Your search keyword '"Castander F.J."' showing total 50 results

1. CosmoHub: Interactive exploration and distribution of astronomical data on Hadoop

Author

Tallada, P., Carretero, J., Casals, J., Acosta-Silva, C., Serrano, S., Caubet, M., Castander, F.J., César, E., Crocce, M., Delfino, M., Eriksen, M., Fosalba, P., Gaztañaga, E., Merino, G., Neissner, C., and Tonello, N.

Published

2020

2. The PAU Survey: Operation and orchestration of multi-band survey data

Author

Tonello, N., Tallada, P., Serrano, S., Carretero, J., Eriksen, M., Folger, M., Neissner, C., Sevilla-Noarbe, I., Castander, F.J., Delfino, M., De Vicente, J., Fernandez, E., Garcia-Bellido, J., Gaztanaga, E., Padilla, C., Sanchez, E., and Tortorelli, L.

Published

2019

3. DES science portal: Computing photometric redshifts

Author

Gschwend, J., Rossel, A.C., Ogando, R.L.C., Neto, A.F., Maia, M.A.G., da Costa, L.N., Lima, M., Pellegrini, P., Campisano, R., Singulani, C., Adean, C., Benoist, C., Aguena, M., Carrasco Kind, M., Davis, T.M., de Vicente, J., Hartley, W.G., Hoyle, B., Palmese, A., Sadeh, I., Abbott, T.M.C., Abdalla, F.B., Allam, S., Annis, J., Asorey, J., Brooks, D., Calcino, J., Carollo, D., Castander, F.J., D’Andrea, C.B., Desai, S., Evrard, A.E., Fosalba, P., Frieman, J., García-Bellido, J., Glazebrook, K., Gerdes, D.W., Gruendl, R.A., Gutierrez, G., Hinton, S., Hollowood, D.L., Honscheid, K., Hoormann, J.K., James, D.J., Kuehn, K., Kuropatkin, N., Lahav, O., Lewis, G., Lidman, C., Lin, H., Macaulay, E., Marshall, J., Melchior, P., Miquel, R., Möller, A., Plazas, A.A., Sanchez, E., Santiago, B., Scarpine, V., Schindler, R.H., Sevilla-Noarbe, I., Smith, M., Sobreira, F., Sommer, N.E., Suchyta, E., Swanson, M.E.C., Tarle, G., Tucker, B.E., Tucker, D.L., Uddin, S., and Walker, A.R.

Published

2018

4. The PAU Survey and Euclid: Improving broadband photometric redshifts with multi-task learning.

Author

Cabayol, L., Eriksen, M., Carretero, J., Casas, R., Castander, F. J., Fernández, E., Garcia-Bellido, J., Gaztanaga, E., Hildebrandt, H., Hoekstra, H., Joachimi, B., Miquel, R., Padilla, C., Pocino, A., Sanchez, E., Serrano, S., Sevilla, I., Siudek, M., Tallada-Crespí, P., and Aghanim, N.

Subjects

EXPANDING universe, GALACTIC redshift, PHOTOMETRY, UNIVERSE, REDSHIFT, GALAXIES

Abstract

Current and future imaging surveys require photometric redshifts (photo-zs) to be estimated for millions of galaxies. Improving the photo-z quality is a major challenge but is needed to advance our understanding of cosmology. In this paper we explore how the synergies between narrow-band photometric data and large imaging surveys can be exploited to improve broadband photometric redshifts. We used a multi-task learning (MTL) network to improve broadband photo-z estimates by simultaneously predicting the broadband photo-z and the narrow-band photometry from the broadband photometry. The narrow-band photometry is only required in the training field, which also enables better photo-z predictions for the galaxies without narrow-band photometry in the wide field. This technique was tested with data from the Physics of the Accelerating Universe Survey (PAUS) in the COSMOS field. We find that the method predicts photo-zs that are 13% more precise down to magnitude iAB< 23; the outlier rate is also 40% lower when compared to the baseline network. Furthermore, MTL reduces the photo-z bias for high-redshift galaxies, improving the redshift distributions for tomographic bins with z > 1. Applying this technique to deeper samples is crucial for future surveys such as Euclid or LSST. For simulated data, training on a sample with iAB < 23, the method reduces the photo-z scatter by 16% for all galaxies with iAB < 25. We also studied the effects of extending the training sample with photometric galaxies using PAUS high-precision photo-zs, which reduces the photo-z scatter by 20% in the COSMOS field. [ABSTRACT FROM AUTHOR]

Published

2023

5. Exploring the selection of galaxy clusters and groups: an optical survey for X-ray dark clusters.

Author

Gilbank, David G., Bower, Richard G., Castander, F.J., and Ziegler, B.L.

Subjects

STAR clusters, GALAXIES, METAPHYSICAL cosmology, SUPERCLUSTERS, ASTROPHYSICS, ASTRONOMY

Abstract

Data from a new, wide-field, coincident optical and X-ray survey, the X-ray Dark Cluster Survey (XDCS), are presented. This survey comprises simultaneous and independent searches for clusters of galaxies in the optical and X-ray passbands. Optical cluster detection algorithms implemented on the data are detailed. Two distinct optically selected catalogues are constructed, one based on I-band overdensity, the other on overdensities of colour-selected galaxies. The superior accuracy of the colour-selection technique over that of the single-passband method is demonstrated, via internal consistency checks and comparison with external spectroscopic redshift information. This is compared with an X-ray-selected cluster catalogue. In terms of gross numbers, the survey yields 185 I-band-selected, 290 colour-selected and 15 X-ray-selected systems, residing in ∼11 deg2 of optical + X-ray imaging. The relationship between optical richness/luminosity and X-ray luminosity is examined, by measuring X-ray luminosities at the positions of our 290 colour-selected systems. Power-law correlations between the optical richness/luminosity and X-ray luminosity are fitted, both exhibiting approximately 0.2 dex of intrinsic scatter. Interesting outliers in these correlations are discussed in greater detail. Spectroscopic follow-up of a subsample of X-ray underluminous systems confirms their reality. [ABSTRACT FROM AUTHOR]

Published

2004

6. The Purport of Space Telescopes in Supernova Research.

Author

Vinkó, József, Szalai, Tamás, and Könyves-Tóth, Réka

Subjects

SPACE telescopes, COSMIC dust, STELLAR evolution, ASTROPHYSICS, SCIENTIFIC community

Abstract

The violent stellar explosions known as supernovae have received especially strong attention in both the research community and the general public recently. With the advent of space telescopes, the study of these extraordinary events has switched gears and it has become one of the leading fields in modern astrophysics. In this paper, we review some of the recent developments, focusing mainly on studies related to space-based observations. [ABSTRACT FROM AUTHOR]

Published

2023

7. The scientific performance of the microchannel X-ray telescope on board the SVOM mission.

Author

Götz, D., Boutelier, M., Burwitz, V., Chipaux, R., Cordier, B., Feldman, C., Ferrando, P., Fort, A., Gonzalez, F., Gros, A., Hussein, S., Le Duigou, J.-M., Meidinger, N., Mercier, K., Meuris, A., Pearson, J., Renault-Tinacci, N., Robinet, F., Schneider, B., and Willingale, R.

Subjects

X-ray telescopes, FOCAL length, ASTROPHYSICS, SPACE telescopes, OPTICS

Abstract

The Microchannel X-ray Telescope (MXT) will be the first focusing X-ray telescope based on a narrow field "Lobster-Eye" optical design to be flown on a satellite, namely the Sino-French mission SVOM. SVOM will be dedicated to the study of Gamma-Ray Bursts and more generally time-domain astrophysics. The MXT telescope is a compact (focal length ∼ 1.15 m) and light (< 42 kg) instrument, sensitive in the 0.2–10 keV energy range. It is composed of an optical system, based on micro-pore optics (MPOs) of 40 μ m pore size, coupled to a low-noise pnCDD X-ray detector. In this paper we describe the expected scientific performance of the MXT telescope, based on the End-to-End calibration campaign performed in fall 2021, before the integration of the SVOM payload on the satellite. [ABSTRACT FROM AUTHOR]

Published

2023

8. CATCH: chasing all transients constellation hunters space mission.

Author

Li, Panping, Yin, Qian-Qing, Li, Zhengwei, Tao, Lian, Wen, Xiangyang, Zhang, Shuang-Nan, Qi, Liqiang, Zhang, Juan, Zhao, Donghua, Li, Dalin, Yu, Xizheng, Bu, Qingcui, Chen, Wen, Chen, Yupeng, Huang, Yiming, Huang, Yue, Jin, Ge, Li, Gang, Liu, Hongbang, and Liu, Xiaojing

Subjects

MICROSPACECRAFT, INTELLIGENT control systems, FOCAL length, ARTIFICIAL satellites

Abstract

In time-domain astronomy, a substantial number of transients will be discovered by multi-wavelength and multi-messenger observatories, posing a great challenge for follow-up capabilities. We have thus proposed an intelligent X-ray constellation, the Chasing All Transients Constellation Hunters (CATCH) space mission. Consisting of 126 micro-satellites in three types, CATCH will have the capability to perform follow-up observations for a large number of different types of transients simultaneously. Each satellite in the constellation will carry lightweight X-ray optics and use a deployable mast to increase the focal length. The combination of different optics and detector systems enables different types of satellites to have multiform observation capabilities, including timing, spectroscopy, imaging, and polarization. Controlled by the intelligent system, different satellites can cooperate to perform uninterrupted monitoring, all-sky follow-up observations, and scanning observations with a flexible field of view (FOV) and multi-dimensional observations. Therefore, CATCH will be a powerful mission to study the dynamic universe. Here, we present the current design of the spacecraft, optics, detector system, constellation configuration and observing modes, as well as the development plan. [ABSTRACT FROM AUTHOR]

Published

2023

9. Quasar Identification Using Multivariate Probability Density Estimated from Nonparametric Conditional Probabilities.

Author

Farmer, Jenny, Allen, Eve, and Jacobs, Donald J.

Subjects

MAXIMUM entropy method, NONPARAMETRIC estimation, QUASARS, CONDITIONAL probability, ORDER statistics, PROBABILITY theory, DENSITY

Abstract

Nonparametric estimation for a probability density function that describes multivariate data has typically been addressed by kernel density estimation (KDE). A novel density estimator recently developed by Farmer and Jacobs offers an alternative high-throughput automated approach to univariate nonparametric density estimation based on maximum entropy and order statistics, improving accuracy over univariate KDE. This article presents an extension of the single variable case to multiple variables. The univariate estimator is used to recursively calculate a product array of one-dimensional conditional probabilities. In combination with interpolation methods, a complete joint probability density estimate is generated for multiple variables. Good accuracy and speed performance in synthetic data are demonstrated by a numerical study using known distributions over a range of sample sizes from 100 to 10 6 for two to six variables. Performance in terms of speed and accuracy is compared to KDE. The multivariate density estimate developed here tends to perform better as the number of samples and/or variables increases. As an example application, measurements are analyzed over five filters of photometric data from the Sloan Digital Sky Survey Data Release 17. The multivariate estimation is used to form the basis for a binary classifier that distinguishes quasars from galaxies and stars with up to 94% accuracy. [ABSTRACT FROM AUTHOR]

Published

2023

10. Observational constraints on Tsallis holographic dark energy with Ricci horizon cutoff.

Author

Feizi Mangoudehi, Zahra

Subjects

DARK energy, PHASE transitions, COSMOLOGICAL constant, EQUATIONS of state, ACCELERATION (Mechanics)

Abstract

In this research, we are interested in constraining the nonlinear interacting and noninteracting Tsallis holographic dark energy (THDE) with Ricci horizon cutoff by employing three observational datasets. To this aim, the THDE with Ricci horizon considering the noninteraction and nonlinear interaction terms will be fitted by the SNe Ia, SNe Ia+H(z), and SNe Ia+H(z)+GRB samples to investigate the Hubble (H (z) ), dark-energy equation of state ( ω D E ), effective equation of state ( ω e f f ), and deceleration (q ) parameters. Investigating the H (z) parameter illustrates that our models are in good consistency with respect to observations. Also, it can reveal the turning point for both noninteracting and nonlinear interacting THDE with Ricci cutoff in the late-time era. Next, the analysis of the ω D E for our models displays that the dark energy can experience the phantom state at the current time. However, this lies in the quintessence regime in the early era and approaches the cosmological constant in the late-time epoch. Similar results will be given for the ω e f f parameter with the difference that the ω e f f will experience the quintessence region at the current redshift. In addition to the mentioned parameters, the study of the q parameter indicates that the models satisfy an acceptable transition phase from the matter- to the dark energy-dominated era. After that, the classical stability ( v s 2 ) will be analyzed for our models. The v s 2 shows that the noninteracting and nonlinear interacting THDE with Ricci cutoff will be stable in the past era but unstable in the present and progressive epochs. Then, we will employ the J e r k (J ) and O M parameters to distinguish between our models and the Λ C D M model. Finally, we will calculate the age of the Universe for the THDE and nonlinear interacting THDE with Ricci as the IR cutoff. [ABSTRACT FROM AUTHOR]

Published

2022

11. The Diffraction-Limited Near-Infrared Spectropolarimeter (DL-NIRSP) of the Daniel K. Inouye Solar Telescope (DKIST).

Author

Jaeggli, Sarah A., Lin, Haosheng, Onaka, Peter, Yamada, Hubert, Anan, Tetsu, Bonnet, Morgan, Ching, Gregory, Huang, Xiao-Pei, Kramar, Maxim, McGregor, Helen, Nitta, Garry, Rae, Craig, Robertson, Louis, Schad, Thomas A., Toyama, Paul, Young, Jessica, Berst, Chris, Harrington, David M., Liang, Mary, and Puentes, Myles

Subjects

SOLAR telescopes, SCIENTIFIC apparatus & instruments, SPECTRAL lines, OPTICS, SPECTROGRAPHS, WAVELENGTHS

Abstract

The Diffraction-Limited Near-Infrared Spectropolarimeter (DL-NIRSP) is one of the first-light instruments for the National Science Foundation's Daniel K. Inouye Solar Telescope (DKIST). DL-NIRSP is an integral-field, dual-beam spectropolarimeter intended for studying magnetically sensitive spectral lines in the Sun's photosphere, chromosphere, and corona with high spectral resolution and polarimetric accuracy. Two novel fiber-optic integral-field units (IFUs), paired with selectable feed optics and a field-scanning mirror provide great flexibility in spatial sampling ( 0.03 ″ , 0.08 ″ , and 0.5 ″ ) and field coverage ( 2 ′ × 2 ′ ). The IFUs allow DL-NIRSP to record all the spectra from a 2D field of view simultaneously, enabling the instrument to study the evolution of highly dynamic events. The spectrograph is an all-reflecting, near-Littrow design, which achieves a resolving power of approximately 125,000. Multiple wavelengths can be observed simultaneously using three spectral arms: one for visible wavelengths (500 – 900 nm) and two for infrared wavelengths (900 – 1350 nm and 1350 – 1800 nm). Each supporting camera sub-system is capable of a 30-Hz frame rate, making it possible to track dynamic phenomena on the Sun. [ABSTRACT FROM AUTHOR]

Published

2022

12. The Role of Cross-Correlations in the Multi-Tracer Area.

Author

Blanchard, Alain

Subjects

NOISE, PHYSICAL cosmology

Abstract

Mapping the same volume of space with different tracers allows us to obtain information through estimated quantities exploiting the multi-tracer technique. Indeed, the cross-correlation of different probes provides information that cannot be otherwise obtained. In addition, some estimated quantities are not sensitive to the noise produced by the sampling variance but are only limited by the shot (or Poisson) noise, an attractive perspective. A simple example is the ratio between the (cross)-correlations, measuring the ratio of the bias parameters. Multi-tracer approaches can thereby provide additional information that cannot be extracted from independent volumes. [ABSTRACT FROM AUTHOR]

Published

2022

13. A Short Review on the Latest Neutrinos Mass and Number Constraints from Cosmological Observables.

Author

Sakr, Ziad

Subjects

HUBBLE constant, NUMBERS of species, NEUTRINO mass, SPECIES distribution, NEUTRINOS, PHYSICAL cosmology

Abstract

We review the neutrino science, focusing on its impact on cosmology along with the latest constraints on its mass and number of species. We also discuss its status as a possible solution to some of the recent cosmological tensions, such as the Hubble constant or the matter fluctuation parameter. We end by showing forecasts from next-generation planned or candidate surveys, highlighting their constraining power, alone or in combination, but also the limitations in determining neutrino mass distribution among its species. [ABSTRACT FROM AUTHOR]

Published

2022

14. How the Big Bang Ends Up Inside a Black Hole.

Author

Gaztanaga, Enrique

Subjects

BLACK holes, DARK matter, GRAVITATIONAL collapse, PHYSICAL cosmology, QUANTUM states, INFLATIONARY universe, DARK energy

Abstract

The standard model of cosmology assumes that our Universe began 14 Gyrs (billion years) ago from a singular Big Bang creation. This can explain a vast range of different astrophysical data from a handful of free cosmological parameters. However, we have no direct evidence or fundamental understanding of some key assumptions: Inflation, Dark Matter and Dark Energy. Here we review the idea that cosmic expansion originates instead from gravitational collapse and bounce. The collapse generates a Black Hole (BH) of mass M ≃ 5 × 10 22 M ⊙ that formed 25 Gyrs ago. As there is no pressure support, the cold collapse can continue inside in free fall until it reaches atomic nuclear saturation (GeV), when is halted by Quantum Mechanics, as two particles cannot occupy the same quantum state. The collapse then bounces like a core-collapse supernovae, producing the Big Bang expansion. Cosmic acceleration results from the BH event horizon. During collapse, perturbations exit the horizon to re-enter during expansion, giving rise to the observed universe without the need for Inflation or Dark Energy. Using Ockham's razor, this makes the BH Universe (BHU) model more compelling than the standard singular Big Bang creation. [ABSTRACT FROM AUTHOR]

Published

2022

15. Astronomical big data processing using machine learning: A comprehensive review.

Author

Sen, Snigdha, Agarwal, Sonali, Chakraborty, Pavan, and Singh, Krishna Pratap

Subjects

MACHINE learning, ELECTRONIC data processing, BIG data, ASTRONOMERS, ASTRONOMY

Abstract

Astronomy, being one of the oldest observational sciences, has collected a lot of data over the ages. In recent times, it is experiencing a huge data surge due to advancements in telescopic technologies with automated digital outputs. The main driver behind this article is to present various relevant Machine Learning (ML) algorithms and big data frameworks or tools being applied and can be employed in large astronomical data-set analysis to assist astronomers in solving multiple vital intriguing problems. Throughout this survey, we attempt to review, evaluate and summarize diverse astronomical data sources, gain knowledge of structure, the complexity of the data, and challenges in the data processing. Additionally, we discuss ample technologies being developed to handle and process this voluminous data. We also look at numerous activities being carried out all over the world enriching this domain. While going through existing literature, we perceived a limited number of comprehensive studies reported so far analyzing astronomy data-sets from the viewpoint of parallel processing and machine learning collectively. This motivated us to pursue this extensive literature review task by outlining up-to-date contributions and opportunities available in this area. Besides, this article also discusses briefly a cloud-based machine learning approach to estimate the extra-galactic object redshifts considering photometric data as input features. As the intersection of big data, machine learning and astronomy is a quite new paradigm, this article will create a strong awareness among interested young scientists for future research and provide an appropriate insight on how these algorithms and tools are becoming inevitable to the astronomy community day by day. [ABSTRACT FROM AUTHOR]

Published

2022

16. Confidence Limits of Evolutionary Synthesis Models.

Author

Cerviño, Miguel and Luridiana, Valentina

Abstract

The probabilistic nature of the IMF in stellar systems implies that clusters of the same mass and age do not present the same unique values of their observed parameters. Instead they follow a distribution. We address the study of such distributions in terms of their confidence limits that can be obtained by evolutionary synthesis models. These confidence limits can be understood as the inherent uncertainties of synthesis models. We will compare such confidence limits arising from the discreteness of the number of stars obtained with Monte Carlo simulations with the dispersion resulting from an analytical formalism. We give some examples of the effects on the kinetic energy, V–K, EW(Hβ) and multiwavelength continuum. [ABSTRACT FROM AUTHOR]

Published

2002

17. Gravitation and the Universe from large scale-structures: The GAUSS mission concept Mapping the cosmic web up to the reionization era.

Author

Blanchard, Alain, Aubourg, Éric, Brax, Philippe, Castander, Francisco J., Codis, Sandrine, Escoffier, Stéphanie, Dournac, Fabien, Ferté, Agnès, Finelli, Fabio, Fosalba, Pablo, Gangler, Emmanuel, Gontcho, Satya Gontcho A, Hawken, Adam, Ilić, Stéphane, Kneib, Jean-Paul, Kunz, Martin, Lavaux, Guilhem, Le Fèvre, Olivier, Lesgourgues, Julien, and Mellier, Yannick

Subjects

INFLATIONARY universe, CONCEPT mapping, DARK energy, PROPERTIES of matter, UNIVERSE, GRAVITATION

Abstract

Today, thanks in particular to the results of the ESA Planck mission, the concordance cosmological model appears to be the most robust to describe the evolution and content of the Universe from its early to late times. It summarizes the evolution of matter, made mainly of dark matter, from the primordial fluctuations generated by inflation around 10− 30 second after the Big Bang to galaxies and clusters of galaxies, 13.8 billion years later, and the evolution of the expansion of space, with a relative slowdown in the matter-dominated era and, since a few billion years, an acceleration powered by dark energy. But we are far from knowing the pillars of this model which are inflation, dark matter and dark energy. Comprehending these fundamental questions requires a detailed mapping of our observable Universe over the whole of cosmic time. The relic radiation provides the starting point and galaxies draw the cosmic web. JAXA's LiteBIRD mission will map the beginning of our Universe with a crucial test for inflation (its primordial gravity waves), and the ESA Euclid mission will map the most recent half part, crucial for dark energy. The mission concept GAUSS, described in this White Paper, aims at being a mission to fully map the cosmic web up to the reionization era, linking early and late evolution, to tackle and disentangle the crucial degeneracies persisting after the Euclid era between dark matter and inflation properties, dark energy, structure growth and gravitation at large scale. [ABSTRACT FROM AUTHOR]

Published

2021

18. Optical-Ultraviolet Tidal Disruption Events.

Author

van Velzen, Sjoert, Holoien, Thomas W.-S., Onori, Francesca, Hung, Tiara, and Arcavi, Iair

Abstract

The existence of optical-ultraviolet Tidal Disruption Events (TDEs) could be considered surprising because their electromagnetic output was originally predicted to be dominated by X-ray emission from an accretion disk. Yet over the last decade, the growth of optical transient surveys has led to the identification of a new class of optical transients occurring exclusively in galaxy centers, many of which are considered to be TDEs. Here we review the observed properties of these events, identified based on a shared set of both photometric and spectroscopic properties. We present a homogeneous analysis of 33 sources that we classify as robust TDEs, and which we divide into classes. The criteria used here to classify TDEs will possibly get updated as new samples are collected and potential additional diversity of TDEs is revealed. We also summarize current measurements of the optical-ultraviolet TDE rate, as well as the mass function and luminosity function. Many open questions exist regarding the current sample of events. We anticipate that the search for answers will unlock new insights in a variety of fields, from accretion physics to galaxy evolution. [ABSTRACT FROM AUTHOR]

Published

2020

19. Detection of short high-energy transients in the local universe with SVOM/ECLAIRs.

Author

Arcier, B., Atteia, J. L., Godet, O., Mate, S., Guillot, S., Dagoneau, N., Rodriguez, J., Gotz, D., Schanne, S., and Bernardini, M. G.

Abstract

The coincidental detection of the gravitational wave event GW 170817 and the gamma-ray burst GRB 170817A marked the advent of multi-messenger astronomy and represented a milestone in the study of GRBs. Significant progress in this field is expected in the coming years with the increased sensitivity of gravitational waves detectors and the launch of new facilities for the high-energy survey of the sky. In this context, the launch of SVOM in mid-2022, with its two wide-field high-energy instruments ECLAIRs and GRM, will foster the possibilities of coincidental transient detection with gravitational waves and gamma-rays events. The purpose of this paper is to assess the ability of SVOM/ECLAIRs to detect and quickly characterize high-energy transients in the local Universe (z ≤ 0.3), and to discuss the contribution of this instrument to multi-messenger astronomy and to gamma-ray burst (GRB) astrophysics in the 2020’s. A list of local HE transients, along with their main characteristics, is constructed through an extensive literature survey. This list includes 41 transients: 24 long GRBs, 10 short GRBs and 7 SGR Giant Flares. The detectability of these transients with ECLAIRs is assessed with detailed simulations using tools developed for the SVOM mission, including a GEANT4 simulation of the energy response and a simulated trigger algorithm representative of the onboard trigger algorithm. SVOM/ECLAIRs would have been able to detect 88% of the short high-energy transients in our list: 22 out of 24 long GRBs, 8 out of 10 short GRBs and 6 out of 7 SGR Giant Flares. The SNR for almost all detections will be sufficiently high to allow the on-board ECLAIRs trigger algorithm to derive the localisation of the transient, transmitting it to the SVOM satellite and ground-based instruments. Coupled with the anti-solar pointing strategy of SVOM, this will enable an optimal follow-up of the events, allowing the observation of their afterglows, supernovae/kilonovae counterparts, and host galaxies. We conclude the paper with a discussion of the unique contribution expected from SVOM and of the possibility of simultaneous GW detection for each type of transient in our sample. [ABSTRACT FROM AUTHOR]

Published

2020

20. Characterizing some Gaia Alerts with LAMOST and SDSS.

Author

Huo, Z., Dennefeld, M., Liu, X., Pursimo, T., and Zhang, T.

Subjects

EMISSION-line galaxies, SUPERNOVAE, GALAXY spectra, QUASARS, GALAXIES

Abstract

The ESA-Gaia satellite is regularly producing Alerts on objects where photometric variability has been detected after several passages over the same region of the sky. The physical nature of these objects has often to be determined with the help of complementary observations from ground-based facilities. We have compared the list of Gaia Alerts (from the beginning in 2014 to Nov. 1st, 2018) with archival LAMOST and SDSS spectroscopic data. A search radius of 3″ has been adopted. In using survey data, the date of the ground-based observation rarely corresponds to the date of the Alert, but this allows at least the identification of the source if it is persistent, or the host galaxy if the object was only transient like a supernova (SN). Some of the objects have several LAMOST observations, and we complemented this search by adding also SDSS DR15 data in order to look for long-term variability. A list of Gaia Nuclear Transients (GNT) from Kostrzewa-Rutkowska et al. (Mon. Not. R. Astron. Soc. 481(1):307, 2018) has been included in this search also. We found 26 Gaia Alerts with spectra in LAMOST+SDSS labelled as stars, among which 12 have multi-epoch spectra. A majority of them are Cataclysmic Variables (CVs). Similarly, 206 Gaia Alerts have associated spectra labelled as galaxies, among which 49 have multi-epoch spectra. Those spectra were generally obtained on a date widely different from the Alert date, and are mostly emission-line galaxies with no particularity (except a few Seyferts), leading to the suspicion that most of the Alerts were due to a SN. As for the GNT list, we found 55 associated spectra labelled as galaxies, among them 13 with multi-epoch spectra. In these two galaxy samples, in only two cases, Gaia17aal and GNTJ170213+2543, was the date of the spectroscopic observation close enough to the Alert date: we find a trace of the SN itself in their LAMOST spectrum, both being now classified here as a type Ia SN. Compared to the galaxy sample from the Gaia alerts, the GNT sample has a higher proportion of AGNs, suggesting that some of the detected variations are also due to the AGN itself. Similarly for Quasars, we found only 30 Gaia Alerts but 68 GNT cases associated with single epoch quasar spectra in the databases. In addition to those, 12 plus 23 are quasars where multi-epoch spectra are available. For ten out of these 35, their multi-epoch spectra show appearance or disappearance of the broad Balmer lines and also variations in the continuum, qualifying them as "Changing Look Quasars" and therefore significantly increasing the available sample of such objects. [ABSTRACT FROM AUTHOR]

Published

2020

21. The Host Galaxies of Tidal Disruption Events.

Author

French, K. Decker, Wevers, Thomas, Law-Smith, Jamie, Graur, Or, and Zabludoff, Ann I.

Subjects

STELLAR black holes, GALAXIES, STAR formation, STELLAR populations, BLACK holes

Abstract

Recent studies of Tidal Disruption Events (TDEs) have revealed unexpected correlations between the TDE rate and the large-scale properties of the host galaxies. In this review, we present the host galaxy properties of all TDE candidates known to date and quantify their distributions. We consider throughout the differences between observationally-identified types of TDEs and differences from spectroscopic control samples of galaxies. We focus here on the black hole and stellar masses of TDE host galaxies, their star formation histories and stellar populations, the concentration and morphology of the optical light, the presence of AGN activity, and the extra-galactic environment of the TDE hosts. We summarize the state of several possible explanations for the links between the TDE rate and host galaxy type. We present estimates of the TDE rate for different host galaxy types and quantify the degree to which rate enhancement in some types results in rate suppression in others. We discuss the possibilities for using TDE host galaxies to assist in identifying TDEs in upcoming large transient surveys and possibilities for TDE observations to be used to study their host galaxies. [ABSTRACT FROM AUTHOR]

Published

2020

22. Cosmological N-body simulations: a challenge for scalable generative models.

Author

Perraudin, Nathanaël, Srivastava, Ankit, Lucchi, Aurelien, Kacprzak, Tomasz, Hofmann, Thomas, and Réfrégier, Alexandre

Subjects

MACHINE learning, GENERATIVE adversarial networks, PHYSICAL cosmology

Abstract

Deep generative models, such as Generative Adversarial Networks (GANs) or Variational Autoencoders (VAs) have been demonstrated to produce images of high visual quality. However, the existing hardware on which these models are trained severely limits the size of the images that can be generated. The rapid growth of high dimensional data in many fields of science therefore poses a significant challenge for generative models. In cosmology, the large-scale, three-dimensional matter distribution, modeled with N-body simulations, plays a crucial role in understanding the evolution of structures in the universe. As these simulations are computationally very expensive, GANs have recently generated interest as a possible method to emulate these datasets, but they have been, so far, mostly limited to two dimensional data. In this work, we introduce a new benchmark for the generation of three dimensional N-body simulations, in order to stimulate new ideas in the machine learning community and move closer to the practical use of generative models in cosmology. As a first benchmark result, we propose a scalable GAN approach for training a generator of N-body three-dimensional cubes. Our technique relies on two key building blocks, (i) splitting the generation of the high-dimensional data into smaller parts, and (ii) using a multi-scale approach that efficiently captures global image features that might otherwise be lost in the splitting process. We evaluate the performance of our model for the generation of N-body samples using various statistical measures commonly used in cosmology. Our results show that the proposed model produces samples of high visual quality, although the statistical analysis reveals that capturing rare features in the data poses significant problems for the generative models. We make the data, quality evaluation routines, and the proposed GAN architecture publicly available at https://github.com/nperraud/3DcosmoGAN. [ABSTRACT FROM AUTHOR]

Published

2019

23. Superluminous Supernovae.

Author

Moriya, Takashi J., Sorokina, Elena I., and Chevalier, Roger A.

Abstract

Superluminous supernovae are a new class of supernovae that were recognized about a decade ago. Both observational and theoretical progress has been significant in the last decade. In this review, we first briefly summarize the observational properties of superluminous supernovae. We then introduce the three major suggested luminosity sources to explain the huge luminosities of superluminous supernovae, i.e., the nuclear decay of 56Ni, the interaction between supernova ejecta and dense circumstellar media, and the spin down of magnetars. We compare these models and discuss their strengths and weaknesses. [ABSTRACT FROM AUTHOR]

Published

2018

24. Astronomical Distance Determination in the Space Age.

Author

Czerny, Bożena, Beaton, Rachael, Bejger, Michał, Cackett, Edward, Dall'Ora, Massimo, Holanda, R. F. L., Jensen, Joseph B., Jha, Saurabh W., Lusso, Elisabeta, Minezaki, Takeo, Risaliti, Guido, Salaris, Maurizio, Toonen, Silvia, and Yoshii, Yuzuru

Abstract

The formal division of the distance indicators into primary and secondary leads to difficulties in description of methods which can actually be used in two ways: with, and without the support of the other methods for scaling. Thus instead of concentrating on the scaling requirement we concentrate on all methods of distance determination to extragalactic sources which are designated, at least formally, to use for individual sources. Among those, the Supernovae Ia is clearly the leader due to its enormous success in determination of the expansion rate of the Universe. However, new methods are rapidly developing, and there is also a progress in more traditional methods. We give a general overview of the methods but we mostly concentrate on the most recent developments in each field, and future expectations. [ABSTRACT FROM AUTHOR]

Published

2018

25. A Preliminary Investigation of CSPN in the HASH Database.

Author

Parker, Quentin A., Xiang, Zou, and Ritter, Andreas

Subjects

PLANETARY nebulae, DATABASES, STELLAR evolution, CATALOGS

Abstract

We present some preliminary findings on the population of planetary nebula where central stars (CSPN) have been independently identified in the HASH catalogue. Many new discoveries and candidates have been found (416 at the time of this writing), adding significantly to the previously known sample of about 600. We also present results from a comparison between our own HASH measurements of CSPN and those provided in existing CSPN catalogues and those from Gaia. We show the value of a federated, multi-wavelength database of Galactic PNe like HASH in terms of not only uncovering faint, new CSPN but of assisting in correct identifications, removing PN mimics with apparent CSPN, correcting incorrect assignments and providing improved positions. HASH provides the community with a comprehensive and reliable resource for any study of the CSPN population of Galactic PNe. [ABSTRACT FROM AUTHOR]

Published

2022

26. Cosmological dynamics of a bulk scalar field in the DGP setup.

Author

Nozari, Kourosh and Rashidi, Narges

Subjects

PHYSICAL cosmology, BRANES, GRAVITY, SCALAR field theory, IMAGING phantoms, SELF-consistent field theory

Abstract

We reconsider the issue of cosmological dynamics in a DGP setup with a bulk scalar field. The ghost-free, normal branch of this DGP-inspired braneworld scenario has the potential to realize a self-consistent phantom-like behavior. The roles played by the bulk canonical scalar field on this phantom-like dynamics are explored. Within a dynamical system approach, the effective phantom nature of the scenario is investigated with details. This analysis shows that there is a stable, late-time de Sitter phase. [ABSTRACT FROM AUTHOR]

Published

2012

27. On the initial cluster mass distribution inferred from synthesis models.

Author

Cerviño, Miguel and Valls-Gabaud, David

Subjects

STAR clusters, GAUSSIAN distribution, STELLAR mass, STELLAR initial mass function, STELLAR luminosity function

Abstract

In this contribution we examine the problem of inferring ages and initial cluster masses from synthesis models at the limit of low-mass clusters ( M≤ a few ×104 M⊙). We show that it is not possible to apply directly synthesis models using standard methods to such clusters, since the basic hypothesis implicit in the models (a fixed proportionality between the number of stars in different evolutionary phases) is not fulfilled due to an insufficient number of stars for a reliable sampling of the stellar initial mass function. The consequence of this incomplete sampling is a non-Gaussian distribution of the mass–luminosity relation for clusters that share the same evolutionary conditions (age, metallicity and stellar initial mass distribution function). We review some tests, that can be performed before the start of the analysis, to estimate if the observed cluster can be analyzed with synthesis models following traditional procedures (like χ2 minimization) or if it is necessary make use of synthesis models in a probabilistic framework. Finally, we show the implications of these results for estimating the low-mass tail in the initial cluster mass distribution function. [ABSTRACT FROM AUTHOR]

Published

2009

28. The Flux Ratio of the [OIII] λλ 5007,4959 Doublet with Redshift.

Author

Laker, Mayalen A., Camacho, Conner D., Jones, Daniel, and Moody, Joseph

Subjects

FINE-structure constant, ASTRONOMICAL surveys, EMISSION-line galaxies, ATOMIC physics, GALAXIES

Abstract

As a test of the time symmetry of forbidden-line emission processes, we measured the [OIII] λ λ 4959 and 5007 emission lines of more than 12,000 galaxies from the Sloan Digital Sky Survey DR8 to examine the [OIII] λ λ 4959,5007 flux ratio as a function of redshift z. Using two different approaches, we fitted each line with a Gaussian curve and rejected any spectrum not conforming to requirements of line symmetry, S/N levels, and continuum fit. We found the variance in the ratio of flux to be between 4.7 and −3.3% for 0 < z < 0.433 which is consistent with no change. After correcting for systematic effects of noise, we found the mean value of the [OIII] λ λ 4959,5007 flux ratio to be 2.98 ± 0.01 which is consistent with theory and previous studies using AGN spectra. We also used these data to estimate an upper limit on the time dependence of the fine structure constant α of Δ α / α (0) < 1.4 × 10 − 5 for galaxies within the same redshift range. This corresponds to | α − 1 d α / d t | < 2 × 10 − 15 yr − 1 , which is also in line with previous estimates from SDSS QSO data. [ABSTRACT FROM AUTHOR]

Published

2022

29. Evolutionary Synthesis Models: Gamma-ray Emission.

Author

Cerviño, M., Knödlseder, J., Schaerer, D., and von Ballmoos, P.

Published

2001

30. The Interplay of Cluster and Galaxy Evolution.

Author

Nichol, Robert C., Miller, Christopher J., and Goto, Tomotsugu

Subjects

GALAXY clusters, GALACTIC evolution, GALAXY formation, METAPHYSICAL cosmology, ASTROPHYSICS, SPACE sciences

Abstract

We review here the interplay of cluster and galaxy evolution. As a case study, we consider the Butcher-Oemler effect and propose that it is the result of the changing rate of cluster merger events in a hierarchical universe. This case study highlights the need for new catalogs of clusters and groups that possess quantified morphologies. We present such a sample here, namely the Sloan Digital Sky Survey (SDSS) C4 Catalog, which has been objectively-selected from the SDSS spectroscopic galaxy sample. We outline here the C4 algorithm and present first results based on the SDSS Early Data Release, including an X-ray luminosity-velocity dispersion (Lx-σv) scaling relationship (as a function of cluster morphology) and the density-SFR relation of galaxies within C4 clusters (Gomez et al., 2003). We also discuss the merger of Coma and the NGC4839 group and its effect on the galaxy populations in these systems. We finish with a brief discussion of a new sample of HΔ-selected galaxies (i.e., k+a, post-starburst galaxies) obtained from the SDSS spectroscopic survey. [ABSTRACT FROM AUTHOR]

Published

2003

31. THE X-RAY BACKGROUND.

Author

HASINGER, GÜNTHER

Published

1995

32. A Serendipitous Deep Cluster Survey from ROSAT-PSPC pointed observations.

Author

Rosati, P.

Subjects

GALAXY clusters, ASTROPHYSICS

Abstract

Presents a deep X-ray selected sample of galaxy clusters which has been created from a serendipitous search in ROSAT-PSPC deep pointed observations at high galactic latitude. Overview of the ROSAT deep cluster survey; Results from the optical follow-up program.

Published

1998

33. Image Simulations for Strong and Weak Gravitational Lensing.

Author

A. Plazas, Andrés

Subjects

GRAVITATIONAL lenses, GRAVITATIONAL potential, DARK matter, ASTROPHYSICS, IMAGE, DARK energy

Abstract

Gravitational lensing has been identified as a powerful tool to address fundamental problems in astrophysics at different scales, ranging from exoplanet identification to dark energy and dark matter characterization in cosmology. Image simulations have played a fundamental role in the realization of the full potential of gravitational lensing by providing a means to address needs such as systematic error characterization, pipeline testing, calibration analyses, code validation, and model development. We present a general overview of the generation and applications of image simulations in strong and weak gravitational lensing. [ABSTRACT FROM AUTHOR]

Published

2020

34. Long-Term Optical Monitoring of Blazars.

Author

Gazeas, Kosmas

Subjects

RADIO telescopes, ASTRONOMICAL surveys, VARIABLE stars, ACTIVE galactic nuclei

Abstract

Systematic monitoring of specific targets in the optical regime was historically applied on a very narrow sample of known variable stars. The discovery of blazars in the 20th century brought to the foreground the need for new global sky surveys, covering the entire sky and fainter sources. Full-sky surveys are conducted more easily from space observatories, while radio telescopes perform follow up observations from the ground. Blazars are detected in a wide range of energies, while they exhibit strong variability in various wavelengths from γ-rays and X-rays to the optical and radio domain. This results in a detailed classification, according to their emission properties in each region. The rapid variability in optical domain makes blazars interesting targets for optical sky surveys, offering a new opportunity to study their variability in the time domain. Digital sky surveys in optical and near-IR found a fertile ground with the aid of sensitive sensors. Only a few dedicated programs are focusing on blazar variability, a trend which evolved rapidly in the last decade. Modern techniques, in combination with dedicated sky survey programs lead towards a new era of long-term monitoring of blazars, aiming towards the search or variability on various time scales. In this work, an overview of blazar optical surveys and monitoring projects is given, addressing the major points of each one, and highlighting the constraints that the long-term study of blazars will bring through future international campaigns. [ABSTRACT FROM AUTHOR]

Published

2019

35. The IllustrisTNG simulations: public data release.

Author

Nelson, Dylan, Springel, Volker, Pillepich, Annalisa, Rodriguez-Gomez, Vicente, Torrey, Paul, Genel, Shy, Vogelsberger, Mark, Pakmor, Ruediger, Marinacci, Federico, Weinberger, Rainer, Kelley, Luke, Lovell, Mark, Diemer, Benedikt, and Hernquist, Lars

Subjects

GALAXY formation, SUPERMASSIVE black holes, GALACTIC halos, DARK matter, DATA analysis

Abstract

We present the full public release of all data from the TNG100 and TNG300 simulations of the IllustrisTNG project. IllustrisTNG is a suite of large volume, cosmological, gravo-magnetohydrodynamical simulations run with the moving-mesh code Arepo. TNG includes a comprehensive model for galaxy formation physics, and each TNG simulation self-consistently solves for the coupled evolution of dark matter, cosmic gas, luminous stars, and supermassive black holes from early time to the present day, z = 0 . Each of the flagship runs—TNG50, TNG100, and TNG300—are accompanied by halo/subhalo catalogs, merger trees, lower-resolution and dark-matter only counterparts, all available with 100 snapshots. We discuss scientific and numerical cautions and caveats relevant when using TNG. The data volume now directly accessible online is ∼750 TB, including 1200 full volume snapshots and ∼80,000 high time-resolution subbox snapshots. This will increase to ∼1.1 PB with the future release of TNG50. Data access and analysis examples are available in IDL, Python, and Matlab. We describe improvements and new functionality in the web-based API, including on-demand visualization and analysis of galaxies and halos, exploratory plotting of scaling relations and other relationships between galactic and halo properties, and a new JupyterLab interface. This provides an online, browser-based, near-native data analysis platform enabling user computation with local access to TNG data, alleviating the need to download large datasets. [ABSTRACT FROM AUTHOR]

Published

2019

36. CosmoGAN: creating high-fidelity weak lensing convergence maps using Generative Adversarial Networks.

Author

Mustafa, Mustafa, Bard, Deborah, Bhimji, Wahid, Lukić, Zarija, Al-Rfou, Rami, and Kratochvil, Jan M.

Subjects

DEEP learning, COMPUTER simulation, PERFORMANCE theory

Abstract

Inferring model parameters from experimental data is a grand challenge in many sciences, including cosmology. This often relies critically on high fidelity numerical simulations, which are prohibitively computationally expensive. The application of deep learning techniques to generative modeling is renewing interest in using high dimensional density estimators as computationally inexpensive emulators of fully-fledged simulations. These generative models have the potential to make a dramatic shift in the field of scientific simulations, but for that shift to happen we need to study the performance of such generators in the precision regime needed for science applications. To this end, in this work we apply Generative Adversarial Networks to the problem of generating weak lensing convergence maps. We show that our generator network produces maps that are described by, with high statistical confidence, the same summary statistics as the fully simulated maps. [ABSTRACT FROM AUTHOR]

Published

2019

37. The Galaxy Cluster Mass Scale and Its Impact on Cosmological Constraints from the Cluster Population.

Author

Pratt, G. W., Arnaud, M., Biviano, A., Eckert, D., Ettori, S., Nagai, D., Okabe, N., and Reiprich, T. H.

Subjects

GALAXY clusters, POPULATION, MASS measurement, COMPUTER simulation, REDSHIFT, SCALING (Social sciences)

Abstract

The total mass of a galaxy cluster is one of its most fundamental properties. Together with the redshift, the mass links observation and theory, allowing us to use the cluster population to test models of structure formation and to constrain cosmological parameters. Building on the rich heritage from X-ray surveys, new results from Sunyaev-Zeldovich and optical surveys have stimulated a resurgence of interest in cluster cosmology. These studies have generally found fewer clusters than predicted by the baseline Planck Λ CDM model, prompting a renewed effort on the part of the community to obtain a definitive measure of the true cluster mass scale. Here we review recent progress on this front. Our theoretical understanding continues to advance, with numerical simulations being the cornerstone of this effort. On the observational side, new, sophisticated techniques are being deployed in individual mass measurements and to account for selection biases in cluster surveys. We summarise the state of the art in cluster mass estimation methods and the systematic uncertainties and biases inherent in each approach, which are now well identified and understood, and explore how current uncertainties propagate into the cosmological parameter analysis. We discuss the prospects for improvements to the measurement of the mass scale using upcoming multi-wavelength data, and the future use of the cluster population as a cosmological probe. [ABSTRACT FROM AUTHOR]

Published

2019

38. The Physics of Galaxy Cluster Outskirts.

Author

Walker, Stephen, Simionescu, Aurora, Nagai, Daisuke, Okabe, Nobuhiro, Eckert, Dominique, Mroczkowski, Tony, Akamatsu, Hiroki, Ettori, Stefano, and Ghirardini, Vittorio

Subjects

GALAXY clusters, GALAXIES, TELESCOPES, ELECTROMAGNETIC spectrum, ASTROPHYSICS, SPACE exploration

Abstract

As the largest virialized structures in the universe, galaxy clusters continue to grow and accrete matter from the cosmic web. Due to the low gas density in the outskirts of clusters, measurements are very challenging, requiring extremely sensitive telescopes across the entire electromagnetic spectrum. Observations using X-rays, the Sunyaev-Zeldovich effect, and weak lensing and galaxy distributions from the optical band, have over the last decade helped to unravel this exciting new frontier of cluster astrophysics, where the infall and virialization of matter takes place. Here, we review the current state of the art in our observational and theoretical understanding of cluster outskirts, and discuss future prospects for exploration using newly planned and proposed observatories. [ABSTRACT FROM AUTHOR]

Published

2019

39. Hot Atmospheres, Cold Gas, AGN Feedback and the Evolution of Early Type Galaxies: A Topical Perspective.

Author

Werner, N., McNamara, B. R., Churazov, E., and Scannapieco, E.

Subjects

ATMOSPHERE, COLD gases, MILKY Way, X-ray spectra, ACTIVE galactic nuclei

Abstract

Most galaxies comparable to or larger than the mass of the Milky Way host hot, X-ray emitting atmospheres, and many such galaxies are radio sources. Hot atmospheres and radio jets and lobes are the ingredients of radio-mechanical active galactic nucleus (AGN) feedback. While a consensus has emerged that such feedback suppresses cooling of hot cluster atmospheres, less attention has been paid to massive galaxies where similar mechanisms are at play. Observation indicates that the atmospheres of elliptical and S0 galaxies were accreted externally during the process of galaxy assembly and augmented significantly by stellar mass loss. Their atmospheres have entropy and cooling time profiles that are remarkably similar to those of central cluster galaxies. About half display filamentary or disky nebulae of cool and cold gas, much of which has likely cooled from the hot atmospheres. We review the observational and theoretical perspectives on thermal instabilities in galactic atmospheres and the evidence that AGN heating is able to roughly balance the atmospheric cooling. Such heating and cooling may be regulating star formation in all massive spheroids at late times. [ABSTRACT FROM AUTHOR]

Published

2019

40. Fast cosmic web simulations with generative adversarial networks.

Author

Rodríguez, Andres C., Kacprzak, Tomasz, Lucchi, Aurelien, Amara, Adam, Sgier, Raphaël, Fluri, Janis, Hofmann, Thomas, and Réfrégier, Alexandre

Subjects

COSMIC rays, N-body simulations (Astronomy), LARGE Synoptic Survey Telescope, COMPUTATIONAL physics, MACHINE learning

Abstract

Dark matter in the universe evolves through gravity to form a complex network of halos, filaments, sheets and voids, that is known as the cosmic web. Computational models of the underlying physical processes, such as classical N-body simulations, are extremely resource intensive, as they track the action of gravity in an expanding universe using billions of particles as tracers of the cosmic matter distribution. Therefore, upcoming cosmology experiments will face a computational bottleneck that may limit the exploitation of their full scientific potential. To address this challenge, we demonstrate the application of a machine learning technique called Generative Adversarial Networks (GAN) to learn models that can efficiently generate new, physically realistic realizations of the cosmic web. Our training set is a small, representative sample of 2D image snapshots from N-body simulations of size 500 and 100 Mpc. We show that the GAN-generated samples are qualitatively and quantitatively very similar to the originals. For the larger boxes of size 500 Mpc, it is very difficult to distinguish them visually. The agreement of the power spectrum Pk is 1-2% for most of the range, between k=0.06 and k=0.4. For the remaining values of k, the agreement is within 15%, with the error rate increasing for k>0.8. For smaller boxes of size 100 Mpc, we find that the visual agreement to be good, but some differences are noticable. The error on the power spectrum is of the order of 20%. We attribute this loss of performance to the fact that the matter distribution in 100 Mpc cutouts was very inhomogeneous between images, a situation in which the performance of GANs is known to deteriorate. We find a good match for the correlation matrix of full Pk range for 100 Mpc data and of small scales for 500 Mpc, with ∼20% disagreement for large scales. An important advantage of generating cosmic web realizations with a GAN is the considerable gains in terms of computation time. Each new sample generated by a GAN takes a fraction of a second, compared to the many hours needed by traditional N-body techniques. We anticipate that the use of generative models such as GANs will therefore play an important role in providing extremely fast and precise simulations of cosmic web in the era of large cosmological surveys, such as Euclid and Large Synoptic Survey Telescope (LSST). [ABSTRACT FROM AUTHOR]

Published

2018

41. Cosmological Distance Indicators.

Author

Suyu, Sherry H., Chang, Tzu-Ching, Courbin, Frédéric, and Okumura, Teppei

Subjects

GRAVITATIONAL effects, GRAVITATIONAL fields, ASTRONOMICAL observations, TIME delay systems, ASTROPHYSICS, MAGNETIC fields

Abstract

We review three distance measurement techniques beyond the local universe: (1) gravitational lens time delays, (2) baryon acoustic oscillation (BAO), and (3) HI intensity mapping. We describe the principles and theory behind each method, the ingredients needed for measuring such distances, the current observational results, and future prospects. Time-delays from strongly lensed quasars currently provide constraints on H0 with <4% uncertainty, and with 1% within reach from ongoing surveys and efforts. Recent exciting discoveries of strongly lensed supernovae hold great promise for time-delay cosmography. BAO features have been detected in redshift surveys up to z≲0.8 with galaxies and z∼2 with Ly-α forest, providing precise distance measurements and H0 with <2% uncertainty in flat ΛCDM. Future BAO surveys will probe the distance scale with percent-level precision. HI intensity mapping has great potential to map BAO distances at z∼0.8 and beyond with precisions of a few percent. The next years ahead will be exciting as various cosmological probes reach 1% uncertainty in determining H0, to assess the current tension in H0 measurements that could indicate new physics. [ABSTRACT FROM AUTHOR]

Published

2018

42. Can stellar winds account for temperature fluctuations?

Author

Luridiana, Valentina, Cerviño, Miguel, and Binette, Luc

Published

2002

43. Fitting the integrated spectral energy distributions of galaxies.

Subjects

SPECTRAL energy distribution, GALAXIES, PREDICTION theory, MATHEMATICAL models, UNCERTAINTY (Information theory), REDSHIFT, STELLAR mass, STAR formation, DATA analysis, RADIATION

Published

2011

44. DSRL: A low-resolution stellar spectral of LAMOST automatic classification method based on discrete wavelet transform and deep learning methods

Author

Li, Hao, Zhao, Qing, Zhang, Chengkui, Cui, Chenzhou, Fan, Dongwei, Wang, Yuan, and Chen, Yarui

Published

2024

45. Molecular hydrogen in absorption at high redshifts: Science cases for CUBES

Author

Balashev, S. A. and Noterdaeme, P.

Published

2023

46. Clustering-based data placement in cloud computing: a predictive approach

Author

Sellami, Mokhtar, Mezni, Haithem, Hacid, Mohand Said, and Gammoudi, Mohamed Moshen

Published

2021

47. A deep study of the high–energy transient sky

Author

Guidorzi, C., Frontera, F., Ghirlanda, G., Stratta, G., Mundell, C. G., Virgilli, E., Rosati, P., Caroli, E., Amati, L., Pian, E., Kobayashi, S., Ghisellini, G., Fryer, C., Valle, M. Della, Margutti, R., Marongiu, M., Martone, R., Campana, R., Fuschino, F., Labanti, C., Orlandini, M., Stephen, J. B., Brandt, S., Silva, R. Curado da, Laurent, P., Mochkovitch, R., Bozzo, E., Ciolfi, R., Burderi, L., and Di Salvo, T.

Published

2021

48. The local dark sector: Probing gravitation’s low-acceleration frontier and dark matter in the Solar System neighborhood

Author

Bergé, Joel, Baudis, Laura, Brax, Philippe, Chiow, Sheng-Wey, Christophe, Bruno, Doré, Olivier, Fayet, Pierre, Hees, Aurélien, Jetzer, Philippe, Lämmerzahl, Claus, List, Meike, Métris, Gilles, Pernot-Borràs, Martin, Read, Justin, Reynaud, Serge, Rhodes, Jason, Rievers, Benny, Rodrigues, Manuel, Sumner, Timothy, Uzan, Jean-Philippe, and Yu, Nan

Published

2021

49. Study of the open cluster Alessi-Teutsch 9 (ASCC 10) using multiband photometry and Gaia EDR3

Author

Sánchez, Néstor, López-Martínez, Fátima, Ocando, Sandra, and Blay, Pere

Published

2021

50. Cosmological Newtonian Limits on Large Spacetime Scales

Author

Liu, Chao and Oliynyk, Todd A.

Published

2018