Progress Being Made On Quantum Entanglement Methods that Work in Mainstream Telecom Wavelengths
(FibreSystems) The prospect of full quantum networks exploiting entangled photons is drawing closer with efforts from researchers such Hee Su Park from the Korea Research Institute of Standards and Science (KRISS).
From 2005 to 2010, Park built up a quantum optics lab to develop measurement techniques for quantum information technologies. He wanted to ﬁnd out to what extent optical ﬁbres guiding multiple spatial modes can be used for quantum communications. Quantum networks encourage ‘collaboration by scientists in diverse ﬁelds, and surely inspire a lot of novel and interesting ideas,’ Park explained.
ﬁndings from scientists like Park are already suggesting ways in which quantum networks could be integrated with ﬁbre networks. Experimental approaches previously used diﬀerent wavelengths of light and diﬀerent types of ﬁbre to the predominantly single-mode, single core ﬁbre infrastructure that today underlies the internet. But, new methods increase the chances that quantum networks might integrate with existing systems. It may be at least 20 years until that becomes a reality – but ﬁndings are already being published that put the process in motion.
Park stressed how important high-dimensional entanglement could be in quantum networks. ‘By transferring the quantum state of entangled photons to the qubits of quantum computers, two physically separated quantum processors can be, in principle, connected by entanglement to build a distributed quantum computer,’ he explained.
‘High-dimensional encoding helps us to increase the amount of quantum links that can be generated by single photons. Of course there are a huge lot of technical challenges regarding connection between diﬀerent types of qubits and long-distance transmission of photons.
A comprehensive survey, the article also includes descriptions of the work of other scientists: 1) Caspar van der Wal’s group at the University of Groningen is one of several teams developing semiconductor-based qubits that could simplify such transductions; 2) Wolfgang Loeﬄer’s team, at Leiden University in the Netherlands;3) Andrew Forbes from the University of the Witswatersrand in Johannesburg, South Africa, groups the ways quantum communication experiments entangle photons into two extremes; 4) Research at Delﬅ University in the Netherlands that is already building quantum networks based on NV centres in diamonds,