D. Daval, R. Hellmann, G. D. Saldi, R. Wirth, and K. G. Knauss, Linkin nm-scale 758 measurements of the anisotropy of silicate surface reactivity to macroscopic dissolution rate 759 laws: new insights based on diopside, Geochim. Cosmochim. Acta, vol.107, pp.121-134, 2013.

L. Deng and D. Jincheng, Development of effective empirical potentials for molecular 761 dynamics simulations of the structures and properties of boroaluminosilicate glasses, Journal, vol.762, pp.177-194, 2016.

P. M. Dove, H. Nizhou, W. Af, and J. J. De-yoreo, Kinetics of amorphous silica 764 dissolution and the paradox of the silica polymorphs, Proc Natl Acad Sci U S A, vol.105, pp.9903-765, 2008.

E. S. Levenson and Y. , Quantifying micron-scale grain detachment during 767 weathering experiments on limestone, Geochim. Cosmochim. Acta, vol.173, pp.86-96, 2015.

P. Fenter, P. Zapol, H. He, and N. C. Sturchio, On the variation of dissolution rates at the 769 orthoclase (001) surface with pH and temperature, Geochim. Cosmochim. Acta, vol.141, pp.598-611, 2014.

C. Fischer, A. Rs, and L. , How predictable are dissolution rates of crystalline 771 material?, Geochim. Cosmochim. Acta, vol.98, pp.177-185, 2012.

C. Fischer, I. Kurganskaya, T. Schäfer, and A. Lüttge, Variability of crystal surface 773 reactivity: What do we know?, Applied Geochemistry, vol.43, pp.132-157, 2014.

C. Fischer, S. Finkeldei, F. Brandt, D. Bosbach, and A. Luttge, Direct measurement of 775 surface dissolution rates in potential nuclear waste forms: The example of pyrochlore, Applied 776 Material Interfaces, vol.7, pp.17857-17865, 2015.

A. Fischer and A. Lüttge, Beyond the conventional understanding of water-rock 778 reactivity, Earth Planetary Science Letters, vol.457, pp.100-105, 2017.

P. Frugier, S. Gin, Y. Minet, T. Chave, B. Bonin et al., , p.780

L. Windt and G. Santarini, SON68 nuclear glass dissolution kinetics: Current state of 781 knowledge and basis of the new GRAAL model, Journal of Nuclear Materials, vol.380, pp.8-21, 2008.

I. Galeczka, D. Wolff-boenisch, E. H. Oelkers, and S. R. Gislason, An experimental study of 783 basaltic glass-H 2 O-CO 2 interaction at 22 and 50°C: Implications for subsurface storage of 784 CO 2, Geochim. Cosmochim. Acta, vol.126, pp.123-145, 2014.

T. Geisler, A. Janssen, D. Scheiter, T. Stephan, J. Berndt et al., Aquaeous corrosion of 786 borosilicate glass under acidic conditions: A new corrosion mechanism, Journal of Non, p.787, 2010.

, Crystalline Solids, vol.356, pp.1458-1465

T. Geisler, T. Nagel, M. R. Kilburn, A. Janssen, J. P. Icenhower et al., , p.789

A. A. Nemchin, The mechanism of borosilicate glass corrosion revisited, 2015.

, Cosmochim. Acta, vol.158, pp.112-129

S. Gin, P. Jollivet, M. Fournier, F. Angéli, P. Frugier et al., Origin and 792 consequences of silicate glass passivation by surface layers, Nature communications, vol.6, pp.1-8, 2015.

G. D. Saldi, M. Voltolini, and K. G. Knauss, Effects of surface orientation, fluid chemistry and 899 mechanical polishing on the variability of dolomite dissolution rates, 2017.

, Acta, vol.206, pp.94-111

R. D. Shannon and C. T. Prewitt, Effective ionic radii in oxides and fluorides, Acta 902 Crystallogr., Sect. B: Struct. Crystallogr. Cryst. Chem, vol.25, pp.925-946, 1969.

J. Tullis, Deformation of feldspars, Feldspar Mineralogy. Reviews in Mineralogy, vol.2, pp.905-297, 1983.

M. P. Tole, A. C. Lasaga, C. Patano, and W. B. White, The kinetics of dissolution of 908 nepheline (NaAlSiO 4 ), Geochim. Cosmochim. Acta, vol.50, pp.379-392, 1986.

A. Verney-carron, S. Gin, and G. Libourel, A fractured roman glass block altered for 1800 911 years in seawater: Analogy with nuclear waste glass in a deep geological repository, 2008.

, Cosmochim. Acta, vol.72, pp.5372-5385

J. D. Vienna, J. V. Ryan, S. Gin, and Y. Inagaki, Current understanding and remaining 915 challenges in modeling long-term degradation of borosilicate nuclear waste glasses, 916 International Journal of Applied Glass Science, vol.4, pp.283-294, 2013.

A. F. White and S. L. Brantley, The effect of time on the weathering of silicate minerals: 919 why do weathering rates differ in the laboratory and field?, Chemical Geology, vol.202, pp.479-506, 2003.

B. Wild, D. Daval, F. Guyot, K. G. Knauss, M. Pollet-villard et al., pH-dependant 922 control of feldspar dissolution rate by altered surface layers, Chem Geol, vol.442, pp.148-159, 2016.

D. Wolff-boenisch, S. R. Gislason, E. H. Oelkers, and C. V. Putnis, The dissolution rates of 925 natural glasses as a function of their composition at pH 4 and 10.6 and temperatures from 25 926 to 74°C, Geochim. Cosmochim. Acta, vol.68, pp.4843-4858, 2004.

Y. Xiao and A. C. Lasaga, Ab initio quantum mechanical studies of the kinetics and 929 mechanisms of silicate dissolution: H + (H 3 O + ) catalysis, Geochim. Cosmochim. Acta, vol.58, p.5400, 1995.