The quantum entanglement of three electrons, using an ultrafast optical pulse and a quantum well of a magnetic semiconductor material, has been demonstrated in a laboratory at the University of Michigan, marking another step toward the realization of a practical quantum computer. While several experiments in recent years have succeeded in entangling pairs of particles, few researchers have managed to correlate three or more particles in a predictable fashion. From the University of Michigan :
Michigan researchers achieve quantum entanglement of three electrons
ANN ARBOR, Mich.— The quantum entanglement of three electrons, using an ultrafast optical pulse and a quantum well of a magnetic semiconductor material, has been demonstrated in a laboratory at the University of Michigan, marking another step toward the realization of a practical quantum computer. While several experiments in recent years have succeeded in entangling pairs of particles, few researchers have managed to correlate three or more particles in a predictable fashion.
The results were presented in an article on Nature Materials’ web site on February 23 and will appear in the March 4 issue of Nature Materials, titled “Optically induced multispin entanglement in a semiconductor quantum well.” Authors of the paper are Jiming Bao, Andrea V. Bragas, Jacek K. Furdyna (University of Notre Dame), and Roberto Merlin.
Entanglement, which is essential to the creation of a quantum computer, is one of the mysterious properties of quantum mechanics that contradicts the notions of classical realism. Quantum computers will be able to perform highly complex tasks that would be impossible for a classical computer, at great speed.
Briefly, entanglement describes a particular state of a set of particles of energy or matter for which correlations exist, so that the particles affect each other regardless of how far apart they are. Einstein called it “spooky action at a distance.” We know that we must be able to harness entanglement in order to develop the quantum gates necessary for storing and processing information in practical quantum computers. These devices will offer enormously enhanced computing power that would permit extremely fast ways to solve certain mathematical problems, such as the factorization of large numbers.
The Michigan team, which has been working on the problem for several years, used ultrafast (50-100 femtosecond) laser pulses and coherent techniques to create and control spin-entangled states in a set of non-interacting electrons bound to donors in a CdTe quantum well. The method, which relies on the exchange interaction between localized excitons and paramagnetic impurities, could in principle be used to entangle an arbitrarily large number of spins.
In the presence of an external magnetic field, a resonant laser pulse creates localized excitons (bound electron-hole pairs) of radius ~ 0.005 microns in the CdTe well. Electrons bound to donor impurities within that radius feel the presence of the exciton in such a way that they became entangled after the exciton is gone. The process involves resonant Raman transitions between Zeeman split spin states. In the experiments, the signature of entanglement involving m electrons is the detection of the mth-harmonic of the fundamental Zeeman frequency in the differential reflectivity data.
“The community is trying various approaches to achieve controllable interactions between qubits. We’ve seen a variety of proposed solutions from atomic physicists involving trapped ions and atoms and even ‘flying qubits’ based on light,” said Merlin. “Solutions based on semiconductor technology, like ours for example, may well hold more promise for practical implementation when combined with advances in nanotechnology.”
The experiments have so far involved a large ensemble of sets of 3 electrons. “Our procedure is potentially set-specific and scalable, which means that it shows definite promise for quantum computing applications,” Merlin said. Cryptography is expected to be one of the first such applications.
The research was conducted at OPIL (Optical Physics Interdisciplinary Laboratory), a laboratory of the FOCUS (Frontiers in Optical Coherent and Ultrafast Science) Center of the University of Michigan and funded by ACS Petroleum Research Fund, NSF (National Science Foundation) and the AFOSR (Air Force Office of Scientific Research) through the MURI (Multidisciplinary University Research Initiative) program.
To read the entire paper, go to http://dx.doi.org/10.1038/Nmat839 or send an email to [email protected]. For more information about the University of Michigan’s FOCUS Center, see http://www.umich.edu/~focuspfc/main.html.
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