35 research outputs found
The mechanism of porosity formation during solvent-mediated phase transformations
Solvent-mediated solid-solid phase transformations often result in the
formation of a porous medium, which may be stable on long time scales or
undergo ripening and consolidation. We have studied replace- ment processes in
the KBr-KCl-H2O system using both in situ and ex situ experiments. The
replacement of a KBr crystal by a K(Br,Cl) solid solution in the presence of an
aqueous solution is facilitated by the gen- eration of a surprisingly stable,
highly anisotropic and connected pore structure that pervades the product
phase. This pore structure ensures efficient solute transport from the bulk
solution to the reacting KBr and K(Br,Cl) surfaces. The compositional profile
of the K(Br,Cl) solid solu- tion exhibits striking discontinuities across
disc-like cavities in the product phase. Similar transformation mechanisms are
probably important in con- trolling phase transformation processes and rates in
a variety of natural and man-made systems.Comment: 22 pages, 7 figure
Crystal growth in confinement
The growth of crystals confined in porous or cellular materials is ubiquitous
in Nature and industry. Confinement affects the formation of biominerals in
living organisms, of minerals in the Earth's crust and of salt crystals
damaging porous limestone monuments, and is also used to control the growth of
artificial crystals. However, the mechanisms by which confinement alters
crystal shapes and growth rates are still not elucidated. Based on novel
\textit{in situ} optical observations of (001) surfaces of NaClO and
CaCO crystals at nanometric distances from a glass substrate, we
demonstrate that new molecular layers can nucleate homogeneously and propagate
without interruption even when in contact with other solids, raising the
macroscopic crystal above them. Confined growth is governed by the peculiar
dynamics of these molecular layers controlled by the two-dimensional transport
of mass through the liquid film from the edges to the center of the contact,
with distinctive features such as skewed dislocation spirals, kinetic
localization of nucleation in the vicinity of the contact edge, and directed
instabilities. Confined growth morphologies can be predicted from the values of
three main dimensionless parameters
Compaction dynamics in ductile granular media
Ductile compaction is common in many natural systems, but the temporal
evolution of such systems is rarely studied. We observe surprising oscillations
in the weight measured at the bottom of a self-compacting ensemble of ductile
grains. The oscillations develop during the first ten hours of the experiment,
and usually persist through the length of an experiment (one week). The weight
oscillations are connected to the grain--wall contacts, and are directly
correlated with the observed strain evolution and the dynamics of grain--wall
contacts during the compaction. Here, we present the experimental results and
characteristic time constants of the system, and discuss possible reasons for
the measured weight oscillations.Comment: 11 pages, 14 figure
Cavity formation in confined growing crystals
Growing crystals form a cavity when placed against a wall. The birth of the
cavity is observed both by optical microscopy of sodium chlorate crystals
(NaClO) growing in the vicinity of a glass surface, and in simulations with
a thin film model. The cavity appears when growth cannot be maintained in the
center of the contact region due to an insufficient supply of growth units
through the liquid film between the crystal and the wall. We obtain a
non-equilibrium morphology diagram characterizing the conditions under which a
cavity appears. Cavity formation is a generic phenomenon at the origin of the
formation of growth rims observed in many experiments, and is a source of
complexity for the morphology of growing crystals in natural environments. Our
results also provide restrictions for the conditions under which compact
crystals can grow in confinement
Mechanisms of phase transformation and creating mechanical strength in a sustainable calcium carbonate cement
Calcium carbonate cements have been synthesized by mixing amorphous calcium carbonate and vaterite powders with water to form a cement paste and study how mechanical strength is created during the setting reaction. In-situ X-ray diffraction (XRD) was used to monitor the transformation of amorphous calcium carbonate (ACC) and vaterite phases into calcite and a rotational rheometer was used to monitor the strength evolution. There are two characteristic timescales of the strengthening of the cement paste. The short timescale of the order 1 h is controlled by smoothening of the vaterite grains, allowing closer and therefore adhesive contacts between the grains. The long timescale of the order 10–50 h is controlled by the phase transformation of vaterite into calcite. This transformation is, unlike in previous studies using stirred reactors, found to be mainly controlled by diffusion in the liquid phase. The evolution of shear strength with solid volume fraction is best explained by a fractal model of the paste structure
Structure of plastically compacting granular packings
The developing structure in systems of compacting ductile grains were studied
experimentally in two and three dimensions. In both dimensions, the peaks of
the radial distribution function were reduced, broadened, and shifted compared
with those observed in hard disk- and sphere systems. The geometrical
three--grain configurations contributing to the second peak in the radial
distribution function showed few but interesting differences between the
initial and final stages of the two dimensional compaction. The evolution of
the average coordination number as function of packing fraction is compared
with other experimental and numerical results from the literature. We conclude
that compaction history is important for the evolution of the structure of
compacting granular systems.Comment: 12 pages, 12 figure
4D imaging of fracturing in organic-rich shales during heating
28 pages, 7 figuresInternational audienceTo better understand the mechanisms of fracture pattern development and fluid escape in low permeability rocks, we performed time-resolved in situ X-ray tomography imaging to investigate the processes that occur during the slow heating (from 60° to 400°C) of organic-rich Green River shale. At about 350°C cracks nucleated in the sample, and as the temperature continued to increase, these cracks propagated parallel to shale bedding and coalesced, thus cutting across the sample. Thermogravimetry and gas chromatography revealed that the fracturing occurring at ~350°C was associated with significant mass loss and release of light hydrocarbons generated by the decomposition of immature organic matter. Kerogen decomposition is thought to cause an internal pressure build up sufficient to form cracks in the shale, thus providing pathways for the outgoing hydrocarbons. We show that a 2D numerical model based on this idea qualitatively reproduces the experimentally observed dynamics of crack nucleation, growth and coalescence, as well as the irregular outlines of the cracks. Our results provide a new description of fracture pattern formation in low permeability shales
Propulsive Power in Cross-Country Skiing: Application and Limitations of a Novel Wearable Sensor-Based Method During Roller Skiing
Cross-country skiing is an endurance sport that requires extremely high maximal aerobic power. Due to downhill sections where the athletes can recover, skiers must also have the ability to perform repeated efforts where metabolic power substantially exceeds maximal aerobic power. Since the duration of these supra-aerobic efforts is often in the order of seconds, heart rate, and pulmonary VO2 do not adequately reflect instantaneous metabolic power. Propulsive power (Pprop) is an alternative parameter that can be used to estimate metabolic power, but the validity of such calculations during cross-country skiing has rarely been addressed. The aim of this study was therefore twofold: to develop a procedure using small non-intrusive sensors attached to the athlete for estimating Pprop during roller-skiing and to evaluate its limits; and (2) to utilize this procedure to determine the Pprop generated by high-level skiers during a simulated distance race. Eight elite male cross-country skiers simulated a 15 km individual distance race on roller skis using ski skating techniques on a course (13.5 km) similar to World Cup skiing courses. Pprop was calculated using a combination of standalone and differential GNSS measurements and inertial measurement units. The method's measurement error was assessed using a Monte Carlo simulation, sampling from the most relevant sources of error. Pprop decreased approximately linearly with skiing speed and acceleration, and was approximated by the equation Pprop(v,v˙) = −0.54·v −0.71·v˙ + 7.26 W·kg−1. Pprop was typically zero for skiing speeds >9 m·s−1, because the athletes transitioned to the tuck position. Peak Pprop was 8.35 ± 0.63 W·kg−1 and was typically attained during the final lap in the last major ascent, while average Pprop throughout the race was 3.35 ± 0.23 W·kg−1. The measurement error of Pprop increased with skiing speed, from 0.09 W·kg−1 at 2.0 m·s−1 to 0.58 W·kg−1 at 9.0 m·s−1. In summary, this study is the first to provide continuous measurements of Pprop for distance skiing, as well as the first to quantify the measurement error during roller skiing using the power balance principle. Therefore, these results provide novel insight into the pacing strategies employed by high-level skiers