Your search keyword '"Allende-Prieto, Carlos"' showing total 7 results

1. A stellar stream remnant of a globular cluster below the metallicity floor

Author

Martin, Nicolas F., Venn, Kim A., Aguado, David S., Starkenburg, Else, González Hernández, Jonay I., Ibata, Rodrigo A., Bonifacio, Piercarlo, Caffau, Elisabetta, Sestito, Federico, Arentsen, Anke, Allende Prieto, Carlos, Carlberg, Raymond G., Fabbro, Sébastien, Fouesneau, Morgan, Hill, Vanessa, Jablonka, Pascale, Kordopatis, Georges, Lardo, Carmela, Malhan, Khyati, Mashonkina, Lyudmila I., McConnachie, Alan W., Navarro, Julio F., Sánchez-Janssen, Rubén, Thomas, Guillaume F., Yuan, Zhen, and Mucciarelli, Alessio

Abstract

Stellar ejecta gradually enrich the gas out of which subsequent stars form, making the least chemically enriched stellar systems direct fossils of structures formed in the early Universe1. Although a few hundred stars with metal content below 1,000th of the solar iron content are known in the Galaxy2–4, none of them inhabit globular clusters, some of the oldest known stellar structures. These show metal content of at least approximately 0.2% of the solar metallicity ([Fe/H]≳−2.7). This metallicity floor appears universal5,6, and it has been proposed that protogalaxies that merged into the galaxies we observe today were simply not massive enough to form clusters that survived to the present day7. Here we report observations of a stellar stream, C-19, whose metallicity is less than 0.05% of the solar metallicity ([Fe/H]=−3.38±0.06(statistical)±0.20(systematic)). The low metallicity dispersion and the chemical abundances of the C-19 stars show that this stream is the tidal remnant of the most metal-poor globular cluster ever discovered, and is significantly below the purported metallicity floor: clusters with significantly lower metallicities than observed today existed in the past and contributed their stars to the Milky Way halo.

Published

2022

2. Nightside condensation of iron in an ultrahot giant exoplanet

Author

Ehrenreich, David, Lovis, Christophe, Allart, Romain, Zapatero Osorio, María Rosa, Pepe, Francesco, Cristiani, Stefano, Rebolo, Rafael, Santos, Nuno C., Borsa, Francesco, Demangeon, Olivier, Dumusque, Xavier, González Hernández, Jonay I., Casasayas-Barris, Núria, Ségransan, Damien, Sousa, Sérgio, Abreu, Manuel, Adibekyan, Vardan, Affolter, Michael, Allende Prieto, Carlos, Alibert, Yann, Aliverti, Matteo, Alves, David, Amate, Manuel, Avila, Gerardo, Baldini, Veronica, Bandy, Timothy, Benz, Willy, Bianco, Andrea, Bolmont, Émeline, Bouchy, François, Bourrier, Vincent, Broeg, Christopher, Cabral, Alexandre, Calderone, Giorgio, Pallé, Enric, Cegla, H. M., Cirami, Roberto, Coelho, João M. P., Conconi, Paolo, Coretti, Igor, Cumani, Claudio, Cupani, Guido, Dekker, Hans, Delabre, Bernard, Deiries, Sebastian, D’Odorico, Valentina, Di Marcantonio, Paolo, Figueira, Pedro, Fragoso, Ana, Genolet, Ludovic, Genoni, Matteo, Génova Santos, Ricardo, Hara, Nathan, Hughes, Ian, Iwert, Olaf, Kerber, Florian, Knudstrup, Jens, Landoni, Marco, Lavie, Baptiste, Lizon, Jean-Louis, Lendl, Monika, Lo Curto, Gaspare, Maire, Charles, Manescau, Antonio, Martins, C. J. A. P., Mégevand, Denis, Mehner, Andrea, Micela, Giusi, Modigliani, Andrea, Molaro, Paolo, Monteiro, Manuel, Monteiro, Mario, Moschetti, Manuele, Müller, Eric, Nunes, Nelson, Oggioni, Luca, Oliveira, António, Pariani, Giorgio, Pasquini, Luca, Poretti, Ennio, Rasilla, José Luis, Redaelli, Edoardo, Riva, Marco, Santana Tschudi, Samuel, Santin, Paolo, Santos, Pedro, Segovia Milla, Alex, Seidel, Julia V., Sosnowska, Danuta, Sozzetti, Alessandro, Spanò, Paolo, Suárez Mascareño, Alejandro, Tabernero, Hugo, Tenegi, Fabio, Udry, Stéphane, Zanutta, Alessio, and Zerbi, Filippo

Abstract

Ultrahot giant exoplanets receive thousands of times Earth’s insolation1,2. Their high-temperature atmospheres (greater than 2,000 kelvin) are ideal laboratories for studying extreme planetary climates and chemistry3–5. Daysides are predicted to be cloud-free, dominated by atomic species6and much hotter than nightsides5,7,8. Atoms are expected to recombine into molecules over the nightside9, resulting in different day and night chemistries. Although metallic elements and a large temperature contrast have been observed10–14, no chemical gradient has been measured across the surface of such an exoplanet. Different atmospheric chemistry between the day-to-night (‘evening’) and night-to-day (‘morning’) terminators could, however, be revealed as an asymmetric absorption signature during transit4,7,15. Here we report the detection of an asymmetric atmospheric signature in the ultrahot exoplanet WASP-76b. We spectrally and temporally resolve this signature using a combination of high-dispersion spectroscopy with a large photon-collecting area. The absorption signal, attributed to neutral iron, is blueshifted by −11 ± 0.7 kilometres per second on the trailing limb, which can be explained by a combination of planetary rotation and wind blowing from the hot dayside16. In contrast, no signal arises from the nightside close to the morning terminator, showing that atomic iron is not absorbing starlight there. We conclude that iron must therefore condense during its journey across the nightside.

Published

2020

3. Solar and stellar photospheric abundances

Author

Allende Prieto, Carlos

Abstract

The determination of photospheric abundances in late-type stars from spectroscopic observations is a well-established field, built on solid theoretical foundations. Improving those foundations to refine the accuracy of the inferred abundances has proven challenging, but progress has been made. In parallel, developments on instrumentation, chiefly regarding multi-object spectroscopy, have been spectacular, and a number of projects are collecting large numbers of observations for stars across the Milky Way and nearby galaxies, promising important advances in our understanding of galaxy formation and evolution. After providing a brief description of the basic physics and input data involved in the analysis of stellar spectra, a review is made of the analysis steps, and the available tools to cope with large observational efforts. The paper closes with a quick overview of relevant ongoing and planned spectroscopic surveys, and highlights of recent research on photospheric abundances.

Published

2016

4. Final design and progress of WEAVE: the next generation wide-field spectroscopy facility for the William Herschel Telescope

Author

Evans, Christopher J., Simard, Luc, Takami, Hideki, Dalton, Gavin, Trager, Scott, Abrams, Don Carlos, Bonifacio, Piercarlo, Aguerri, J. Alfonso L., Middleton, Kevin, Benn, Chris, Dee, Kevin, Sayède, Frédéric, Lewis, Ian, Pragt, Johannes, Pico, Sergio, Walton, Nic, Rey, Jeurg, Allende Prieto, Carlos, Peñate, José, Lhome, Emilie, Agócs, Tibor, Alonso, José, Terrett, David, Brock, Matthew, Gilbert, James, Schallig, Ellen, Ridings, Andy, Guinouard, Isabelle, Verheijen, Marc, Tosh, Ian, Rogers, Kevin, Lee, Martin, Steele, Iain, Stuik, Remko, Tromp, Niels, Jaskó, Attila, Carrasco, Esperanza, Farcas, Szigfrid, Kragt, Jan, Lesman, Dirk, Kroes, Gabby, Mottram, Chris, Bates, Stuart, Rodriguez, Luis Fernando, Gribbin, Frank, Delgado, José Miguel, Herreros, José Miguel, Martin, Carlos, Cano, Diego, Navarro, Ramon, Irwin, Mike, Lewis, Jim, Gonzalez Solares, Eduardo, Murphy, David, Worley, Clare, Bassom, Richard, O'Mahoney, Neil, Bianco, Andrea, Zurita, Christina, ter Horst, Rik, Molinari, Emilio, Lodi, Marcello, Guerra, José, Martin, Adrian, Vallenari, Antonella, Salasnich, Bernardo, Baruffolo, Andrea, Jin, Shoko, Hill, Vanessa, Smith, Dan, Drew, Janet, Poggianti, Bianca, Pieri, Mat, Dominquez Palmero, Lillian, and Farina, Cecilia

Published

2016

5. WEAVE core processing system

Author

Chiozzi, Gianluca, Radziwill, Nicole M., Walton, Nicholas A., Irwin, Mike, Lewis, James R., Gonzalez-Solares, Eduardo, Dalton, Gavin, Trager, Scott, Aguerri, J. Alfonso L., Allende Prieto, Carlos, Benn, Chris R., Abrams, Don Carlos, Picó, Sergio, Middleton, Kevin, Lodi, Marcello, and Bonifacio, Piercarlo

Published

2014

6. Project overview and update on WEAVE: the next generation wide-field spectroscopy facility for the William Herschel Telescope

Author

Ramsay, Suzanne K., McLean, Ian S., Takami, Hideki, Dalton, Gavin, Trager, Scott, Abrams, Don Carlos, Bonifacio, Piercarlo, López Aguerri, J. Alfonso, Middleton, Kevin, Benn, Chris, Dee, Kevin, Sayède, Frédéric, Lewis, Ian, Pragt, Johan, Pico, Sergio, Walton, Nic, Rey, Juerg, Allende Prieto, Carlos, Peñate, José, Lhome, Emilie, Agócs, Tibor, Alonso, José, Terrett, David, Brock, Matthew, Gilbert, James, Ridings, Andy, Guinouard, Isabelle, Verheijen, Mark, Tosh, Ian, Rogers, Kevin, Steele, Iain, Stuik, Remko, Tromp, Neils, Jasko, Attila, Kragt, Jan, Lesman, Dirk, Mottram, Chris, Bates, Stuart, Gribbin, Frank, Rodriguez, Luis Fernando, Delgado, José M., Martin, Carlos, Cano, Diego, Navarro, Ramón, Irwin, Mike, Lewis, Jim, Gonzalez Solares, Eduardo, O'Mahony, Neil, Bianco, Andrea, Zurita, Christina, ter Horst, Rik, Molinari, Emilio, Lodi, Marcello, Guerra, José, Vallenari, Antonella, and Baruffolo, Andrea

Published

2014

7. Model Photospheres for Late-Type Stars from the Inversion of High-Resolution Spectroscopic Observations: The Sun

Author

Allende Prieto, Carlos, Ruiz Cobo, Basilio, and García López, J.

Abstract

An inversion technique has been developed to recover LTE, one-dimensional, model photospheres for late-type stars from very high resolution, high signal-to-noise ratio stellar line profiles. It is successfully applied to the Sun by using a set of clean Ti I, Ca I, Cr I, and Fe Inormalized line profiles with accurate transition probabilities, taking advantage of the well-understood collisional enhancement of the wings of the Ca Iline at 6162 Å. Line and continuum center-to-limb variations, continuum flux, and wings of strong metal lines are synthesized by means of the model obtained and are compared with solar observations, as well as with predictions from other well-known theoretical and empirical solar models, showing the reliability of the inversion procedure. The prospects for and limitations of the application of this method to other late-type stars are discussed.

Published

1998