Add to ORKGHigh-dimensional Hilbert spaces used for quantum communication channels offer the possibility of large data transmission capabilities. We propose a method of characterizing the channel capacity of an entangled photonic state in high-dimensional position and momentum bases. We use this method to measure the channel capacity of a parametric down-conversion state by measuring in up to 576 dimensions per detector. We achieve a channel capacity over 7 bits/photon in either the position or momentum basis. Furthermore, we provide a correspondingly high-dimensional separability bound that suggests that the channel performance cannot be replicated classically
Compressive sensing utilizes sparsity to realize efficient image reconstruction. It is a valuable pr...
The storage and processing of quantum information are susceptible to external noise, resulting in co...
We report on experimental and theoretical studies on recently introduced entanglement measures which...
High-dimensional Hilbert spaces used for quantum communication channels offer the possibility of lar...
The resources needed to conventionally characterize a quantum system are overwhelmingly large for hi...
We demonstrate a simple experimental method for creating entangled qudits. Using transverse-momentum...
Quantum buffers will be an essential part of quantum-information networks. A buffer that can preserv...
Here, we present recent developments in the field of quantum imaging focusing on the high dimensiona...
We show how weak nonlinearities can be used in a device-independent quantum key distribution (QKD) p...
We introduce a quantity which is formed using classical notions of mutual information and which is c...
Witnessing continuous-variable Bell nonlocality is a challenging endeavor, but Bell himself showed h...
The entanglement of squeezed light beams is critical for quantum optical applications, but has so fa...
Shannon proved in 1949 that information-theoretic-secure encryption is possible if the encryption ke...
We study transverse spatial coherence of approximately localized single-photon states. We demonstrat...
We present a measurement protocol for discriminating between two different quantum states of a qubit...
Compressive sensing utilizes sparsity to realize efficient image reconstruction. It is a valuable pr...
The storage and processing of quantum information are susceptible to external noise, resulting in co...
We report on experimental and theoretical studies on recently introduced entanglement measures which...
High-dimensional Hilbert spaces used for quantum communication channels offer the possibility of lar...
The resources needed to conventionally characterize a quantum system are overwhelmingly large for hi...
We demonstrate a simple experimental method for creating entangled qudits. Using transverse-momentum...
Quantum buffers will be an essential part of quantum-information networks. A buffer that can preserv...
Here, we present recent developments in the field of quantum imaging focusing on the high dimensiona...
We show how weak nonlinearities can be used in a device-independent quantum key distribution (QKD) p...
We introduce a quantity which is formed using classical notions of mutual information and which is c...
Witnessing continuous-variable Bell nonlocality is a challenging endeavor, but Bell himself showed h...
The entanglement of squeezed light beams is critical for quantum optical applications, but has so fa...
Shannon proved in 1949 that information-theoretic-secure encryption is possible if the encryption ke...
We study transverse spatial coherence of approximately localized single-photon states. We demonstrat...
We present a measurement protocol for discriminating between two different quantum states of a qubit...
Compressive sensing utilizes sparsity to realize efficient image reconstruction. It is a valuable pr...
The storage and processing of quantum information are susceptible to external noise, resulting in co...
We report on experimental and theoretical studies on recently introduced entanglement measures which...