Edan Lerner - Publications

Preprints:

Edan Lerner and Eran Bouchbinder, Generic statistical and spatial properties of low-energy excitations in computer glasses, arXiv:2405.07851.
Avraham Moriel, Edan Lerner, and Eran Bouchbinder, Experimental evidence for the ω⁴ tail of the nonphononic spectra of glasses, arXiv:2404.16996.

2024:

Edan Lerner, Avraham Moriel, and Eran Bouchbinder, Enumerating low-frequency nonphononic vibrations in computer glasses, J. Chem. Phys. 161, 014504 (2024), also arXiv:2404.12735.
Tommaso Pettinari, Gustavo Düring, and Edan Lerner, Elasticity of self-organized frustrated disordered spring networks, Phys. Rev. E 109, 054906 (2024), also arXiv:2401.11996.
Edan Lerner, Effects of coordination and stiffness scale-separation in disordered elastic networks, Phys. Rev. E 109, 054904 (2024), also arXiv:2312.06427.
Avraham Moriel, David Richard, Edan Lerner, and Eran Bouchbinder, Elementary processes in dilatational plasticity of glasses, Phys. Rev. Research 6, 023167 (2024), also arXiv:2402.03044.
Avraham Moriel, Edan Lerner, and Eran Bouchbinder, The boson peak in the vibrational spectra of glasses, Phys. Rev. Research 6, 023053 (2024), also arXiv:2304.03661.
Daan Haver, Daniel Acuña, Sharan Janbaz, Edan Lerner, Gustavo Düring, and Corentin Coulais, Elasticity and rheology of auxetic granular metamaterials, PNAS 121, e2317915121 (2024), also arXiv:2310.03547.
Julia A. Giannini, Edan Lerner, Francesco Zamponi, and M. Lisa Manning, Scaling regimes and fluctuations of observables in computer glasses approaching the unjamming transition, J. Chem. Phys. 160, 034502 (2024), also arXiv:2309.08784.

2023:

Edan Lerner and Eran Bouchbinder, Scaling theory of critical strain-stiffening in disordered elastic networks, Extreme Mech. Lett. 65, 102104 (2023), also arXiv:2208.08204.
David Richard, Geert Kapteijns, and Edan Lerner, Detecting low-energy quasilocalized excitations in computer glasses, Phys. Rev. E 108, 044124 (2023), also arXiv:2303.12887.
Edan Lerner and Eran Bouchbinder, Boson-peak vibrational modes in glasses feature hybridized phononic and quasilocalized excitations, J. Chem. Phys. 158, 194503 (2023), also arXiv:2210.10326.
Ellen Zheng, Martin Brandenbourger, Louis Robinet, Peter Schall, Edan Lerner, and Corentin Coulais, Self-oscillation and Synchronisation Transitions in Elasto-Active Structures, Phys. Rev. Lett. 130, 178202 (2023), also arXiv:2106.05721.
Edan Lerner and Eran Bouchbinder, Anomalous linear elasticity of disordered networks, Soft Matter 19, 1076 (2023), also arXiv:2209.04237.
Karina González-López, Eran Bouchbinder, and Edan Lerner, Variability of mesoscopic mechanical disorder in disordered solids, J. Non-Cryst. Solids 604, 122137 (2023), also arXiv:2012.03634.

2022:

Edan Lerner and Eran Bouchbinder, Nonphononic spectrum of two-dimensional structural glasses, J. Chem. Phys. 157, 166101 (2022), also arXiv:2208.05725.
Edan Lerner and Eran Bouchbinder, Disordered crystals reveal soft quasilocalized glassy excitations, Phys. Rev. Lett. 129, 095501 (2022), also arXiv:2203.01383.
Edan Lerner, Ultrahigh Poisson's ratio glasses, Phys. Rev. Materials 6, 065604 (2022), also arXiv:2202.10993.
Minh Triet Dang, Luka Gartner, Peter Schall, and Edan Lerner, Measuring the free energy of hard-sphere colloidal glasses, J. Phys. D: Appl. Phys. 55, 165304 (2022).

2021:

Edan Lerner and Eran Bouchbinder, Low-energy quasilocalized excitations in structural glasses, J. Chem. Phys. 155, 200901 (2021), also arXiv:2108.13859.
Julia A Giannini, David Richard, M. Lisa Manning, and Edan Lerner, Bond-space operator disentangles quasi-localized and phononic modes in structural glasses, Phys. Rev. E 104, 044905 (2021), also arXiv:2106.16231.
David Richard, Edan Lerner, and Eran Bouchbinder, Brittle to ductile transitions in glasses: Roles of soft defects and loading geometry, MRS Bulletin Impact 46, 902 (2021), also arXiv:2103.05258.
Geert Kapteijns, Eran Bouchbinder, and Edan Lerner, A unified quantifier of mechanical disorder in solids, Phys. Rev. E 104, 035001 (2021), also arXiv:2106.12613.
Geert Kapteijns, David Richard, Eran Bouchbinder, Thomas B. Schrøder, Jeppe C. Dyre, and Edan Lerner, Does mesoscopic elasticity control viscous slowing down in glassforming liquids?, J. Chem. Phys. 155, 074502 (2021), also arXiv:2103.11404.
David Richard, Corrado Rainone, and Edan Lerner, Finite-size study of the athermal quasistatic yielding transition in structural glasses, J. Chem. Phys. 155, 056101 (2021), also arXiv:2104.02441.
Eran Bouchbinder, Edan Lerner, Corrado Rainone, PierFrancesco Urbani, and Francesco Zamponi, Low-frequency vibrational spectrum of mean-field disordered systems, Phys. Rev. B, 103, 174202 (2021), also arXiv:2012.11558.
Corrado Rainone, Pierfrancesco Urbani, Francesco Zamponi, Edan Lerner, Eran Bouchbinder, Mean-field model of interacting quasilocalized excitations in glasses, Scipost Phys. Core 4, 008 (2021), also arXiv:2010.11180.
Geert Kapteijns, David Richard, Eran Bouchbinder, and Edan Lerner, Elastic moduli fluctuations predict wave attenuation rates in glasses, J. Chem. Phys. 154, 081101 (2021), see also Scilight and arXiv:2008.08337.
Karina González-López, Mahajan Shivam, Yuanjian Zheng, Massimo Pica Ciamarra, and Edan Lerner, Mechanical disorder of sticky-sphere glasses. I. Effect of attractive interactions, Phys. Rev. E 103, 022605 (2021), also arXiv:2008.12011.
Karina González-López, Mahajan Shivam, Yuanjian Zheng, Massimo Pica Ciamarra, and Edan Lerner, Mechanical disorder of sticky-sphere glasses. II. Thermomechanical inannealability, Phys. Rev. E 103, 022606 (2021), also arXiv:2009.08238.
David Richard, Geert Kapteijns, Julia A. Giannini, M. Lisa Manning, Edan Lerner, A simple and broadly-applicable definition of shear transformation zones, Phys. Rev. Lett. 126, 015501 (2021), also arXiv:2007.08181.

2020:

Karina González-López and Edan Lerner, An energy-landscape-based crossover temperature in glass-forming liquids, J. Chem. Phys. 153, 241101 (2020), also, arXiv:2010.07153.
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, Predicting plasticity in disordered solids from structural indicators, Phys. Rev. Materials 4, 113609 (2020), also arXiv:2003.11629.
Edan Lerner, Note: Simple argument for emergent anisotropic stress correlations in disordered solids, J. Chem. Phys. 153, 216101 (2020), also arXiv:2010.08420.
Avraham Moriel, Yuri Lubomirsky, Edan Lerner, and Eran Bouchbinder, Extracting the properties of quasilocalized modes in computer glasses: Long-range continuum fields, contour integrals and boundary effects, Phys. Rev. E 102, 033008 (2020), also arXiv:2007.11421.
David Richard, Karina González-López, Geert Kapteijns, Robert Pater, Talya Vaknin, Eran Bouchbinder, and Edan Lerner, Universality of the nonphononic vibrational spectrum across different classes of computer glasses, Phys. Rev. Lett. 125, 085502 (2020), also arXiv:2003.07616.
Prasenjit Das, H. George E. Hentschel, Edan Lerner, and Itamar Procaccia, Robustness of Density of Low Frequency States in Amorphous Solids, Phys. Rev. B 102, 014202 (2020), also arXiv:2005.06197.
Corrado Rainone, Eran Bouchbinder, and Edan Lerner, Statistical mechanics of local force dipole responses in computer glasses, J. Chem. Phys. 152, 194503 (2020) also arXiv:2001.11430.
Geert Kapteijns, David Richard and Edan Lerner, Nonlinear quasilocalized excitations in glasses. True representatives of soft spots, Phys. Rev. E 101, 032130 (2020), also arXiv:1912.10930.
Edan Lerner, Finite-size effects in the nonphononic density of states in computer glasses, Phys. Rev. E 101, 032120 (2020) also arXiv:1911.12741.
Corrado Rainone, Eran Bouchbinder, and Edan Lerner, Pinching a glass reveals key properties of its soft spots, PNAS 117, 5228 (2020), also arXiv:1911.07744.

2019:

Stefan Kooij and Edan Lerner, Characterizing nonaffinity upon decompression of soft-sphere packings, Phys. Rev. E 100, 042609 (2019), also arXiv:1907.09318.
Martin Brandenbourger, Xander Locsin, Edan Lerner, and Corentin Coulais, Non-reciprocal robotic metamaterials, Nat. Commun. 10, 4608 (2019), also arXiv:1903.03807.
Avraham Moriel, Geert Kapteijns, Corrado Rainone, Jacques Zylberg, Edan Lerner, and Eran Bouchbinder, Wave attenuation in glasses: Rayleigh and generalized-Rayleigh scattering scaling, J. Chem. Phys. 151, 104503 (2019), also arXiv:1905.03378.
Robbie Rens and Edan Lerner, Rigidity and auxeticity transitions in networks with strong bond-bending interactions, Eur. Phys. J. E 42, 114 (2019), also arXiv:1904.07054.
Edan Lerner, Mechanical properties of simple computer glasses, J. Non-Cryst. Solids 522, 119570 (2019), also arXiv:1902.08991.
Zohar Schwartzman-Nowik, Edan Lerner, and Eran Bouchbinder, Anisotropic structural predictor in glassy materials, Phys. Rev. E 99, 060601(R) (2019), also arXiv:1901.05202.
Corrado Rainone, Avraham Moriel, Geert Kapteijns, Eran Bouchbinder, and Edan Lerner, Finite-size effects on sound damping in stable computer glasses, arXiv:1902.06225.
Wencheng Ji, Marko Popović, Tom W. J. de Geus, Edan Lerner, and Matthieu Wyart, Theory for the density of interacting quasi-localised modes in amorphous solids, Phys. Rev. E 99, 023003 (2019), also arXiv:1806.01561.
Geert Kapteijns, Wencheng Ji, Carolina Brito, Matthieu Wyart, and Edan Lerner, Fast generation of ultrastable computer glasses by minimization of an augmented potential energy, Phys. Rev. E 99, 012106 (2019), also arXiv:1808.00018.

2018:

Robbie Rens, Carlos Villarroel, Gustavo Düring, and Edan Lerner, Micromechanical theory of strain-stiffening of biopolymer networks, Phys. Rev. E 98, 062411 (2018), also arXiv:1808.04756.
Edan Lerner, Itamar Procaccia, Corrado Rainone, Murari Singh, On the protocol dependence of plasticity in ultra-stable amorphous solids, Phys. Rev. E 98, 063001 (2018), also arXiv:1806.09134.
Carolina Brito, Edan Lerner, and Matthieu Wyart, Theory for Swap Acceleration near the Glass and Jamming Transitions for Continuously Polydisperse Particles, Phys. Rev. X 8, 031050 (2018), also arXiv:1801:03796.
Edan Lerner, Quasilocalized states of self stress in packing-derived networks, Eur. Phys. J. E 41, 93 (2018), also arXiv:1707:02086.
Geert Kapteijns, Eran Bouchbinder, and Edan Lerner, Universal non-phononic density of states in 2D, 3D and 4D glasses, Phys. Rev. Lett. 121, 055501 (2018), also arXiv:1803.11383.
Eran Bouchbinder and Edan Lerner, Universal disorder-induced broadening of phonon bands: from disordered lattices to glasses, New J. Phys. 20, 073022 (2018), also arXiv:1801:05170.
Edan Lerner and Eran Bouchbinder, A characteristic energy scale in glasses, J. Chem. Phys. 148, 214502 (2018), also arXiv:1802:01131.
Edan Lerner and Eran Bouchbinder, Frustration-induced internal stresses are responsible for quasilocalized modes in structural glasses, Phys. Rev. E 97, 032140 (2018), also arXiv:1711:11263.

2017:

Edan Lerner and Eran Bouchbinder, Effect of instantaneous and continuous quenches on the density of vibrational modes in model glasses, Phys. Rev. E 96, 020104(R) (2017), also: arXiv:1705:01037.
Stefan Kooij and Edan Lerner, Unjamming in models with analytic pairwise potentials, Phys. Rev. E 95, 062141 (2017), also: arXiv:1610.02843.
Jacques Zylberg, Edan Lerner, Yohai Bar-Sinai, and Eran Bouchbinder, Local thermal energy as a structural indicator in glasses, PNAS 114, 7289 (2017), also arXiv:1703:09014.
Edan Lerner, Comment on "Spatial structure of states of self stress in jammed systems" by D. M. Sussman, C. P. Goodrich, and A. J. Liu, Soft Matter, 2016, 12, 3982, Soft Matter 13, 1530 (2017).

2016:

Luka Gartner and Edan Lerner, Nonlinear modes disentangle glassy and Goldstone modes in structural glasses, SciPost Phys. 1, 016 (2016), also: arXiv:1610.03410.
Oleg Gendelman, Edan Lerner, Yoav G. Pollack, Itamar Procaccia, Corrado Rainone, and Birte Riechers, Emergent inter-particle interactions in thermal amorphous solids, Phys. Rev. E 94, 051001(R) (2016), also arXiv:1608.05919.
Edan Lerner, Gustavo Düring, and Eran Bouchbinder, Statistics and properties of low-frequency vibrational modes in structural glasses, Phys. Rev. Lett. 117, 035501 (2016), also arXiv:1604.05187. See also Erratum.
Gustavo Düring, Edan Lerner, and Matthieu Wyart, Effect of particle collisions in dense suspension flows, Phys. Rev. E 94, 022601 (2016), also arXiv:1602.08317.
Edan Lerner, Micromechanics of nonlinear plastic modes, Phys. Rev. E 93, 053004 (2016), also: arXiv:1603.05455.
Luka Gartner and Edan Lerner, Nonlinear plastic modes in disordered solids, Phys. Rev. E 93, 011001(R) (2016), also: arXiv:1507.06931.

2015:

Eric DeGiuli, Gustavo Düring, Edan Lerner, and Matthieu Wyart, Unified theory of inertial granular flows and non-Brownian suspensions, Phys. Rev. E 91, 062206 (2015), also: arXiv:1410.3535.
Eric DeGiuli, Edan Lerner, and Matthieu Wyart, Theory of the jamming transition at finite temperature, J. Chem. Phys. 142, 164503 (2015), also: arXiv:1501.06995.

2014:

Edan Lerner, Nicholas P. Bailey, Jeppe C. Dyre, Density scaling and quasiuniversality of flow-event statistics for athermal plastic flows, Phys. Rev. E 90, 052304 (2014), also: arXiv:1405.0156.
Eric DeGiuli, Edan Lerner, Carolina Brito, and Matthieu Wyart, The distribution of forces affects vibrational properties in hard sphere glasses, PNAS 111, 17054 (2014), also arXiv:1402.3834.
Jie Lin, Edan Lerner, Alberto Rosso, and Matthieu Wyart, Scaling description of the yielding transition in soft amorphous solids at zero temperature, PNAS 111, 14382 (2014), also arXiv:1403.6735.
Edan Lerner, Eric DeGiuli, Gustavo Düring, and Matthieu Wyart, Breakdown of continuum elasticity in amorphous solids, Soft Matter 10, 5085 (2014), also arXiv:1312.2146.
Eric DeGiuli, Adrien Laversanne-Finot, Gustavo Düring, Edan Lerner, and Matthieu Wyart, Effects of coordination and pressure on sound attenuation, boson peak and elasticity in amorphous solids, Soft Matter 10, 5628 (2014), also arXiv:1401.6563.
Gustavo Düring, Edan Lerner, and Matthieu Wyart, Length scales and self-organization in dense suspension flows, Phys. Rev. E 89, 022305 (2014), also arXiv:1308.3886.
Jie Lin, Alaa Saade, Edan Lerner, Alberto Rosso, and Matthieu Wyart, On the density of shear transformations in amorphous solids, Europhys. Lett. 105, 26003 (2014), also arXiv:1307.1646.

2013:

Edan Lerner, Gustavo Düring, and Matthieu Wyart, Low-energy non-linear excitations in sphere packings, Soft Matter 9, 8252 (2013), also arXiv:1302.3990.

2012:

Edan Lerner, Gustavo Düring, and Matthieu Wyart, Simulations of driven overdamped frictionless hard spheres, Comp. Phys. Comm. 184, 628 (2013), also arXiv:1111.7225.
Gustavo Düring, Edan Lerner and Matthieu Wyart, Phonon gap and localization lengths in floppy materials, Soft Matter 9, 146 (2013), also arXiv:1204.3542.
Edan Lerner, Gustavo Düring, and Matthieu Wyart, Toward a microscopic description of flow near the jamming threshold, Europhys. Lett. 99, 58003 (2012), also arXiv:1201.3650.
Edan Lerner, Gustavo Düring, and Matthieu Wyart, A unified framework for non-Brownian suspension flows and soft amorphous solids, PNAS 109, 4798-4803 (2012), also arXiv:1112.0558.
Smarajit Karmakar, Edan Lerner, and Itamar Procaccia, Direct estimate of the static length-scale accompanying the glass transition, Physica A 391, 1001 (2012), also arXiv:1104.1036.

2011:

Smarajit Karmakar, Edan Lerner, Itamar Procaccia, and Jacques Zylberg, Effect of the interparticle potential on the yield stress of amorphous solids, Phys. Rev. E 83, 046106 (2011), also arXiv:1010.4687.
H.G.E. Hentschel, Smarajit Karmakar, Edan Lerner, Itamar Procaccia, Do athermal amorphous solids exist?, Phys. Rev. E 83, 061101 (2011), also arXiv:1101.0101.

2010:

Smarajit Karmakar, Edan Lerner, and Itamar Procaccia, Statistical physics of the yielding transition in amorphous solids, Phys. Rev. E 82, 055103(R) (2010), also arXiv:1008.3967.
Smarajit Karmakar, Edan Lerner, Itamar Procaccia, and Jacques Zylberg, Statistical physics of elastoplastic steady states in amorphous solids: finite temperatures and strain rates, Phys. Rev. E 82, 031301 (2010), also arXiv:1006.3737.
Smarajit Karmakar, Edan Lerner, and Itamar Procaccia, Athermal nonlinear elastic constants of amorphous solids, Phys. Rev. E 82, 026105 (2010), also arXiv:1004.2198.
Smarajit Karmakar, Edan Lerner, and Itamar Procaccia, Plasticity-induced anisotropy in amorphous solids: the Bauschinger effect, Phys. Rev. E 82, 026104 (2010), also arXiv:0910.4281.
Smarajit Karmakar, Anaël Lemaître, Edan Lerner, and Itamar Procaccia, Predicting plastic flow events in athermal shear-strained amorphous solids, Phys. Rev. Lett. 104, 215502 (2010), also arXiv:1002.3487.
H. G. E. Hentschel, Smarajit Karmakar, Edan Lerner, and Itamar Procaccia, Size of plastic events in strained amorphous solids at finite temperatures, Phys. Rev. Lett. 104, 025501 (2010), also arXiv:0908.2167.

2009:

Edan Lerner and Itamar Procaccia, Scaling theory for steady-state plastic flows in amorphous solids, Phys. Rev. E 80, 026128 (2009), also arXiv:0905.3319.
Edan Lerner, Itamar Procaccia, and Jacques Zylberg, Statistical mechanics and dynamics of a three-dimensional glass-forming system, Phys. Rev. Lett. 102, 125701 (2009), also arXiv:0902.1888.
Edan Lerner and Itamar Procaccia, Locality and nonlocality in elastoplastic responses of amorphous solids, Phys. Rev. E 79, 066109 (2009), also arXiv:0901.3477.
Edan Lerner, Itamar Procaccia, Emily S. C. Ching, and H. G. E. Hentschel, Relations between material mechanical parameters and interparticle potential in amorphous solids, Phys. Rev. B 82, 180203(R) (2009), also arXiv:0902.4516.
Laurent Boué, Edan Lerner, Itamar Procaccia, and Jacques Zylberg, Predictive statistical mechanics for glass forming systems, J. Stat. Mech. P11010 (2009), also arXiv:0905.3962.
Edan Lerner, Itamar Procaccia, and Ido Regev, Quantitative theory of a time-correlation function in a one-component glass-forming liquid with anisotropic potential, Phys. Rev. E 79, 031501 (2009), also arXiv:0806.3685.

2008:

Edan Lerner and Itamar Procaccia, Quantitative theory of a relaxation function in a glass-forming system, Phys. Rev. E 78, 020501(R) (2008),also arXiv:0804.1205.

2007:

Valery Ilyin, Edan Lerner, T.-S. Lo, and Itamar Procaccia, Statistical mechanics of the glass transition in one-component liquids with an anisotropic potential, Phys. Rev. Lett. 99, 135702 (2007), also arXiv:0705.1043.