3,073 research outputs found
Chip-scale Simulations in a Quantum-correlated Synthetic Space
An efficient simulator for quantum systems is one of the original goals for
the efforts to develop a quantum computer [1]. In recent years, synthetic
dimension in photonics [2] have emerged as a potentially powerful approach for
simulation that is free from the constraint of geometric dimensionality. Here
we demonstrate a quantum-correlated synthetic crystal, based upon a
coherently-controlled broadband quantum frequency comb produced in a chip-scale
dynamically modulated lithium niobate microresonator. The time-frequency
entanglement inherent with the comb modes significantly extends the
dimensionality of the synthetic space, creating a massive nearly 400 x 400
synthetic lattice with electrically-controlled tunability. With such a system,
we are able to utilize the evolution of quantum correlations between entangled
photons to perform a series of simulations, demonstrating quantum random walks,
Bloch oscillations, and multi-level Rabi oscillations in the time and frequency
correlation space. The device combines the simplicity of monolithic
nanophotonic architecture, high dimensionality of a quantum-correlated
synthetic space, and on-chip coherent control, which opens up an avenue towards
chip-scale implementation of large-scale analog quantum simulation and
computation [1,3,4] in the time-frequency domain.Comment: 21 pages, 14 figures (including supplementary materials
Controlling rare-earth ions in a nanophotonic resonator using the ac Stark shift
On-chip nanophotonic cavities will advance quantum information science and measurement because they enable efficient interaction between photons and long-lived solid-state spins, such as those associated with rare-earth ions in crystals. The enhanced photon-ion interaction creates new opportunities for all-optical control using the ac Stark shift. Toward this end, we characterize the ac Stark interaction between off-resonant optical fields and Nd^(3+)-ion dopants in a photonic crystal resonator fabricated from yttrium orthovanadate (YVO_4). Using photon echo techniques, at a detuning of 160 MHz we measure a maximum ac Stark shift of
2π × 12.3 MHz per intracavity photon, which is large compared to both the homogeneous linewidth (Γ_h = 84 kHz) and characteristic width of isolated spectral features created through optical pumping (Γ_f ≈ 3 MHz). The photon-ion interaction strength in the device is sufficiently large to control the frequency and phase of the ions for quantum information processing applications. In particular, we discuss and assess the use of the cavity enhanced ac Stark shift to realize all-optical quantum memory and detection protocols. Our results establish the ac Stark shift as a powerful added control in rare-earth ion quantum technologies
Electrically empowered microcomb laser
Optical frequency comb underpins a wide range of applications from
communication, metrology, to sensing. Its development on a chip-scale platform
-- so called soliton microcomb -- provides a promising path towards system
miniaturization and functionality integration via photonic integrated circuit
(PIC) technology. Although extensively explored in recent years, challenges
remain in key aspects of microcomb such as complex soliton initialization, high
threshold, low power efficiency, and limited comb reconfigurability. Here we
present an on-chip laser that directly outputs microcomb and resolves all these
challenges, with a distinctive mechanism created from synergetic interaction
among resonant electro-optic effect, optical Kerr effect, and optical gain
inside the laser cavity. Realized with integration between a III-V gain chip
and a thin-film lithium niobate (TFLN) PIC, the laser is able to directly emit
mode-locked microcomb on demand with robust turnkey operation inherently built
in, with individual comb linewidth down to 600 Hz, whole-comb frequency tuning
rate exceeding Hz/s, and 100% utilization of optical
power fully contributing to comb generation. The demonstrated approach unifies
architecture and operation simplicity, high-speed reconfigurability, and
multifunctional capability enabled by TFLN PIC, opening up a great avenue
towards on-demand generation of mode-locked microcomb that is expected to have
profound impact on broad applications
Controlling rare-earth ions in a nanophotonic resonator using the ac Stark shift
On-chip nanophotonic cavities will advance quantum information science and measurement because they enable efficient interaction between photons and long-lived solid-state spins, such as those associated with rare-earth ions in crystals. The enhanced photon-ion interaction creates new opportunities for all-optical control using the ac Stark shift. Toward this end, we characterize the ac Stark interaction between off-resonant optical fields and Nd^(3+)-ion dopants in a photonic crystal resonator fabricated from yttrium orthovanadate (YVO_4). Using photon echo techniques, at a detuning of 160 MHz we measure a maximum ac Stark shift of
2π × 12.3 MHz per intracavity photon, which is large compared to both the homogeneous linewidth (Γ_h = 84 kHz) and characteristic width of isolated spectral features created through optical pumping (Γ_f ≈ 3 MHz). The photon-ion interaction strength in the device is sufficiently large to control the frequency and phase of the ions for quantum information processing applications. In particular, we discuss and assess the use of the cavity enhanced ac Stark shift to realize all-optical quantum memory and detection protocols. Our results establish the ac Stark shift as a powerful added control in rare-earth ion quantum technologies
Integrated Pockels Laser
The development of integrated semiconductor lasers has miniaturized
traditional bulky laser systems, enabling a wide range of photonic
applications. A progression from pure III-V based lasers to III-V/external
cavity structures has harnessed low-loss waveguides in different material
systems, leading to significant improvements in laser coherence and stability.
Despite these successes, however, key functions remain absent. In this work, we
address a critical missing function by integrating the Pockels effect into a
semiconductor laser. Using a hybrid integrated III-V/Lithium Niobate structure,
we demonstrate several essential capabilities that have not existed in previous
integrated lasers. These include a record-high frequency modulation speed of 2
exahertz/s (2.010 Hz/s) and fast switching at 50 MHz, both of
which are made possible by integration of the electro-optic effect. Moreover,
the device co-lases at infrared and visible frequencies via the second-harmonic
frequency conversion process, the first such integrated multi-color laser.
Combined with its narrow linewidth and wide tunability, this new type of
integrated laser holds promise for many applications including LiDAR, microwave
photonics, atomic physics, and AR/VR
Performance of CMS muon reconstruction in pp collision events at sqrt(s) = 7 TeV
The performance of muon reconstruction, identification, and triggering in CMS
has been studied using 40 inverse picobarns of data collected in pp collisions
at sqrt(s) = 7 TeV at the LHC in 2010. A few benchmark sets of selection
criteria covering a wide range of physics analysis needs have been examined.
For all considered selections, the efficiency to reconstruct and identify a
muon with a transverse momentum pT larger than a few GeV is above 95% over the
whole region of pseudorapidity covered by the CMS muon system, abs(eta) < 2.4,
while the probability to misidentify a hadron as a muon is well below 1%. The
efficiency to trigger on single muons with pT above a few GeV is higher than
90% over the full eta range, and typically substantially better. The overall
momentum scale is measured to a precision of 0.2% with muons from Z decays. The
transverse momentum resolution varies from 1% to 6% depending on pseudorapidity
for muons with pT below 100 GeV and, using cosmic rays, it is shown to be
better than 10% in the central region up to pT = 1 TeV. Observed distributions
of all quantities are well reproduced by the Monte Carlo simulation.Comment: Replaced with published version. Added journal reference and DO
Performance of CMS muon reconstruction in pp collision events at sqrt(s) = 7 TeV
The performance of muon reconstruction, identification, and triggering in CMS
has been studied using 40 inverse picobarns of data collected in pp collisions
at sqrt(s) = 7 TeV at the LHC in 2010. A few benchmark sets of selection
criteria covering a wide range of physics analysis needs have been examined.
For all considered selections, the efficiency to reconstruct and identify a
muon with a transverse momentum pT larger than a few GeV is above 95% over the
whole region of pseudorapidity covered by the CMS muon system, abs(eta) < 2.4,
while the probability to misidentify a hadron as a muon is well below 1%. The
efficiency to trigger on single muons with pT above a few GeV is higher than
90% over the full eta range, and typically substantially better. The overall
momentum scale is measured to a precision of 0.2% with muons from Z decays. The
transverse momentum resolution varies from 1% to 6% depending on pseudorapidity
for muons with pT below 100 GeV and, using cosmic rays, it is shown to be
better than 10% in the central region up to pT = 1 TeV. Observed distributions
of all quantities are well reproduced by the Monte Carlo simulation.Comment: Replaced with published version. Added journal reference and DO
Azimuthal anisotropy of charged particles at high transverse momenta in PbPb collisions at sqrt(s[NN]) = 2.76 TeV
The azimuthal anisotropy of charged particles in PbPb collisions at
nucleon-nucleon center-of-mass energy of 2.76 TeV is measured with the CMS
detector at the LHC over an extended transverse momentum (pt) range up to
approximately 60 GeV. The data cover both the low-pt region associated with
hydrodynamic flow phenomena and the high-pt region where the anisotropies may
reflect the path-length dependence of parton energy loss in the created medium.
The anisotropy parameter (v2) of the particles is extracted by correlating
charged tracks with respect to the event-plane reconstructed by using the
energy deposited in forward-angle calorimeters. For the six bins of collision
centrality studied, spanning the range of 0-60% most-central events, the
observed v2 values are found to first increase with pt, reaching a maximum
around pt = 3 GeV, and then to gradually decrease to almost zero, with the
decline persisting up to at least pt = 40 GeV over the full centrality range
measured.Comment: Replaced with published version. Added journal reference and DO
Search for a W' boson decaying to a bottom quark and a top quark in pp collisions at sqrt(s) = 7 TeV
Results are presented from a search for a W' boson using a dataset
corresponding to 5.0 inverse femtobarns of integrated luminosity collected
during 2011 by the CMS experiment at the LHC in pp collisions at sqrt(s)=7 TeV.
The W' boson is modeled as a heavy W boson, but different scenarios for the
couplings to fermions are considered, involving both left-handed and
right-handed chiral projections of the fermions, as well as an arbitrary
mixture of the two. The search is performed in the decay channel W' to t b,
leading to a final state signature with a single lepton (e, mu), missing
transverse energy, and jets, at least one of which is tagged as a b-jet. A W'
boson that couples to fermions with the same coupling constant as the W, but to
the right-handed rather than left-handed chiral projections, is excluded for
masses below 1.85 TeV at the 95% confidence level. For the first time using LHC
data, constraints on the W' gauge coupling for a set of left- and right-handed
coupling combinations have been placed. These results represent a significant
improvement over previously published limits.Comment: Submitted to Physics Letters B. Replaced with version publishe
Compressed representation of a partially defined integer function over multiple arguments
In OLAP (OnLine Analitical Processing) data are analysed in an n-dimensional cube. The cube may be represented as a partially defined function over n arguments. Considering that often the function is not defined everywhere, we ask: is there a known way of representing the function or the points in which it is defined, in a more compact manner than the trivial one
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