Misha Brodsky: Decoherence of polarization entanglement in optical fibers

Thursday, August 25, 2011 12:00 pm - 1:00 pm EDT (GMT -04:00)

Misha Brodsky, AT&T Labs

Abstract

Quantum mechanics permits the existence of unique correlations, or entanglement, between individual particles. The ability of entangled particles to act in concert is preserved even when they are separated by large distances and thus serves as a resource for numerous applications. For example, distributing entangled photon pairs between remote parties potentially enables secure communication or could offer the possibility of interconnecting quantum computers. The vast transparency band of the installed global fiber-optic network, consisting of over a Gigameter of optical fiber cables, presents a particularly attractive opportunity for this task. The bond between entangled photons is, however, very fragile and could be lost.

Several physical phenomena set limitations on transmission of classical light pulses through optical fibers. An intriguing and crucial question is how some of these well-studied phenomena, for instance Polarization Mode Dispersion (PMD), arising from inherent defects and miniscule imperfections in fibers,
affect a polarization entangled photon pair. How far could one send entangled photons while still maintaining the connection between them?

We investigate, theoretically and experimentally, PMD-induced degradation of entanglement between two photons transmitted over fibers. We show that the loss of entanglement could be either gradual or surprisingly abrupt. In addition, we point to cases in which the adverse effect of fiber propagation could be self compensated. Finally, we define the range of fiber parameters over which entanglement remains sufficient for secure communication. The richness of the observed phenomena suggests that fiber-based entanglement distribution systems could serve as natural laboratories for studying entanglement

Biography
Dr. Misha Brodsky joined AT&T Labs in 2000. His contributions to fiber optic communications focused on optical transmission systems and physics of fiber propagation, most notably through his work on polarization effects in fiber-optic networks. More recently Misha has been working on quantum communications; single photon detection; where his prime research interest is in photon entanglement and entanglement decoherence mechanisms in optical fibers.

Dr. Brodsky has authored or co-authored over 70 journal and conference papers, a book chapter and about two dozen patent applications. He is a topical editor for Optics Letters and has been active on numerous program committees for IEEE Photonics Society and OSA conferences. Dr. Brodsky holds a PhD in Physics from MIT.