Friction law and hysteresis in granular materials

The macroscopic friction of particulate materials often weakens as the flow rate is increased, leading to potentially disastrous intermittent phenomena including earthquakes and landslides. We theoretically and numerically study this phenomenon in simple granular materials. We show that velocity weakening, corresponding to a nonmonotonic behavior in the friction law, mu(I), is present even if the dynamic and static microscopic friction coefficients are identical, but disappears for softer particles. We argue that this instability is induced by endogenous acoustic noise, which tends to make contacts slide, leading to faster flow and increased noise. We show that soft spots, or excitable regions in the materials, correspond to rolling contacts that are about to slide, whose density is described by a nontrivial exponent theta(s). We build a microscopic theory for the nonmonotonicity of mu(I), which also predicts the scaling behavior of acoustic noise, the fraction of sliding contacts chi, and the sliding velocity, in terms of theta(s). Surprisingly, these quantities have no limit when particles become infinitely hard, as confirmed numerically. Our analysis rationalizes previously unexplained observations and makes experimentally testable predictions.

Local excitations in amorphous solids

Wencheng Ji

Amorphous solids are structurally disordered. They are very common and include glasses, colloids, and granular materials, but are far less understood than crystalline solids. Key aspects of these materials are controlled by the presence of excitations in which a group of particles rearranges. This motion can be triggered by (a) quantum fluctuations associated with two-level systems (TLS), which dominate the low temperature properties of conventional glasses and have practical importance on superconducting qubits; by (b) thermal fluctuations associated with activations, which are related to the famous and challenging

glass transition'' problem; or by (c) exerting an external stress or strain associated with shear transformations, which control the plasticity. Hence, it is important to understand how temperature and system preparation determines the density and geometry of these excitations. The possible unification of these excitations into a common description is also a fundamental problem.  These local excitations are thought to have a close relationship with

Quasi-localised modes (QLMs)'' which are present in the low-frequency vibrational spectrum in amorphous solids. Understanding the properties of QLMs and clarifying the relation between QLMs and these local excitations are important to the study of the latter. In this thesis: (1) we provide a theory for the QLMs, D_L(omega) ~ omega^alpha, that establishes the link between QLMs and shear transformations for systems under quasi-static loading. It predicts two regimes depending on the density of shear transformations P(x)~ x^theta (with x the additional stress needed to trigger a shear transformation). If theta>1/4, alpha=4 and a finite fraction of quasi-localised modes form shear transformations, whose amplitudes vanish at low frequencies. If theta

EPFL2021

The effect of high relative humidity on a network of water-sensitive particles (couscous) as revealed by in situ X-ray tomography

Edward Ando, Gioacchino Viggiani

Water significantly influences the mechanical behaviour of all granular materials but none as much as hygroscopic amorphous particles. With sufficiently high water content, particles can swell, agglomerate and their mechanical properties can be reduced, having direct effects on the macroscopic response of the material. In the food and pharmaceutical industry this can cause loss of product functionality. Despite their relevance, very little is known about the microscopic processes that induce these phenomena. Previous studies focused on single particle behaviour, the strength of agglomerated particles and the material flowability, leaving unexplored the link connecting the particle behaviour and the bulk response. This experimental study aims to investigate this aspect with quantitative measurements at both particle and macroscopic scales. A sample of fine couscous is exposed to a high relative humidity (RH) air flow, while being subjected to oedometric conditions, in order to reproduce the storage-silo conditions. In the meantime, X-ray tomographies are acquired continuously and the resulting images are analysed. The designed spatial resolution allows each particle of the sample to be identified and tracked, allowing volumetric evolution to be compared to the properties of the whole sample. The analysis reveals a dilation-compaction macroscopic behaviour, a result of the competition between the particle swelling and the higher deformability as the water content increases. The number, orientations and inter-particle contacts are computed. Their area is related to the applied boundary conditions, and is found to be consistent with the particle swelling and dependent on the applied stress direction.

ROYAL SOC CHEMISTRY2022

Etude de l'origine et de la croissance de particules submicrométriques dans les plasmas radiofréquence réactifs

Christian Deschenaux

The formation of sub-micron sized particulates has been studied in a low pressure (0.1 mbar) radio-frequency (13.56 MHz) capacitively coupled plasma discharge. Particles are studied in situ by infrared absorption spectroscopy, laser illumination and Cavity Ring Down Absorption Spectroscopy. Transmission Electron Microscopy was applied ex situ for particulates collected during the plasma. We propose that two principal mechanisms may be involved in the formation of these particulates: formation and trapping of negative ions in the gaseous phase, and the recycling of material deposited on the electrodes during the discharge, by film erosion or delamination. The relative importance of these two mechanisms was studied in silane, methane, ethylene and acetylene plasmas. The growth of the particulates in silane plasmas, monitored with Infrared and Cavity Ring Down Absorption Spectroscopy, allowed us to distinguish an increasing volume growth phase followed by an agglomeration phase at constant volume, in agreement with the literature. A slight powder and film recycling effect is detected as the experiments are repeated, as observed by an increasing particle size. The hydrogen content of powder formed in silane plasmas was estimated in situ by infrared absorption spectroscopy and changes in the infrared absorption spectrum could be observed for silane diluted with hydrogen and argon. In particular, the porous structure of the powder was observed from the high content of surface related vibration bonds relative to bulk related bonds. Photoluminescence was detected for the particles at 2.15eV that could possibly be attributed to the crystalline structure of the particles. Infrared Absorption Spectroscopy and mass spectrometry applied in situ showed that acetylenic compounds are preferentially produced in methane, ethylene and acetylene plasmas and that the hydrogen content of the other species produced in these plasmas depends on the initial gas hydrogen content. Negative ions were evidenced in these plasmas and a polymerization reaction is proposed between acetylene and C2nHx- negative ions to explain the formation of particle's precursors. The formation of aromatic structures is suggested for n>3. The different relative abundance of C2Hx- ions is proposed to explain the different powder production rates with different initial gases or different fluxes. Hydrogen may inhibit the formation of high-mass negative ions and particles. Fast growth of spherical amorphous carbon particles (∼100s) was observed for a low pressure (0.1 mbar) acetylene plasma. The sp3 structure was confirmed in situ by infrared absorption spectroscopy. Slow growth (∼1000s) of irregularly shaped particles is observed for methane plasmas at the same pressure and power. Particle heterogeneity was studied with Transmission Electron Microscopy and showed graphitic onions, multiwalled nanotubes, flakes and agglomerates attributed to the erosion or the delamination of the deposited carbon layer. The influence of the recycling of the deposited layer on the powder formation was observed in situ from enhanced particle formation as the experiments were repeated. A similar behavior was observed for discharges containing mixtures of hexamethyldisiloxane, oxygen and helium. Keeping in mind that the control of powder homogeneity implies a control over the reactor contamination and its history, we conclude that an important part of the particulates formed in the discharges studied depends on the gas phase reactions, determined by the plasma chemistry.

EPFL2002

Etude de l'origine et de la croissance de particules submicrométriques dans les plasmas radiofréquence réactifs

Christian Deschenaux

EPFL2002