (4) : " Pgrav + PSagnac' (7) The first term formed the basis of the analysis of our earlier experiments9 on gravitationally in- duced quantum interference, and the second term is given by Eq. (2). The difficulty in observing the phase shift ^sagnac is that its maximum value is only of order 2% of the maximum value of p^av for thermal neutrons. However, for an incident beam which is precisely vertical (along a plumb line), 0 ^ is independent of the interferometer rotation angle cp. For this orientation, the phase shift due to Earth's rotation can be easily worked out from Eq. (2); it is £sagnac= (47TW *//* )cM SitiOL Sin(
1. Specifically, I propose that the excitations commonly associated with 1^1 arise as the consequence of a simultaneity condition involving the pairwise masses of all four qq combinations. In order to understand this condition, we first consider Fig. 1(a), which depicts three mesons mx, m2, and m3 resonating in pairs to produce particles A {m1m2) and B {mxm^ simultaneously. This can occur only if the invariant three-body mass takes on a particular value M0 determined by the masses of A9 B, and the three mesons. Almost a generation back, Peierls noted the sharp. energy dependence of this effect, and proposed that it could be responsible for generating the JW*(1512).2 Others extended Peierls's treatment to produce excellent predictions for the masses of theAlf Q, a n d £ mesons. Physically, there is nothing strange about this effective "force"; for example, in the singly ionized hydrogen molecule, molecular binding is produced by exactly such an (exchange) mechanism. Mathematically, the realization of this effect involves some subtleties. I recently noted that past technical objections to the sheet structure3 can be eliminated by restating the condition as follows. Consider particles mx and m3 to form again resonance B, but take particles m2 and m3 to be relatively at rest. The related singularity is now on the correct sheet, and is guaranteed to be strong in the limit that B has zero width.4 Moreover, if particles m2 and m3 are identical, the Peierls kinematic condition is simultaneously satisfied in the same limit. The restriction to <°> (b) FIG. 1. (a) Three-meson system with pairs forming resonances A and B. (b) Four-quark system with pairs forming mesons a, b9 and c. The pair q3 and qA are relatively at rest. 1106 © 1979 The American Physical Society