When the detectors are turned on, the photon is determined to go through exactly one of the slits/paths, and the interference pattern disappears. If the detectors are turned off, the interference pattern reappears. The reason that this experiment is significant is that to-date, any experiment that attempted to extract which-path (or which-slit) information from the photons or electrons traveling through the slit would destroy the interference pattern. Nevertheless, the researchers have provided an interesting new way to approach the wave-particle duality. Similarly, building up the interference pattern requires moving the D2 detector away from the slits, meaning that D1 provides the only information about the trajectory. While these results seem to violate that principle, it's the TEM 01 mode of the laser that allows the determination of which opening an individual photon passes through. In the traditional way of thinking, the particle and wave natures of photons cannot be accessed simultaneously. Ultimately, this experiment is an intriguing new addition to the literature on the wave-particle duality. When they used a laser with a single maximum, they lost the ability to determine which opening an individual photon passed through. It's the TEM 01 beam structure that allowed the simultaneous measurement of the wave-like interference pattern and the particle-like path through one of the slits. In this position, it measured the complete interference pattern produced by the single photons. Then D2 was pulled far enough away from the slits for the photons to interfere. This was used to confirm that the entanglement measurements matched up with the ones from the detector. First, D2 was placed right next to the slits, so it was able to tell which the signal photon went through. The researchers used a second counter, called D2, to reveal the final position of the signal photon. D1 revealed which slit the signal photon went through, thanks to the combination of entanglement and the TEM 01 double maximum structure. One photon (known as the signal) was sent through the double slits, while the second (the idler) passed to a photon counter, labeled D1. Both of these photons still had the double-maximum structure of the TEM 01 mode and, since they were entangled, any measurement on one will tell us something about the other. Before reaching the openings, the laser was directed onto a crystal of beta barium borate (BBO), which reemits light in two complementary polarization states, leaving the pair of photons entangled. Advertisementīut you wouldn't necessarily know which of the slits the photon went through-determining that required an additional step. (The researchers tested this using a special detector, similar to the technology in digital cameras.) Thus, an individual photon should pass through either one or the other slit, based on which intensity maximum it is in. The beam of photons was directed onto a double slit so that each of the points of maximum intensity were more or less aligned with one of the openings. The "01" means there are two distinct points of maximum intensity.įrom a quantum mechanical point of view, a single photon from this source is a combination of two quantum states superposed, so a measurement will find a photon preferentially in one or the other of these intensity maxima with equal probability. The researchers started with a laser in a configuration known as TEM 01 mode, which means the electric (E) and magnetic (M) fields are perpendicular (or transverse, T) to the direction the photons travel. The key to the experiment is the particular state in which the photons were produced. The entanglement enabled them to determine which opening the photon went through, but a detector on the other side still picked up an interference pattern, demonstrating light's wave- and particle-like characteristics simultaneously. Schleich entangled two photons and allowed one to pass through a barrier with two slits. However, Ralf Menzel, Dirk Puhlmann, Axel Heuer, and Wolfgang P. Typically, the particle nature and the wave nature have to be observed separately if you track the particles through a single slit, the interference pattern vanishes. Amazingly, this also works if you send the particles through one at a time-the interference pattern builds up slowly as more particles go through. The double-slit experiment has been replicated with photons, electrons, atoms, and even entire molecules. The subtlest experiment in quantum mechanics is also one of the simplest: send a stream of particles through two openings in a barrier, and you'll produce an interference pattern because the particles act as waves.
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