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Multilateralism under Strain: The Challenges of the European Union’s Engagement With International Institutions
Multilateralism is under strain. The election of US President Donald Trump has brought about a new challenge to the rules based international order. The EU, itself a form of multilateral cooperation, also faces internal challenges, including the migration crisis, terrorism, growing populism, and disrespect for the rule of law. This working paper discusses how the EU can respond to such internal and external challenges when engaging with multilateral institutions. At a time when multilateralism is increasingly challenged, the EU requires a clear strategy that links its general support for multilateralism with specific international objectives
INEFFICIENCIES OF INSTITUTIONAL ARRANGEMENTS IN INTERNATIONAL WHEAT TRADE A PRELIMINARY INVESTIGATION OF EASTERN EUROPE AND SOUTH AFRICA
The beginning of the new century marked important changes in the world wheat market. These changes relate to traditional wheat export countries. In future, non-traditional wheat export countries in Eastern Europe, such as the Ukraine, may increasingly put pressure on traditional wheat suppliers in the world market.International Relations/Trade,
Quantum Nature of Edge Magnetism in Graphene
It is argued that the subtle crossover from decoherence-dominated classical
magnetism to fluctuation-dominated quantum magnetism is experimentally
accessible in graphene nanoribbons. We show that the width of a nanoribbon
determines whether the edge magnetism is on the classical side, on the quantum
side, or in between. In the classical regime, decoherence is dominant and leads
to static spin polarizations at the ribbon edges, which are well described by
mean-field theories. The quantum Zeno effect is identified as the basic
mechanism which is responsible for the spin polarization and thereby enables
the application of graphene in spintronics. On the quantum side, however, the
spin polarization is destroyed by dynamical processes. The great tunability of
graphene magnetism thus offers a viable route for the study of the
quantum-classical crossover.Comment: 5 pages, 3 figure
Generic First-Order vs. Continuous Quantum Nucleation of Supersolidity
We analyze the nucleation of supersolid order out of the superfluid ground
state of bosons on the triangular lattice. While the stability of supersolidity
against phase separation in this system is by now well established for
nearest-neighbor and long-range dipolar interactions, relevant for
two-dimensional arrays of ultra-cold polar molecules, here we address directly
the nature of the superfluid-to-supersolid transition. Based on symmetry
arguments and quantum Monte Carlo simulations, we conclude that this quantum
phase transition is driven first-order beyond the line of particle-hole
symmetry. Along this line, the transition is continuous and its scaling
behavior consistent with the three-dimensional (3D) XY universality class. We
relate this finding to a 3D Z6 clock model description of the enlarged symmetry
of the solid order parameter field. In the generic case however, the symmetry
reduces to that of a 3D Z3 clock model, which reflects the first-order nature
of the generic superfluid-to-supersolid quantum phase transition on the
triangular lattice.Comment: 4 pages, 5 figure
The Impact of Biofuel Production on Food Security: A Briefing Paper with a Particular Emphasis on Maize-to-Ethanol Production
A multi-feedstock approach is crucial for sustainable biofuel production in South Africa. In respect of ethanol production, biofuel producers should be allowed to draw on a range of starch-based crops including maize. A multi-feedstock approach will enable producers to select crops best suited to the agro-climate of the regions where their plants are situated and to minimize logistic costs by sourcing crops grown closest to their plants. In recent months, plans to use maize to produce ethanol have raised concerns that this could jeopardize food security in South Africa.biofuel production, food security, maize, Food Security and Poverty, Resource /Energy Economics and Policy, Q10, Q27,
Effective models for strong electronic correlations at graphene edges
We describe a method for deriving effective low-energy theories of electronic
interactions at graphene edges. Our method is applicable to general edges of
honeycomb lattices (zigzag, chiral, and even disordered) as long as localized
low-energy states (edge states) are present. The central characteristic of the
effective theories is a dramatically reduced number of degrees of freedom. As a
consequence, the solution of the effective theory by exact diagonalization is
feasible for reasonably large ribbon sizes. The quality of the involved
approximations is critically assessed by comparing the correlation functions
obtained from the effective theory with numerically exact quantum Monte-Carlo
calculations. We discuss effective theories of two levels: a relatively
complicated fermionic edge state theory and a further reduced Heisenberg spin
model. The latter theory paves the way to an efficient description of the
magnetic features in long and structurally disordered graphene edges beyond the
mean-field approximation.Comment: 13 pages, 9 figure
High-Resolution Near-Field Raman Microscopy of Single-Walled Carbon Nanotubes
We present near-field Raman spectroscopy and imaging of single isolated single-walled carbon nanotubes with a spatial resolution of ≈25  nm. The near-field origin of the image contrast is confirmed by the measured dependence of the Raman scattering signal on tip-sample distance and the unique polarization properties. The method is used to study local variations in the Raman spectrum along a single single-walled carbon nanotube
Geometry fluctuations in a two-dimensional quantum antiferromagnet
The paper considers the effects of random fluctuations of the local spin
connectivities (fluctuations of the geometry) on ground state properties of a
two-dimensional quantum antiferromagnet. We analyse the behavior of spins
described by the Heisenberg model as a function of what we call phason flip
disorder, following a terminology used for aperiodic systems. The calculations
were carried out both within linear spin wave theory and using quantum Monte
Carlo simulations. An "order by disorder" phenomenon is observed in this model,
wherein antiferromagnetism is found to be enhanced by phason disorder. The
value of the staggered order parameter increases with the number of defects,
accompanied by an increase in the ground state energy of the system.Comment: 5 pages, 7 figures. Shortened and corrected version (as accepted for
publication in Physical Review B
A phason disordered two dimensional quantum antiferromagnet
We examine a novel type of disorder in quantum antiferromagnets. Our model
consists of localized spins with antiferromagnetic exchanges on a bipartite
quasiperiodic structure, which is geometrically disordered in such a way that
no frustration is introduced. In the limit of zero disorder, the structure is
the perfect Penrose rhombus tiling. This tiling is progressively disordered by
augmenting the number of random "phason flips" or local tile-reshuffling
operations. The ground state remains N\'eel ordered, and we have studied its
properties as a function of increasing disorder using linear spin wave theory
and quantum Monte Carlo. We find that the ground state energy decreases,
indicating enhanced quantum fluctuations with increasing disorder. The magnon
spectrum is progressively smoothed, and the effective spin wave velocity of low
energy magnons increases with disorder. For large disorder, the ground state
energy as well as the average staggered magnetization tend towards limiting
values characteristic of this type of randomized tilings.Comment: 5 pages, 7 figure
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