18,744 research outputs found
A Birkhoff connection between quantum circuits and linear classical reversible circuits
Birkhoff's theorem tells how any doubly stochastic matrix can be decomposed as a weighted sum of permutation matrices. Similar theorems on unitary matrices reveal a connection between quantum circuits and linear classical reversible circuits. It triggers the question whether a quantum computer can be regarded as a superposition of classical reversible computers
CLIC Background Studies and optimization of the innermost tracker elements
The harsh machine background at the Compact Linear Collider (CLIC) forms a
strong constraint on the design of the innermost part of the tracker. For the
CLIC Conceptual Design Report, the detector concepts developed for the
International Linear Collider (ILC) were adapted to the CLIC environment. We
present the new layout for the Vertex Detector and the Forward Tracking Disks
of the CLIC detector concepts, as well as the background levels in these
detectors. We also study the dependence of the background rates on technology
parameters like thickness of the active layer and detection threshold.Comment: 7 pages, 5 figures, LCWS 201
Method to make a single-step etch mask for 3D monolithic nanostructures
Current nanostructure fabrication by etching is usually limited to planar
structures as they are defined by a planar mask. The realisation of
three-dimensional (3D) nanostructures by etching requires technologies beyond
planar masks. We present a method to fabricate a 3D mask that allows to etch
three-dimensional monolithic nanostructures by using only CMOS-compatible
processes. The mask is written in a hard-mask layer that is deposited on two
adjacent inclined surfaces of a Si wafer. By projecting in single step two
different 2D patterns within one 3D mask on the two inclined surfaces, the
mutual alignment between the patterns is ensured. Thereby after the mask
pattern is defined, the etching of deep pores in two oblique directions yields
a three-dimensional structure in Si. As a proof of concept we demonstrate 3D
mask fabrication for three-dimensional diamond-like photonic band gap crystals
in silicon. The fabricated crystals reveal a broad stop gap in optical
reflectivity measurements. We propose how 3D nanostructures with five different
Bravais lattices can be realised, namely cubic, tetragonal, orthorhombic,
monoclinic, and hexagonal, and demonstrate a mask for a 3D hexagonal crystal.
We also demonstrate the mask for a diamond-structure crystal with a 3D array of
cavities. In general, the 2D patterns for the different surfaces can be
completely independent and still be in perfect mutual alignment. Indeed, we
observe an alignment accuracy of better than 3.0 nm between the 2D mask
patterns on the inclined surfaces, which permits one to etch well-defined
monolithic 3D nanostructures.Comment: 18 pages, 10 figure
Extracting the top-quark running mass using +1-jet events produced at the Large Hadron Collider
We present the calculation of the next-to-leading order QCD corrections for
top-quark pair production in association with an additional jet at hadron
colliders, using the modified minimal subtraction scheme to renormalize the
top-quark mass. The results are compared to measurements at the Large Hadron
Collider run I. In particular, we determine the top-quark running mass from a
fit of the theoretical results presented here to the LHC data
Spatial homogeneity of optically switched semiconductor photonic crystals and of bulk semiconductors
This paper discusses free carrier generation by pulsed laser fields as a
mechanism to switch the optical properties of semiconductor photonic crystals
and bulk semiconductors on an ultrafast time scale. Requirements are set for
the switching magnitude, the time-scale, the induced absorption as well as the
spatial homogeneity, in particular for silicon at lambda= 1550 nm. Using a
nonlinear absorption model, we calculate carrier depth profiles and define a
homogeneity length l_hom. Homogeneity length contours are visualized in a plane
spanned by the linear and two-photon absorption coefficients. Such a
generalized homogeneity plot allows us to find optimum switching conditions at
pump frequencies near v/c= 5000 cm^{-1} (lambda= 2000 nm). We discuss the
effect of scattering in photonic crystals on the homogeneity. We experimentally
demonstrate a 10% refractive index switch in bulk silicon within 230 fs with a
lateral homogeneity of more than 30 micrometers. Our results are relevant for
switching of modulators in absence of photonic crystals
Geiger-Mode Avalanche Photodiodes in Particle Detection
It is well known that avalanche photodiodes operated in the Geiger mode above
the breakdown voltage offer a virtually infinite sensitivity and time accuracy
in the picosecond range that can be used for single photon detection. However,
their performance in particle detection remains still unexplored. In this
contribution, we are going to expose the different steps that we have taken in
order to prove the efficiency of Geiger mode avalanche photodiodes in the
aforementioned field. In particular, we will present an array of pixels of
1mmx1mm fabricated with a standard CMOS technology for characterization in a
test beam.Comment: 7 pages, 2 figures, Proceedings of LCWS1
Physical limitations to the spatial resolution of solid-state detectors
In this paper we explore the effect of -ray emission, fluctuations in
th e signal deposition on the detection of charged particles in silicon-based
detec tors. We show that these two effects ultimately limit the resolution that
can be achieved by interpolation of the signal in finely segmented
position-sensitive solid-state devices.Comment: 5 page
Top quark precision physics at the International Linear Collider
Top quark production in the process at a future
linear electron positron collider with polarized beams is a powerful tool to
determine the scale of new physics. Studies at the \ttbar threshold will
allow for precise determination of the top quark mass in a well defined
theoretical framework. At higher energies vector, axial vector and tensorial CP
conserving couplings can be separately determined for the photon and the
component in the electro-weak production process. The sensitivity to new
physics would be dramatically improved w.r.t. to what expected from LHC for
electroweak couplings.Comment: White paper for Snowmass CSS 201
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