Space Qualification of Ultrafast Laser‐Written Integrated Waveguide Optics

Satellite-based quantum technologies represent a possible route for extending the achievable range of quantum communication, allowing the construction of worldwide quantum networks without quantum repeaters. In space missions, however, the volume available for the instrumentation is limited, and footprint is a crucial specification of the devices that can be employed. Integrated optics could be highly beneficial in this sense, as it allows for the miniaturization of different functionalities in small and monolithic photonic circuits. In this work, we report on the qualification of waveguides fabricated in glass by femtosecond laser micromachining for their use in a low Earth orbit space environment. In particular, we exposed different laser written integrated devices, such as straight waveguides, directional couplers, and Mach-Zehnder interferometers, to suitable proton and $\gamma$-ray irradiation. Our experiments show that no significant changes have been induced to their characteristics and performances by the radiation exposure. Our results, combined with the high compatibility of laser-written optical circuits to quantum communication applications, pave the way for the use of laser-written integrated photonic components in future satellite missions.

[1]  Catherine Holloway,et al.  The NanoQEY mission: ground to space quantum key and entanglement distribution using a nanosatellite , 2014, Security and Defence.

[2]  P. Lam,et al.  Room temperature single photon source using fiber-integrated hexagonal boron nitride , 2017 .

[3]  Imran Khan,et al.  Quantum-limited measurements of optical signals from a geostationary satellite , 2016, ArXiv.

[4]  Jian-Wei Pan,et al.  Satellite-Relayed Intercontinental Quantum Network. , 2018, Physical review letters.

[5]  Yongmei Huang,et al.  Satellite-to-ground quantum key distribution , 2017, Nature.

[6]  Harry Buhrman,et al.  The quantum technologies roadmap: a European community view , 2018, New Journal of Physics.

[7]  Nemanja Jovanovic,et al.  Low bend loss waveguides enable compact, efficient 3D photonic chips. , 2013, Optics express.

[8]  G. Vallone,et al.  Interference at the Single Photon Level Along Satellite-Ground Channels. , 2015, Physical review letters.

[9]  Alexander Ling,et al.  Generation and analysis of correlated pairs of photons on board a nanosatellite , 2016 .

[10]  H. Weinfurter,et al.  Design and Evaluation of a Handheld Quantum Key Distribution Sender module , 2015, IEEE Journal of Selected Topics in Quantum Electronics.

[11]  Klaus Schilling,et al.  Qube - A CubeSat for Quantum Key Distribution Experiments , 2018 .

[12]  Simone Atzeni,et al.  Symmetric polarization-insensitive directional couplers fabricated by femtosecond laser writing. , 2018, Optics express.

[13]  O. Guyon,et al.  First on-sky demonstration of an integrated-photonic nulling interferometer: the GLINT instrument , 2019, 1911.09808.

[14]  Jeremy L O'Brien,et al.  Laser written waveguide photonic quantum circuits. , 2009, Optics express.

[15]  Simone Atzeni,et al.  Integrated sources of entangled photons at telecom wavelength in femtosecond-laser-written circuits , 2017, 1710.09618.

[16]  Paolo Villoresi,et al.  Experimental Satellite Quantum Communications. , 2014, Physical review letters.

[17]  Jian-Wei Pan,et al.  Experimental quasi-single-photon transmission from satellite to earth. , 2013, Optics express.

[18]  S. Wehner,et al.  Quantum internet: A vision for the road ahead , 2018, Science.

[19]  Stefan Nolte,et al.  On-chip generation of high-order single-photon W-states , 2014, Nature Photonics.

[20]  Roberto Osellame,et al.  Micromachining of photonic devices by femtosecond laser pulses , 2008 .

[21]  Nick Cvetojevic,et al.  Astronomical photonics in the context of infrared interferometry and high-resolution spectroscopy , 2016, Astronomical Telescopes + Instrumentation.

[22]  Graham D. Marshall,et al.  Large-scale silicon quantum photonics implementing arbitrary two-qubit processing , 2018, Nature Photonics.

[23]  P. Lam,et al.  Compact Cavity-Enhanced Single-Photon Generation with Hexagonal Boron Nitride , 2019, ACS Photonics.

[24]  R. Ursin,et al.  Nanobob: a CubeSat mission concept for quantum communication experiments in an uplink configuration , 2018, EPJ Quantum Technology.

[26]  Paolo Villoresi,et al.  CubeSat quantum communications mission , 2017, EPJ Quantum Technology.

[27]  T. Jennewein,et al.  QEYSSAT: a mission proposal for a quantum receiver in space , 2014, Photonics West - Optoelectronic Materials and Devices.

[28]  Fabio Sciarrino,et al.  Experimental multiphase estimation on a chip , 2019, Optica.

[29]  Hiroki Takesue,et al.  Entanglement distribution over 300 km of fiber. , 2013, Optics express.

[30]  M. Toyoshima,et al.  Satellite-to-ground quantum-limited communication using a 50-kg-class microsatellite , 2017, 1707.08154.

[31]  V. Quiring,et al.  A two-channel, spectrally degenerate polarization entangled source on chip , 2016, 1604.03430.

[32]  Dong He,et al.  Satellite-based entanglement distribution over 1200 kilometers , 2017, Science.

[33]  Stefano Taccheo,et al.  Optical waveguide writing with a diode-pumped femtosecond oscillator. , 2004, Optics letters.

[34]  Thomas Pertsch,et al.  Towards 3D-photonic, multi-telescope beam combiners for mid-infrared astrointerferometry. , 2017, Optics express.

[35]  Alexander Ling,et al.  Silicon avalanche photodiode operation and lifetime analysis for small satellites. , 2013, Optics express.

[36]  I. Sagnes,et al.  Interfacing scalable photonic platforms: solid-state based multi-photon interference in a reconfigurable glass chip , 2019, Optica.

[37]  John B. Shoven,et al.  I , Edinburgh Medical and Surgical Journal.

[38]  P. Lam,et al.  Radiation tolerance of two-dimensional material-based devices for space applications , 2018, Nature Communications.

[39]  Dirk Englund,et al.  On-chip detection of non-classical light by scalable integration of single-photon detectors , 2014, Nature Communications.

[40]  F. Bussières,et al.  Secure Quantum Key Distribution over 421 km of Optical Fiber. , 2018, Physical review letters.

[41]  J. Ziegler,et al.  SRIM – The stopping and range of ions in matter (2010) , 2010 .

[42]  A. Eckstein,et al.  Direct bell states generation on a III-V semiconductor chip at room temperature , 2013, CLEO: 2013.

[43]  Jian-Wei Pan,et al.  Ground-to-satellite quantum teleportation , 2017, Nature.