Recovering the full dimensionality of hyperentanglement in collinear photon pairs

Abstract: Exploiting hyperentanglement of photon pairs, that is, simultaneous entanglement in multiple degrees of freedom(DOFs), increases the dimensionality of Hilbert spaces for quantum information processing. However, generation of hyperentangled photon pairs collinearlly, while produces high brightness, results in a smaller Hilbert space due to the two photons being in the same spatial mode. In this letter, we point out that one can recover the full dimensionality of such hyperentanglement through a simple interfere… Show more

“…Entanglement in these two DOFs can be generated straightforwardly in fiber [10] and nonlinear waveguides [11] via nonlinear processes such as spontaneous parametric downconversion (SPDC) and spontaneous four-wave-mixing (SFWM). While these waveguide-based sources benefit from greater mode confinement (compared to their bulk crystal counterparts) and single spatial-mode emission, this latter property also limits the accessible dimensionality of the hyperentangled photon pairs generated, due to the fact that the two entangled photons are in the spatial mode [12]. Beamsplitter-based techniques have been used for the probabilistic separation of the biphotons to achieve polarization-frequency (PF) hyperentanglement * changjia.chen@mail.utoronto.ca [13], but the hyperentanglement is achieved only after post-selection of coincidence detection, with only 50% probability, limiting its potential for applications such as dense coding.…”

“…In order to deterministically separate the PF hyperentangled biphotons generated from collinearly propagating biphotons without destroying the entanglement in either DOF, one can make use of biphoton interference, specifically, the anti-bunching effect on a beamsplitter or a polarizing beamsplitter [14,15]. Based on the proposed design in our recent work [12], here we present an experimental demonstration of a PF hyperentangled photon-pair source. The photons are generated via a broadband type-II spontaneous parametric down conversion in a periodically-poled silica fiber (PPSF) [16], bidirectionally-pumped inside a Sagnac loop.…”

Telecom-band hyperentangled photon pairs from a fiber-based source

“…Entanglement in these two DOFs can be generated straightforwardly in fiber [10] and nonlinear waveguides [11] via nonlinear processes such as spontaneous parametric downconversion (SPDC) and spontaneous four-wave-mixing (SFWM). While these waveguide-based sources benefit from greater mode confinement (compared to their bulk crystal counterparts) and single spatial-mode emission, this latter property also limits the accessible dimensionality of the hyperentangled photon pairs generated, due to the fact that the two entangled photons are in the spatial mode [12]. Beamsplitter-based techniques have been used for the probabilistic separation of the biphotons to achieve polarization-frequency (PF) hyperentanglement * changjia.chen@mail.utoronto.ca [13], but the hyperentanglement is achieved only after post-selection of coincidence detection, with only 50% probability, limiting its potential for applications such as dense coding.…”

“…In order to deterministically separate the PF hyperentangled biphotons generated from collinearly propagating biphotons without destroying the entanglement in either DOF, one can make use of biphoton interference, specifically, the anti-bunching effect on a beamsplitter or a polarizing beamsplitter [14,15]. Based on the proposed design in our recent work [12], here we present an experimental demonstration of a PF hyperentangled photon-pair source. The photons are generated via a broadband type-II spontaneous parametric down conversion in a periodically-poled silica fiber (PPSF) [16], bidirectionally-pumped inside a Sagnac loop.…”

Telecom-band hyperentangled photon pairs from a fiber-based source

“…While the enhancement effected by hyperentanglement in a continuous parameter estimation problem has been analysed in an earlier work [12], this Letter shines light on the enhancement in what is essentially a hypothesis testing task. In this Letter, we propose object-detection using a probe state hyperentangled in polarization as well as frequency degrees of freedom [13]. We show that the QCB for object-detection using hyperentangled photons gives a remarkable 12dB improvement in the exponent of the error probability over QI in the "bad regime".…”

“…Hyperentanglement-enhanced sensitivity in the low noise regime: Ever since the first experimental demonstration of generation of hyperentangled photon pairs [17], different procedures to generate hyperentanglement in different degree of freedom of photons have been successfully demonstrated. Here we will briefly outline one such procedure [13] to generate states hyperentangled in polarization and frequency degrees of freedom. Using two identical type-II non-collinear SPDC generators driven by identical pumps, derived from a common pump, |Φ 1 and |Φ 2 , that are entangled in polarization degree of freedom [18] are produced.…”

“…A first order approximation in squeezing parameter of the resulting hyperentangled state yields a hyperentangled biphoton state. For the low noise regime, the time-bandwith product is adjusted such that the transmitter pulse spans over M temporal modes to give the following output state [13].…”

Hyperentanglement-enhanced quantum illumination

Entangling entanglement: coupling frequency and polarization of biphotons on demand