212 research outputs found
“Društveno korisno” u javnom emitiranju: između idealizma i utilitarizma – Griersonovski elementi tradicije
The paper contains a discussion of the concept the socially useful in connection
with broadcasting and especially in relationship to public service broadcasting.
Tracing the concept back to John Reith’s influential book Broadcast
over Britain from 1924, written on the background of the author’s experiences
in establishing the BBC, the paper introduces a less known source for the establishing
of the kind of standards that have come to be linked to the idea of
broadcasting programming as socially useful activity in the person of John
Grierson, pioneer of the British documentary movement. The paper makes a
comparison of the underlying social philosophy of the two Scots, claiming that
Grierson´s role may have been underestimated when taking into the account
how the documentary film practices of the BBC can be traced directly to the
influence of the British documentary movement of the 30s and 40s.Rad sadrži raspravu koncepta društveno korisnog u vezi s emitiranjem i posebice u
odnosu s javnim emitiranjem. Povezujući koncept s John Reithovom utjecajnom
knjigom Broadcast over Britain iz 1924, napisanoj na temelju autorovih iskustva u
osnivanju BBC-a, rad uvodi i predstavlja manje poznati izvor za formiranje standarda
koji se povezuju s idejom emitiranja programa kao društveno korisnoj aktivnosti
u osobi Johna Griersona, pionira britanskog dokumentarnog pokreta. Rad
uspoređuje temeljne socijalne filozofije dva Škota, tvrdeći da je Griersonova uloga
moguće podcijenjena kada se uzme u obzir kako se dokumentarna filmska praksa
BBC-a može direktno povezati s utjecajem britanskog dokumentarnog pokreta 30-
tih i 40-tih godina prošlog stoljeća
History-dependent friction and slow slip from time-dependent microscopic junction laws studied in a statistical framework
To study the microscopic origins of friction, we build a framework to
describe the collective behaviour of a large number of individual
micro-junctions forming a macroscopic frictional interface. Each micro-junction
can switch in time between two states: A pinned state characterized by a
displacement-dependent force, and a slipping state characterized by a
time-dependent force. Instead of tracking each micro-junction individually, the
state of the interface is described by two coupled distributions for (i) the
stretching of pinned junctions and (ii) the time spent in the slipping state.
We show how this framework represents an overarching structure for important
models existing in the friction literature. We then use it to study
systematically the effect of the time-scale that controls the duration of the
slipping state. We first find the steady-state friction force as a function of
the sliding velocity. As the framework allows for a whole family of
micro-junction behaviour laws, we show how these laws can be chosen to obtain
monotonic (strengthening or weakening) or non-monotonic velocity dependence at
the macroscale. By then considering transient situations, we predict that the
macroscopic static friction coefficient is strongly influenced by the way the
interface was prepared, in particular by the slip dynamics of the previous
sliding event. We also show that slow slip spontaneously occurs in the
framework for a wide range of behaviour laws.Comment: 20 pages, 10 figure
Statistics of the separation between sliding rigid rough surfaces: Simulations and extreme value theory approach
When a rigid rough solid slides on a rigid rough surface, it experiences a
random motion in the direction normal to the average contact plane. Here,
through simulations of the separation at single-point contact between
self-affine topographies, we characterize the statistical and spectral
properties of this normal motion. In particular, its rms amplitude is much
smaller than that of the equivalent roughness of the two topographies, and
depends on the ratio of the slider's lateral size over a characteristic
wavelength of the topography. In addition, due to the non-linearity of the
sliding contact process, the normal motion's spectrum contains wavelengths
smaller than the smallest wavelength present in the underlying topographies. We
show that the statistical properties of the normal motion's amplitude are well
captured by a simple analytic model based on the extreme value theory
framework, extending its applicability to sliding-contact-related topics
On the speed of fast and slow rupture fronts along frictional interfaces
The transition from stick to slip at a dry frictional interface occurs
through the breaking of the junctions between the two contacting surfaces.
Typically, interactions between the junctions through the bulk lead to rupture
fronts propagating from weak and/or highly stressed regions, whose junctions
break first. Experiments find rupture fronts ranging from quasi-static fronts
with speeds proportional to external loading rates, via fronts much slower than
the Rayleigh wave speed, and fronts that propagate near the Rayleigh wave
speed, to fronts that travel faster than the shear wave speed. The mechanisms
behind and selection between these fronts are still imperfectly understood.
Here we perform simulations in an elastic 2D spring--block model where the
frictional interaction between each interfacial block and the substrate arises
from a set of junctions modeled explicitly. We find that a proportionality
between material slip speed and rupture front speed, previously reported for
slow fronts, actually holds across the full range of front speeds we observe.
We revisit a mechanism for slow slip in the model and demonstrate that fast
slip and fast fronts have a different, inertial origin. We highlight the long
transients in front speed even in homogeneous interfaces, and we study how both
the local shear to normal stress ratio and the local strength are involved in
the selection of front type and front speed. Lastly, we introduce an
experimentally accessible integrated measure of block slip history, the Gini
coefficient, and demonstrate that in the model it is a good predictor of the
history-dependent local static friction coefficient of the interface. These
results will contribute both to building a physically-based classification of
the various types of fronts and to identifying the important mechanisms
involved in the selection of their propagation speed.Comment: 29 pages, 21 figure
Material as actor in the enactment of social norms: Engaging with a sociomaterial perspective in childhood studies to avoid the ‘traps of closure’
This article employs a sociomaterial perspective and explores how material artefacts take part in the enactment of social norms by analysing empirical examples from two different childhood studies projects in Norway. Drawing on interview data with tweens, (children aged 8–12), and observational data from an early education and care institution (ECEC), we argue that material, in this case toys and makeup, make a difference in the enactment of social norms in children's everyday lives. Our aim is to demonstrate the malleability of a sociomaterial perspective and show how this can lead to new insights and open childhood studies as a field.publishedVersio
Slow slip and the transition from fast to slow fronts in the rupture of frictional interfaces
The failure of the population of micro-junctions forming the frictional
interface between two solids is central to fields ranging from biomechanics to
seismology. This failure is mediated by the propagation along the interface of
various types of rupture fronts, covering a wide range of velocities. Among
them are so-called slow fronts, which are recently discovered fronts much
slower than the materials' sound speeds. Despite intense modelling activity,
the mechanisms underlying slow fronts remain elusive. Here, we introduce a
multi-scale model capable of reproducing both the transition from fast to slow
fronts in a single rupture event and the short-time slip dynamics observed in
recent experiments. We identify slow slip immediately following the arrest of a
fast front as a phenomenon sufficient for the front to propagate further at a
much slower pace. Whether slow fronts are actually observed is controlled both
by the interfacial stresses and by the width of the local distribution of
forces among micro-junctions. Our results show that slow fronts are
qualitatively different from faster fronts. Since the transition from fast to
slow fronts is potentially as generic as slow slip, we anticipate that it might
occur in the wide range of systems in which slow slip has been reported,
including seismic faults.Comment: 35 pages, 5 primary figures, 6 supporting figures. Post-print version
with improvements from review process include
Using Computational Essays to Scaffold Professional Physics Practice
This article describes a curricular innovation designed to help students
experience authentic physics inquiry with an emphasis on computational modeling
and scientific communication. The educational design centers on a new type of
assignment called a computational essay, which was developed and implemented
over the course of two semesters of an intermediate electricity and magnetism
course at the University of Oslo, Norway. We describe the motivation, learning
goals, and scaffolds used in the computational essay project, with the
intention that other educators will be able to replicate and adapt our design.
We also report on initial findings from this implementation, including key
features of student-written computational essays, student reflections on the
inquiry process, and self-reported conceptual and attitudinal development.
Based on these findings, we argue that computational essays can serve a key
role in introducing students to open-ended, inquiry-based work and setting the
foundation for future computational research and studies.Comment: Submitted to the European Journal of Physic
Diffusion-driven frictional aging in silicon carbide
Friction is the force resisting relative motion of objects. The force depends
on material properties, loading conditions and external factors such as
temperature and humidity, but also contact aging has been identified as a
primary factor. Several aging mechanisms have been proposed, including
increased "contact quantity" due to plastic or elastic creep and enhanced
"contact quality" due to formation of strong interfacial bonds. While proposed
mechanisms for frictional aging have been dependent upon the presence of a
normal force, this factor is not a fundamental prerequisite for the occurrence
of aging. In light of this, we present a novel demonstration of a substantial
frictional aging effect within a cubic silicon carbide system, even when a
normal force is entirely absent. Our observations indicate that the
time-evolution of the frictional aging effect follows a logarithmic behavior,
which is a pattern that has been previously observed in numerous other
materials. To explain this behavior, we provide a derivation that is rooted in
basic statistical mechanics, demonstrating that surface diffusion, a phenomenon
that serves to minimize surface energy in the interface region, can account for
the observed behavior. Upon application of a normal force, the friction force
is enhanced owing to the presence of plastic creep. Although aging resulting
from plastic and elastic creep is widely recognized and incorporated into most
friction laws, diffusion-driven aging has received comparatively less
attention. The ultimate objective is to develop or redesign friction laws by
incorporating the microscopic behavior, with the potential to enhance their
effectiveness
Volume changes in solids induced by chemical alteration
It is a fundamental issue in material
science to understand the mechanical effects of chemical alterations. Often the
replacement of one chemical component by another in a solid induces local volume
changes. Experiments on chemical alteration in “model” materials reveal an intricate
dynamics of elastic stress build-up, fracturing and creation of porosity. In that way
permeability is increased and provides a positive feedback on the process rate.
Important examples from geology are presented
Minimal model for slow, sub-Rayleigh, supershear, and unsteady rupture propagation along homogeneously loaded frictional interfaces
International audienceIn nature and experiments, a large variety of rupture speeds and front modes along frictional interfaces are observed. Here, we introduce a minimal model for the rupture of homogeneously loaded interfaces with velocity strengthening dynamic friction, containing only two dimensionless parameters; τ, which governs the prestress, and ᾱ which is set by the dynamic viscosity. This model contains a large variety of front types, including slow fronts, sub-Rayleigh fronts, super-shear fronts, slip pulses, cracks, arresting fronts and fronts that alternate between arresting and propagating phases. Our results indicate that this wide range of front types is an inherent property of frictional systems with velocity strengthening branches
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