W. A. Merzou, B. Cagneau, F. Gardillou, K. Hilouane, and L. Chassagne, Highly compact and easy-to-use optical chip interferometer with picometric performances, AIP Rev. of Sci. Inst, vol.87, p.103103, 2016.

G. Geoffray, T. Allenet, F. Canto, L. Couston, D. Bucci et al., Development of an opto-fluidic microsystem dedicated to chemical analysis in a nuclear environment, Procedia Chemistry, vol.21, pp.453-460, 2016.
URL : https://hal.archives-ouvertes.fr/hal-01972225

A. Morand, A. Warzecha, E. Ghibaudo, F. Thomas, P. Benech et al., A fully static OCT sensor using a glass integrated optic chip bonded to a CCD linear camera, Proc. SPIE, vol.9365, p.93650, 2015.
URL : https://hal.archives-ouvertes.fr/hal-01961483

C. Duchemin, F. Thomas, B. Martin, E. Morino, R. Puget et al., Development of an inegrated sub-picometric SWIFTS-based wavelength meter, Proc. SPIE, 10110, p.1011016, 2017.

. Berger, An integrated optics 3 way beam combiner for IOTA, Proc. SPIE, vol.4838, p.1011016, 2002.

A. Tervonen, R. B. West, and S. Honkanen, Ion-exchanged glass waveguide technology: a review, Opt. Eng, vol.50, p.71107, 2011.

M. Kufner and S. Kufner, Ion exchange technology for optical waveguides, Optik & Photonik, vol.4, pp.32-34, 2011.

F. ;. Gardillou and . Pic-magazine, A little piece of glass can change everything, vol.3, 2016.

R. Fuest, N. Fabricius, U. Hollenbach, and B. Wolf, Interferometric displacement sensor realized with a planar 3x3 directional coupler in glass, Proc. SPIE, p.1794, 1993.

M. Mccourt, Commercial glass waveguide devices, Proc. SPIE, p.10275, 1994.

J. Broquin, Glass integrated optics: state of the art and position toward other technologies, Proc. SPIE, vol.6475, p.647507, 2007.

N. Courjal, F. Devaux, A. Gerthoffer, C. Guyot, F. Henrot et al., Low-loss LiNbO3 tapered-ridge waveguides made by optical-grade dicing, Opt. Exp, vol.23, pp.13983-13990, 2015.
URL : https://hal.archives-ouvertes.fr/hal-02134460

N. Courjal, M. Bernal, A. Caspar, G. Ulliac, F. Bassignot et al., Lithium Niobate Optical Waveguides Microwaveguides, Interchopen books, Emerging Waveguide Tehcnology, vol.8, 2018.

A. Lin, W. Lei, Z. Xintong, C. Chen, and C. Feng, Depth profile of the nonlinear susceptibility of LiNbO3 ridge waveguides fabricated by ion implantation and dicing, Opt. Mat. Exp, vol.7, pp.3836-38043, 2017.

M. F. Volk, C. E. Rter, M. Santandrea, C. Eigner, L. Padberg et al., Fabrication of low-loss Rb-exchanged ridge waveguides in z-cut KTiOPO4, Opt. Mat. Exp, vol.8, p.82, 2018.

Y. Yao, W. Wang, D. Zhang, and X. Gao, Planar and ridge ZnO optical waveguides produced by 15 MeV C5+ ion irradiation, Opt. Mat. Exp, vol.5, p.1498, 2015.

D. Bucci, B. Martin, and A. Morand, Application of the three-dimensional aperiodic Fourier modal method using arc elements in curvilinear coordinates, vol.29, pp.367-373, 2012.

D. Bucci, B. Martin, and A. Morand, Study of propagation modes of bent waveguides and micro-ring resonators by means of the aperiodic Fourier modal method, Proc. of SPIE, vol.7597, p.75970, 2010.
URL : https://hal.archives-ouvertes.fr/hal-00603655

L. G. Carpenter, H. L. Rogers, P. A. Cooper, C. Holmes, J. C. Gates et al., Low optical-loss facet preparation for silica-on-silicon photonics using the ductile dicing regime, IOP J. Phys. D: Appl. Phys, vol.46, p.475103, 2013.

A. J. Sane and A. R. Cooper, Stress Building and Relaxation During Ion Exchange Strenghening of Glass, J. Amer. Ceram. Soc, vol.70, pp.86-89, 1987.