Publications
[23] Elementary processes in dilatational plasticity of glasses
A. Moriel, D. Richard, E. Lerner, and E. Bouchbinder, Physical Review Research 6, 2024
[22] Connecting microscopic and mesoscopic mechanics in model structural glasses
D. Richard, The Journal of Chemical Physics 160, 2024
[21] Detecting low-energy quasilocalized excitations in computer glasses
D. Richard, G. Kapteijns, and E. Lerner, Physical Review E 108, 2023
[20] Bridging necking and shear-banding mediated tensile failure in glasses
D. Richard, E.T. Lund, J. Schroers, and E. Bouchbinder, Physical Review Materials 7, 2023
[19] Mechanical excitation and marginal triggering during avalanches in sheared amorphous solids
D. Richard, A. Elgailani, D. Vandembroucq, M.L. Manning, and C.E. Maloney, Physical Review E 107, 2023
[18] Bond-space operator disentangles quasilocalized and phononic modes in structural glasses
J.A. Giannini, D. Richard, M.L. Manning, and E. Lerner, Physical Review E 104, 2021
[17] Finite-size study of the athermal quasistatic yielding transition in structural glasses
D. Richard, C. Rainone, and E. Lerner, The Journal of Chemical Physics 155, 2021
[16] Does mesoscopic elasticity control viscous slowing down in glassforming liquids?
G. Kapteijns, D. Richard, E. Bouchbinder, T.B. Schrøder, J.C. Dyre, and E. Lerner, The Journal of Chemical Physics 155, 2021
[15] Brittle to ductile transitions in glasses: Roles of soft defects and loading geometry
D. Richard, E. Lerner, E. Bouchbinder, MRS Bulletin 46, 2021
[14] Elastic moduli fluctuations predict wave attenuation rates in glasses
G. Kapteijns, D. Richard, E. Bouchbinder, and E. Lerner, The Journal of Chemical Physics 154, 2021
[13] Simple and broadly applicable definition of shear transformation zones
D. Richard, G. Kapteijns, J.A. Giannini, M.L. Manning, and E. Lerner, Physical Review Letters 126, 2021
[12] Predicting plasticity in disordered solids from structural indicators
D. Richard, M. Ozawa, S. Patinet, E. Stanifer, B. Shang, S. A. Ridout, B. Xu, G. Zhang, P. K. Morse, J.-L. Barrat, L. Berthier, M. L. Falk, P. Guan, A. J. Liu, K. Martens, S. Sastry, D. Vandembroucq, E. Lerner, and M. L. Manning, Phys. Rev. Materials 4, 2020
[11] Universality of the nonphononic vibrational spectrum across different classes of computer glasses
D. Richard, K. González-López, G. Kapteijns, R. Pater, T. Vaknin, E. Bouchbinder, and E. Lerner, Physical Review Letters 125, 2020
[10] Nonlinear quasilocalized excitations in glasses: True representatives of soft spots
G. Kapteijns, D. Richard, and E. Lerner, Physical Review E 101, 2020
[9] Classical nucleation theory for the crystallization kinetics in sheared liquids
D. Richard and T. Speck, Physical Review E 99, 2019
[8] Communication: Is directed percolation in colloid-polymer mixtures linked to dynamic arrest?
D. Richard, C.P. Royall, and T. Speck, The Journal of chemical physics 148, 2018
[7] Crystallization of hard spheres revisited. II. Thermodynamic modeling, nucleation work, and the surface of tension
D. Richard and T. Speck, The Journal of chemical physics 148, 2018
[6] Crystallization of hard spheres revisited. I. Extracting kinetics and free energy landscape from forward flux sampling
D. Richard and T. Speck, The Journal of chemical physics 148, 2018
[5] Three-body correlations and conditional forces in suspensions of active hard disks
A. Härtel, D. Richard, and T. Speck, Physical Review E 97, 2018
[4] Coupling between criticality and gelation in “sticky” spheres: A structural analysis
D. Richard, J. Hallett, T. Speck, and C.P. Royall, Soft Matter 14, 2018
[3] Entropic interactions between two knots on a semiflexible polymer
D. Richard, S. Stalter, J.T. Siebert, F. Rieger, B. Trefz, and P. Virnau, Polymers 9, 2017
[2] Nucleation pathway and kinetics of phase-separating active Brownian particles
D. Richard, H. Löwen, and T. Speck, Soft Matter 12, 2016
[1] The role of shear in crystallization kinetics: From suppression to enhancement
D. Richard and T. Speck, Scientific reports 5, 2015