12,024 research outputs found
Alexander Invariants of Complex Hyperplane Arrangements
Let A be an arrangement of complex hyperplanes. The fundamental group of the
complement of A is determined by a braid monodromy homomorphism from a finitely
generated free group to the pure braid group. Using the Gassner representation
of the pure braid group, we find an explicit presentation for the Alexander
invariant of A. From this presentation, we obtain combinatorial lower bounds
for the ranks of the Chen groups of A. We also provide a combinatorial
criterion for when these lower bounds are attained.Comment: 26 pages; LaTeX2e with amscd, amssymb package
Characteristic varieties of arrangements
The k-th Fitting ideal of the Alexander invariant B of an arrangement A of n
complex hyperplanes defines a characteristic subvariety, V_k(A), of the complex
algebraic n-torus. In the combinatorially determined case where B decomposes as
a direct sum of local Alexander invariants, we obtain a complete description of
V_k(A). For any arrangement A, we show that the tangent cone at the identity of
this variety coincides with R^1_k(A), one of the cohomology support loci of the
Orlik-Solomon algebra. Using work of Arapura and Libgober, we conclude that all
positive-dimensional components of V_k(A) are combinatorially determined, and
that R^1_k(A) is the union of a subspace arrangement in C^n, thereby resolving
a conjecture of Falk. We use these results to study the reflection arrangements
associated to monomial groups.Comment: LaTeX2e, 20 pages. A reference to Libgober's recent work in
math.AG/9801070 is added. Several points are clarified, a new example is
include
The boundary manifold of a complex line arrangement
We study the topology of the boundary manifold of a line arrangement in CP^2,
with emphasis on the fundamental group G and associated invariants. We
determine the Alexander polynomial Delta(G), and more generally, the twisted
Alexander polynomial associated to the abelianization of G and an arbitrary
complex representation. We give an explicit description of the unit ball in the
Alexander norm, and use it to analyze certain Bieri-Neumann-Strebel invariants
of G. From the Alexander polynomial, we also obtain a complete description of
the first characteristic variety of G. Comparing this with the corresponding
resonance variety of the cohomology ring of G enables us to characterize those
arrangements for which the boundary manifold is formal.Comment: This is the version published by Geometry & Topology Monographs on 22
February 200
Dialing in single-site reactivity of a supported calixarene-protected tetrairidium cluster catalyst.
A closed Ir4 carbonyl cluster, 1, comprising a tetrahedral metal frame and three sterically bulky tert-butyl-calix[4]arene(OPr)3(OCH2PPh2) (Ph = phenyl; Pr = propyl) ligands at the basal plane, was characterized with variable-temperature 13C NMR spectroscopy, which show the absence of scrambling of the CO ligands at temperatures up to 313 K. This demonstration of distinct sites for the CO ligands was found to extend to the reactivity and catalytic properties, as shown by selective decarbonylation in a reaction with trimethylamine N-oxide (TMAO) as an oxidant, which, reacting in the presence of ethylene, leads to the selective bonding of an ethyl ligand at the apical Ir site. These clusters were supported intact on porous silica and found to catalyze ethylene hydrogenation, and a comparison of the kinetics of the single-hydrogenation reaction and steady-state hydrogenation catalysis demonstrates a unique single-site catalyst-with each site having the same catalytic activity. Reaction orders in the catalytic ethylene hydrogenation reaction of approximately 1/2 and 0 for H2 and C2H4, respectively, nearly match those for conventional noble-metal catalysts. In contrast to oxidative decarbonylation, thermal desorption of CO from silica-supported cluster 1 occurred exclusively at the basal plane, giving rise to sites that do not react with ethylene and are catalytically inactive for ethylene hydrogenation. The evidence of distinctive sites on the cluster catalyst leads to a model that links to hydrogen-transfer catalysis on metals-involving some surface sites that bond to both hydrocarbon and hydrogen and are catalytically engaged (so-called "*" sites) and others, at the basal plane, which bond hydrogen and CO but not hydrocarbon and are reservoir sites (so-called "S" sites)
Lifelong Neural Predictive Coding: Learning Cumulatively Online without Forgetting
In lifelong learning systems, especially those based on artificial neural
networks, one of the biggest obstacles is the severe inability to retain old
knowledge as new information is encountered. This phenomenon is known as
catastrophic forgetting. In this article, we propose a new kind of
connectionist architecture, the Sequential Neural Coding Network, that is
robust to forgetting when learning from streams of data points and, unlike
networks of today, does not learn via the immensely popular back-propagation of
errors. Grounded in the neurocognitive theory of predictive processing, our
model adapts its synapses in a biologically-plausible fashion, while another,
complementary neural system rapidly learns to direct and control this
cortex-like structure by mimicking the task-executive control functionality of
the basal ganglia. In our experiments, we demonstrate that our self-organizing
system experiences significantly less forgetting as compared to standard neural
models and outperforms a wide swath of previously proposed methods even though
it is trained across task datasets in a stream-like fashion. The promising
performance of our complementary system on benchmarks, e.g., SplitMNIST, Split
Fashion MNIST, and Split NotMNIST, offers evidence that by incorporating
mechanisms prominent in real neuronal systems, such as competition, sparse
activation patterns, and iterative input processing, a new possibility for
tackling the grand challenge of lifelong machine learning opens up.Comment: Key updates including results on standard benchmarks, e.g., split
mnist/fmnist/not-mnist. Task selection/basal ganglia model has been
integrate
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