109 research outputs found
BigDataBench: a Big Data Benchmark Suite from Internet Services
As architecture, systems, and data management communities pay greater
attention to innovative big data systems and architectures, the pressure of
benchmarking and evaluating these systems rises. Considering the broad use of
big data systems, big data benchmarks must include diversity of data and
workloads. Most of the state-of-the-art big data benchmarking efforts target
evaluating specific types of applications or system software stacks, and hence
they are not qualified for serving the purposes mentioned above. This paper
presents our joint research efforts on this issue with several industrial
partners. Our big data benchmark suite BigDataBench not only covers broad
application scenarios, but also includes diverse and representative data sets.
BigDataBench is publicly available from http://prof.ict.ac.cn/BigDataBench .
Also, we comprehensively characterize 19 big data workloads included in
BigDataBench with varying data inputs. On a typical state-of-practice
processor, Intel Xeon E5645, we have the following observations: First, in
comparison with the traditional benchmarks: including PARSEC, HPCC, and
SPECCPU, big data applications have very low operation intensity; Second, the
volume of data input has non-negligible impact on micro-architecture
characteristics, which may impose challenges for simulation-based big data
architecture research; Last but not least, corroborating the observations in
CloudSuite and DCBench (which use smaller data inputs), we find that the
numbers of L1 instruction cache misses per 1000 instructions of the big data
applications are higher than in the traditional benchmarks; also, we find that
L3 caches are effective for the big data applications, corroborating the
observation in DCBench.Comment: 12 pages, 6 figures, The 20th IEEE International Symposium On High
Performance Computer Architecture (HPCA-2014), February 15-19, 2014, Orlando,
Florida, US
Metallic surface states in a correlated d-electron topological Kondo insulator candidate FeSb2
The resistance of a conventional insulator diverges as temperature approaches
zero. The peculiar low temperature resistivity saturation in the 4f Kondo
insulator (KI) SmB6 has spurred proposals of a correlation-driven topological
Kondo insulator (TKI) with exotic ground states. However, the scarcity of model
TKI material families leaves difficulties in disentangling key ingredients from
irrelevant details. Here we use angle-resolved photoemission spectroscopy
(ARPES) to study FeSb2, a correlated d-electron KI candidate that also exhibits
a low temperature resistivity saturation. On the (010) surface, we find a rich
assemblage of metallic states with two-dimensional dispersion. Measurements of
the bulk band structure reveal band renormalization, a large
temperature-dependent band shift, and flat spectral features along certain high
symmetry directions, providing spectroscopic evidence for strong correlations.
Our observations suggest that exotic insulating states resembling those in SmB6
and YbB12 may also exist in systems with d instead of f electrons
Visualizing Exotic Orbital Texture in the Single-Layer Mott Insulator 1T-TaSe2
Mott insulating behavior is induced by strong electron correlation and can
lead to exotic states of matter such as unconventional superconductivity and
quantum spin liquids. Recent advances in van der Waals material synthesis
enable the exploration of novel Mott systems in the two-dimensional limit. Here
we report characterization of the local electronic properties of single- and
few-layer 1T-TaSe2 via spatial- and momentum-resolved spectroscopy involving
scanning tunneling microscopy and angle-resolved photoemission. Our combined
experimental and theoretical study indicates that electron correlation induces
a robust Mott insulator state in single-layer 1T-TaSe2 that is accompanied by
novel orbital texture. Inclusion of interlayer coupling weakens the insulating
phase in 1T-TaSe2, as seen by strong reduction of its energy gap and quenching
of its correlation-driven orbital texture in bilayer and trilayer 1T-TaSe2. Our
results establish single-layer 1T-TaSe2 as a useful new platform for
investigating strong correlation physics in two dimensions
Low threading dislocation density and antiphase boundary free GaAs epitaxially grown on on-axis Si (001) substrates
The interactions between 1D defect threading dislocations and 2D defect antiphase boundaries and antiphase boundary annihilation in III–V materials on Si heteroepitaxy growth are revealed
Realization of Quantum Spin Hall State in Monolayer 1T'-WTe2
A quantum spin Hall (QSH) insulator is a novel two-dimensional quantum state
of matter that features quantized Hall conductance in the absence of magnetic
field, resulting from topologically protected dissipationless edge states that
bridge the energy gap opened by band inversion and strong spin-orbit coupling.
By investigating electronic structure of epitaxially grown monolayer 1T'-WTe2
using angle-resolved photoemission (ARPES) and first principle calculations, we
observe clear signatures of the topological band inversion and the band gap
opening, which are the hallmarks of a QSH state. Scanning tunneling microscopy
measurements further confirm the correct crystal structure and the existence of
a bulk band gap, and provide evidence for a modified electronic structure near
the edge that is consistent with the expectations for a QSH insulator. Our
results establish monolayer 1T'-WTe2 as a new class of QSH insulator with large
band gap in a robust two-dimensional materials family of transition metal
dichalcogenides (TMDCs).Comment: 19 pages, 4 figures; includes Supplemental Material (11 pages, 7
figures
Intersecting distributed networks support convergent linguistic functioning across different languages in bilinguals
How bilingual brains accomplish the processing of more than one language has been widely investigated by neuroimaging studies. The assimilation-accommodation hypothesis holds that both the same brain neural networks supporting the native language and additional new neural networks are utilized to implement second language processing. However, whether and how this hypothesis applies at the finer-grained levels of both brain anatomical organization and linguistic functions remains unknown. To address this issue, we scanned Chinese-English bilinguals during an implicit reading task involving Chinese words, English words and Chinese pinyin. We observed broad brain cortical regions wherein interdigitated distributed neural populations supported the same cognitive components of different languages. Although spatially separate, regions including the opercular and triangular parts of the inferior frontal gyrus, temporal pole, superior and middle temporal gyrus, precentral gyrus and supplementary motor areas were found to perform the same linguistic functions across languages, indicating regional-level functional assimilation supported by voxel-wise anatomical accommodation. Taken together, the findings not only verify the functional independence of neural representations of different languages, but show co-representation organization of both languages in most language regions, revealing linguistic-feature specific accommodation and assimilation between first and second languages
High energy Millihertz quasi-periodic oscillations in 1A 0535+262 with Insight-HXMT challenge current models
We studied the millihertz quasi-periodic oscillation (mHz QPO) in the 2020
outburst of the Be/X-ray binary 1A 0535+262 using Insight-HXMT data over a
broad energy band. The mHz QPO is detected in the 27-120 keV energy band. The
QPO centroid frequency is correlated with the source flux, and evolves in the
35-95 mHz range during the outburst. The QPO is most significant in the 50-65
keV band, with a significance of ~ 8 sigma, but is hardly detectable (<2 sigma)
in the lowest (1-27 keV) and highest (>120 keV) energy bands. Notably, the
detection of mHz QPO above 80 keV is the highest energy at which mHz QPOs have
been detected so far. The fractional rms of the mHz QPO first increases and
then decreases with energy, reaching the maximum amplitude at 50-65 keV. In
addition, at the peak of the outburst, the mHz QPO shows a double-peak
structure, with the difference between the two peaks being constant at ~0.02
Hz, twice the spin frequency of the neutron star in this system. We discuss
different scenarios explaining the generation of the mHz QPO, including the
beat frequency model, the Keplerian frequency model, the model of two jets in
opposite directions, and the precession of the neutron star, but find that none
of them can explain the origin of the QPO well. We conclude that the
variability of non-thermal radiation may account for the mHz QPO, but further
theoretical studies are needed to reveal the physical mechanism.Comment: 13 pages, 7 figures. Accepted for publication in MNRA
- …