65,248 research outputs found
Seeing is believing: How people fail to identify fake images on the web
The growing ease with which digital images can be convincingly manipulated and widely distributed on the Internet makes viewers increasingly susceptible to visual misinformation and deception. In situations where ill-intentioned individuals seek to deliberately mislead and influence viewers through fake online images, the harmful consequences could be substantial. We describe an exploratory study of how individuals react, respond to, and evaluate the authenticity of images that accompany online stories in Internet-enabled communications channels. Our preliminary findings support the assertion that people perform poorly at detecting skillful image manipulation, and that they often fail to question the authenticity of images even when primed regarding image forgery through discussion. We found that viewers make credibility evaluation based mainly on non-image cues rather than the content depicted. Moreover, our study revealed that in cases where context leads to suspicion, viewers apply post-hoc analysis to support their suspicions regarding the authenticity of the image
Anomalous Phase Shift of Quantum Oscillations in 3D Topological Semimetals
Berry phase physics is closely related to a number of topological states of
matter. Recently discovered topological semimetals are believed to host a
nontrivial Berry phase to induce a phase shift of in the
quantum oscillation ( for hole and for electron carriers). We
theoretically study the Shubnikov-de Haas oscillation of Weyl and Dirac
semimetals, taking into account their topological nature and inter-Landau band
scattering. For a Weyl semimetal with broken time-reversal symmetry, the phase
shift is found to change nonmonotonically and go beyond known values of and . For a Dirac semimetal or paramagnetic Weyl semimetal,
time-reversal symmetry leads to a discrete phase shift of or , as a function of the Fermi energy. Different from the previous works, we
find that the topological band inversion can lead to beating patterns in the
absence of Zeeman splitting. We also find the resistivity peaks should be
assigned integers in the Landau index plot. Our findings may account for recent
experiments in CdAs and should be helpful for exploring the Berry phase
in various 3D systems.Comment: 5 pages, 3 figures, with Supplemental Materia
NIMBUS-5 sounder data processing system. Part 2: Results
The Nimbus-5 spacecraft carries infrared and microwave radiometers for sensing the temperature distribution of the atmosphere. Methods developed for obtaining temperature profiles from the combined set of infrared and microwave radiation measurements are described. Algorithms used to determine (a) vertical temperature and water vapor profiles, (b) cloud height, fractional coverage, and liquid water content, (c) surface temperature, and (d) total outgoing longwave radiation flux are described. Various meteorological results obtained from the application of the Nimbus-5 sounding data processing system during 1973 and 1974 are presented
Magnetic Field Control of the Quantum Chaotic Dynamics of Hydrogen Analogues in an Anisotropic Crystal Field
We report magnetic field control of the quantum chaotic dynamics of hydrogen
analogues in an anisotropic solid state environment. The chaoticity of the
system dynamics was quantified by means of energy level statistics. We analyzed
the magnetic field dependence of the statistical distribution of the impurity
energy levels and found a smooth transition between the Poisson limit and the
Wigner limit, i.e. transition between regular Poisson and fully chaotic Wigner
dynamics. Effect of the crystal field anisotropy on the quantum chaotic
dynamics, which manifests itself in characteristic transitions between
regularity and chaos for different field orientations, was demonstrated.Comment: 4 pages, 4 figure
Quantum quench dynamics of the Bose-Hubbard model at finite temperatures
We study quench dynamics of the Bose-Hubbard model by exact diagonalization.
Initially the system is at thermal equilibrium and of a finite temperature. The
system is then quenched by changing the on-site interaction strength
suddenly. Both the single-quench and double-quench scenarios are considered. In
the former case, the time-averaged density matrix and the real-time evolution
are investigated. It is found that though the system thermalizes only in a very
narrow range of the quenched value of , it does equilibrate or relax well in
a much larger range. Most importantly, it is proven that this is guaranteed for
some typical observables in the thermodynamic limit. In order to test whether
it is possible to distinguish the unitarily evolving density matrix from the
time-averaged (thus time-independent), fully decoherenced density matrix, a
second quench is considered. It turns out that the answer is affirmative or
negative according to the intermediate value of is zero or not.Comment: preprint, 20 pages, 7 figure
Modeling of a Cantilever-Based Near-Field Scanning Microwave Microscope
We present a detailed modeling and characterization of our scalable microwave
nanoprobe, which is a micro-fabricated cantilever-based scanning microwave
probe with separated excitation and sensing electrodes. Using finite-element
analysis, the tip-sample interaction is modeled as small impedance changes
between the tip electrode and the ground at our working frequencies near 1GHz.
The equivalent lumped elements of the cantilever can be determined by
transmission line simulation of the matching network, which routes the
cantilever signals to 50 Ohm feed lines. In the microwave electronics, the
background common-mode signal is cancelled before the amplifier stage so that
high sensitivity (below 1 atto-Farad capacitance changes) is obtained.
Experimental characterization of the microwave probes was performed on
ion-implanted Si wafers and patterned semiconductor samples. Pure electrical or
topographical signals can be realized using different reflection modes of the
probe.Comment: 7 figure
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