Your search keyword '"Schreck, Florian"' showing total 175 results

1. Parallel assembly of neutral atom arrays with an SLM using linear phase interpolation

Author

Knottnerus, Ivo H. A., Tseng, Yu Chih, Urech, Alexander, Spreeuw, Robert J. C., and Schreck, Florian

Subjects

Quantum Physics, Physics - Atomic Physics

Abstract

We present fast parallel rearrangement of single atoms in optical tweezers into arbitrary geometries by updating holograms displayed by an ultra fast spatial light modulator. Using linear interpolation of the tweezer position and the optical phase between the start and end arrays, we can calculate and display holograms every 2.76(2) ms. To show the versatility of our method, we sort the same atomic sample into multiple geometries with success probabilities exceeding 99 % per imaging and rearrangement cycle. This makes the method a useful tool for rearranging large atom arrays for quantum computation and quantum simulation.

Published

2025

2. Terrestrial Very-Long-Baseline Atom Interferometry: Summary of the Second Workshop

Author

Abdalla, Adam, Abe, Mahiro, Abend, Sven, Abidi, Mouine, Aidelsburger, Monika, Alibabaei, Ashkan, Allard, Baptiste, Antoniadis, John, Arduini, Gianluigi, Augst, Nadja, Balamatsias, Philippos, Balaz, Antun, Banks, Hannah, Barcklay, Rachel L., Barone, Michele, Barsanti, Michele, Bason, Mark G., Bassi, Angelo, Bayle, Jean-Baptiste, Baynham, Charles F. A., Beaufils, Quentin, Beldjoudi, Slyan, Belic, Aleksandar, Bennetts, Shayne, Bernabeu, Jose, Bertoldi, Andrea, Bigard, Clara, Bigelow, N. P., Bingham, Robert, Blas, Diego, Bobrick, Alexey, Boehringer, Samuel, Bogojevic, Aleksandar, Bongs, Kai, Bortoletto, Daniela, Bouyer, Philippe, Brand, Christian, Buchmueller, Oliver, Buica, Gabriela, Calatroni, Sergio, Calmels, Lo, Canizares, Priscilla, Canuel, Benjamin, Caramete, Ana, Caramete, Laurentiu-Ioan, Carlesso, Matteo, Carlton, John, Carman, Samuel P., Carroll, Andrew, Casariego, Mateo, Chairetis, Minoas, Charmandaris, Vassilis, Chauhan, Upasna, Chen, Jiajun, Luisa, Maria, Chiofalo, Ciampini, Donatella, Cimbri, Alessia, Clad, Pierre, Coleman, Jonathon, Constantin, Florin Lucian, Contaldi, Carlo R., Corgier, Robin, Dash, Bineet, Davies, G. J., de Rham, Claudia, De Roeck, Albert, Derr, Daniel, Dey, Soumyodeep, Di Pumpo, Fabio, Djordjevic, Goran S., Doebrich, Babette, Dornan, Peter, Doser, Michael, Drougakis, Giannis, Dunningham, Jacob, Duspayev, Alisher, Easo, Sajan, Eby, Joshua, Efremov, Maxim, Elertas, Gedminas, Ellis, John, Entin, Nicholas, Fairhurst, Stephen, Fani, Mattia, Fassi, Farida, Fayet, Pierre, Felea, Daniel, Feng, Jie, Flack, Robert, Foot, Chris, Freegarde, Tim, Fuchs, Elina, Gaaloul, Naceur, Gao, Dongfeng, Gardner, Susan, Garraway, Barry M., Alzar, Carlos L. Garrido, Gauguet, Alexandre, Giese, Enno, Gill, Patrick, Giudice, Gian F., Glasbrenner, Eric P., Glick, Jonah, Graham, Peter W., Granados, Eduardo, Griffin, Paul F., Gue, Jordan, Guellati-Khelifa, Saida, Gupta, Subhadeep, Gupta, Vishu, Hackermueller, Lucia, Haehnelt, Martin, Hakulinen, Timo, Hammerer, Klemens, Hanimeli, Ekim T., Harte, Tiffany, Hartmann, Sabrina, Hawkins, Leonie, Hees, Aurelien, Herbst, Alexander, Hird, Thomas M., Hobson, Richard, Hogan, Jason, Holst, Bodil, Holynski, Michael, Hosten, Onur, Hsu, Chung Chuan, Huang, Wayne Cheng-Wei, Hughes, Kenneth M., Hussain, Kamran, Huetsi, Gert, Iovino, Antonio, Isfan, Maria-Catalina, Janson, Gregor, Jeglic, Peter, Jetzer, Philippe, Jiang, Yijun, Juzeliunas, Gediminas, Kaenders, Wilhelm, Kalliokoski, Matti, Kehagias, Alex, Kilian, Eva, Klempt, Carsten, Knight, Peter, Koley, Soumen, Konrad, Bernd, Kovachy, Tim, Krutzik, Markus, Kumar, Mukesh, Kumar, Pradeep, Labiad, Hamza, Lan, Shau-Yu, Landragin, Arnaud, Landsberg, Greg, Langlois, Mehdi, Lanigan, Bryony, Poncin-Lafitte, Christophe Le, Lellouch, Samuel, Leone, Bruno, Lewicki, Marek, Lien, Yu-Hung, Lombriser, Lucas, Asamar, Elias Lopez, Lopez-Gonzalez, J. Luis, Lowe, Adam, Lu, Chen, Luciano, Giuseppe Gaetano, Lundblad, Nathan, Monjaraz, Cristian de J. Lpez, Mackoit-Sinkeviien, Maena, Maggiore, Michele, Majumdar, Anirban, Makris, Konstantinos, Maleknejad, Azadeh, Marchant, Anna L., Mariotti, Agnese, Markou, Christos, Matthews, Barnaby, Mazumdar, Anupam, McCabe, Christopher, Meister, Matthias, Mentasti, Giorgio, Menu, Jonathan, Messineo, Giuseppe, Meyer-Hoppe, Bernd, Micalizio, Salvatore, Migliaccio, Federica, Millington, Peter, Milosevic, Milan, Mishra, Abhay, Mitchell, Jeremiah, Morley, Gavin W., Mouelle, Noam, Mueller, Juergen, Newbold, David, Ni, Wei-Tou, Niehof, Christian, Noller, Johannes, Odzak, Senad, Oi, Daniel K. L., Oikonomou, Andreas, Omar, Yasser, Overstreet, Chris, Pahl, Julia, Paling, Sean, Pan, Zhongyin, Pappas, George, Pareek, Vinay, Pasatembou, Elizabeth, Paternostro, Mauro, Pathak, Vishal K., Pelucchi, Emanuele, Santos, Franck Pereira dos, Peters, Achim, Pichery, Annie, Pikovski, Igor, Pilaftsis, Apostolos, Pislan, Florentina-Crenguta, Plunkett, Robert, Poggiani, Rosa, Prevedelli, Marco, Veettil, Vishnupriya Puthiya, Rafelski, Johann, Raidal, Juhan, Raidal, Martti, Rasel, Ernst Maria, Renaux-Petel, Sebastien, Richaud, Andrea, Rivero-Antunez, Pedro, Rodzinka, Tangui, Roura, Albert, Rudolph, Jan, Sabulsky, Dylan, Safronova, Marianna S., Sakellariadou, Mairi, Salvi, Leonardo, Sameed, Muhammed, Sarkar, Sumit, Schach, Patrik, Schaeffer, Stefan Alaric, Schelfhout, Jesse, Schilling, Manuel, Schkolnik, Vladimir, Schleich, Wolfgang P., Schlippert, Dennis, Schneider, Ulrich, Schreck, Florian, Schwartzman, Ariel, Schwersenz, Nico, Sergijenko, Olga, Sfar, Haifa Rejeb, Shao, Lijing, Shipsey, Ian, Shu, Jing, Singh, Yeshpal, Sopuerta, Carlos F., Sorba, Marianna, Sorrentino, Fiodor, Spallicci, Alessandro D. A. M, Stefanescu, Petruta, Stergioulas, Nikolaos, Stoerk, Daniel, Stroehle, Jannik, Sunilkumar, Hrudya Thaivalappil, Tam, Zoie, Tandon, Dhruv, Tang, Yijun, Tell, Dorothee, Tempere, Jacques, Temples, Dylan J., Thampy, Rohit P, Tietje, Ingmari C., Tino, Guglielmo M., Tinsley, Jonathan N., Mircea, Ovidiu Tintareanu, Tkalec, Kimberly, Tolley, Andrew J., Tornatore, Vincenza, Torres-Orjuela, Alejandro, Treutlein, Philipp, Trombettoni, Andrea, Ufrecht, Christian, Urrutia, Juan, Valenzuela, Tristan, Valerio, Linda R., van der Grinten, Maurits, Vaskonen, Ville, Vazquez-Aceves, Veronica, Veermae, Hardi, Vetrano, Flavio, Vitanov, Nikolay V., von Klitzing, Wolf, Wald, Sebastian, Walker, Thomas, Walser, Reinhold, Wang, Jin, Wang, Yan, Weidner, C. A., Wenzlawski, Andr, Werner, Michael, Woerner, Lisa, Yahia, Mohamed E., Yazgan, Efe, Cruzeiro, Emmanuel Zambrini, Zarei, M., Zhan, Mingsheng, Zhang, Shengnan, Zhou, Lin, and Zupanic, Erik

Subjects

High Energy Physics - Experiment, Astrophysics - Instrumentation and Methods for Astrophysics, General Relativity and Quantum Cosmology, High Energy Physics - Phenomenology, Physics - Atomic Physics

Abstract

This summary of the second Terrestrial Very-Long-Baseline Atom Interferometry (TVLBAI) Workshop provides a comprehensive overview of our meeting held in London in April 2024, building on the initial discussions during the inaugural workshop held at CERN in March 2023. Like the summary of the first workshop, this document records a critical milestone for the international atom interferometry community. It documents our concerted efforts to evaluate progress, address emerging challenges, and refine strategic directions for future large-scale atom interferometry projects. Our commitment to collaboration is manifested by the integration of diverse expertise and the coordination of international resources, all aimed at advancing the frontiers of atom interferometry physics and technology, as set out in a Memorandum of Understanding signed by over 50 institutions., Comment: Summary of the second Terrestrial Very-Long-Baseline Atom Interferometry Workshop held at Imperial College London: https://indico.cern.ch/event/1369392/

Published

2024

3. Modeling of a continuous superradiant laser on the sub-mHz $^1$S$_0\,\rightarrow\,^3$P$_0$ transition in neutral strontium-88

Author

Dubey, Swadheen, Kazakov, Georgy A., Heizenreder, Benedikt, Zhou, Sheng, Bennetts, Shayne, Schäffer, Stefan Alaric, Sitaram, Ananya, and Schreck, Florian

Subjects

Physics - Atomic Physics, Quantum Physics

Abstract

Continuous superradiance using a narrow optical transition has the potential to improve the short-term stability of state-of-the-art optical clocks. Even though pulsed superradiant emission on a mHz linewidth clock transition has been shown, true continuous operation, without Fourier limitation, has turned out to be extremely challenging. The trade-off between maintaining a high atomic flux while minimizing decoherence effects presents a significant obstacle. Here, we discuss the design of a machine that could overcome this problem by combining a high-flux continuous beam of ultra cold strontium atoms with a bowtie cavity for the generation of superradiant lasing. To evaluate the feasibility of our design, we present simulation results for continuous high-efficiency cooling, loading, and pumping to the upper lasing state inside the bowtie cavity. We then present two different models for stimulating the generated superradiant field by taking into account position-dependent shifts, collisional decoherence, light shifts, and atom loss. Finally, we estimate a laser linewidth of less than 100 mHz, limited by atom number fluctuations, and resulting in an output power of hundreds of fW., Comment: 22 pages, 9 figures

Published

2024

4. Continuous cavity-QED with an atomic beam

Author

Famà, Francesca, Zhou, Sheng, Heizenreder, Benedikt, Tang, Mikkel, Bennetts, Shayne, Jäger, Simon B., Schäffer, Stefan A., and Schreck, Florian

Subjects

Physics - Atomic Physics, Quantum Physics

Abstract

Atoms coupled to cavities provide an exciting playground for the study of fundamental interactions of atoms mediated through a common channel. Many of the applications of cavity-QED and cold-atom experiments more broadly, suffer from limitations caused by the transient nature of an atomic loading cycle. The development of continuous operation schemes is necessary to push these systems to the next level of performance. Here we present a machine designed to produce a continuous flux of collimated atoms that traverse an optical cavity. The atom-light interaction is enhanced by a fast-decaying cavity optimal for studying phenomena where atomic properties dominate. We demonstrate the transition to a collective strong coupling regime heralded by a normal-mode splitting. We observe a second phase with a binary normal-mode splitting born from an offset in the mean velocity of the atoms. Inverting the atomic ensemble in the collective strong coupling regime, we measure continuous optical gain. This work sets the stage for studying threshold conditions for continuous collective phenomena, such as continuous superradiant lasing.

Published

2024

5. Coherent Three-Photon Excitation of the Strontium Clock Transition

Author

He, Junyu, Pasquiou, Benjamin, Escudero, Rodrigo Gonzalez, Zhou, Sheng, Borkowski, Mateusz, and Schreck, Florian

Subjects

Condensed Matter - Quantum Gases, Physics - Atomic Physics

Abstract

We demonstrate coherent three-photon excitation of the strontium clock transition with a contrast of 51(12)% using a Bose-Einstein condensate. We follow it up with a demonstration of three-photon STIRAP-like transfer, overcoming the typical limitations of this technique to odd-level numbers. We also measure the two-body loss coefficient of $^{84}$Sr clock-state atoms. Our work constitutes an essential step towards outcoupling a continuous atom laser beam and provides a fast excitation mechanism for quantum simulation using bosonic alkaline-earth-like atoms., Comment: 8 pages, 6 figures, neatly condensed

Published

2024

6. Optical pumping of ${\mathrm{5s4d} ^1\mathrm{D}_2}$ strontium atoms for laser cooling and imaging

Author

Samland, Jens, Bennetts, Shayne, Chen, Chun-Chia, Escudero, Rodrigo González, Schreck, Florian, and Pasquiou, Benjamin

Subjects

Physics - Atomic Physics

Abstract

We present a faster repumping scheme for strontium magneto-optical traps operating on the broad ${\mathrm{5s^2} ^1\mathrm{S}_0} - {\mathrm{5s5p} ^1\mathrm{P}_1}$ laser cooling transition. Contrary to existing repumping schemes, we directly address lost atoms that spontaneously decayed to the ${\mathrm{5s4d} ^1\mathrm{D}_2}$ state, sending them back into the laser cooling cycle by optical pumping on the ${\mathrm{5s4d} ^1\mathrm{D}_2} - {\mathrm{5s8p} ^1\mathrm{P}_1}$ transition. We thus avoid the $\sim 100 \, \mathrm{\mu s}$-slow decay path from ${\mathrm{5s4d} ^1\mathrm{D}_2}$ to the ${\mathrm{5s5p} ^3\mathrm{P}_{1,2}}$ states that is part of other repumping schemes. Using one low-cost external-cavity diode laser emitting at $448 \, \mathrm{nm}$, we show our scheme increases the flux out of a 2D magneto-optical trap by $60 \, \%$ compared to without repumping. Furthermore, we perform spectroscopy on the ${\mathrm{5s4d} ^1\mathrm{D}_2} - {\mathrm{5s8p} ^1\mathrm{P}_1}$ transition and measure its frequency $\nu_{\mathrm{^{88}Sr}} = (668917515.3 \pm 4.0 \pm 25) \, \mathrm{MHz}$. We also measure the frequency shifts between the four stable isotopes of strontium and infer the specific mass and field shift factors, $\delta \nu_\text{SMS} ^{88,86} = -267(45) \, \mathrm{MHz}$ and $\delta \nu_\text{FS} ^{88,86} = 2(42) \, \mathrm{MHz}$. Finally, we measure the hyperfine splitting of the ${\mathrm{5s8p} ^1\mathrm{P}_1}$ state in fermionic strontium, and deduce the magnetic dipole and electric quadrupole coupling coefficients $A = -4(5) \, \mathrm{MHz}$ and $B = 5(35) \, \mathrm{MHz}$. Our experimental demonstration shows that this simple and very fast scheme could improve the laser cooling and imaging performance of cold strontium atom devices, such as quantum computers based on strontium atoms in arrays of optical tweezers., Comment: 10 pages, 5 figures

Published

2023

7. Terrestrial Very-Long-Baseline Atom Interferometry: Workshop Summary

Author

Abend, Sven, Allard, Baptiste, Alonso, Iván, Antoniadis, John, Araujo, Henrique, Arduini, Gianluigi, Arnold, Aidan, Aßmann, Tobias, Augst, Nadja, Badurina, Leonardo, Balaz, Antun, Banks, Hannah, Barone, Michele, Barsanti, Michele, Bassi, Angelo, Battelier, Baptiste, Baynham, Charles, Quentin, Beaufils, Belic, Aleksandar, Beniwal, Ankit, Bernabeu, Jose, Bertinelli, Francesco, Bertoldi, Andrea, Biswas, Ikbal Ahamed, Blas, Diego, Boegel, Patrick, Bogojevic, Aleksandar, Böhm, Jonas, Böhringer, Samuel, Bongs, Kai, Bouyer, Philippe, Brand, Christian, Brimis, Apostolos, Buchmueller, Oliver, Cacciapuoti, Luigi, Calatroni, Sergio, Canuel, Benjamin, Caprini, Chiara, Caramete, Ana, Caramete, Laurentiu, Carlesso, Matteo, Carlton, John, Casariego, Mateo, Charmandaris, Vassilis, Chen, Yu-Ao, Chiofalo, Maria Luisa, Cimbri, Alessia, Coleman, Jonathon, Constantin, Florin Lucian, Contaldi, Carlo, Cui, Yanou, Da Ros, Elisa, Davies, Gavin, Rosendo, Esther del Pino, Deppner, Christian, Derevianko, Andrei, de Rham, Claudia, De Roeck, Albert, Derr, Daniel, Di Pumpo, Fabio, Djordjevic, Goran, Dobrich, Babette, Domokos, Peter, Dornan, Peter, Doser, Michael, Drougakis, Giannis, Dunningham, Jacob, Duspayev, Alisher, Easo, Sajan, Eby, Joshua, Efremov, Maxim, Ekelof, Tord, Elertas, Gedminas, Ellis, John, Evans, David, Fadeev, Pavel, Fanì, Mattia, Fassi, Farida, Fattori, Marco, Fayet, Pierre, Felea, Daniel, Feng, Jie, Friedrich, Alexander, Fuchs, Elina, Gaaloul, Naceur, Gao, Dongfeng, Gardner, Susan, Garraway, Barry, Gauguet, Alexandre, Gerlach, Sandra, Gersemann, Matthias, Gibson, Valerie, Giese, Enno, Giudice, Gian Francesco, Glasbrenner, Eric, Gündogan, Mustafa, Haehnelt, Martin G., Hakulinen, Timo, Hammerer, Klemens, Hanımeli, Ekim Taylan, Harte, Tiffany, Hawkins, Leonie, Hees, Aurelien, Heise, Jaret, Henderson, Victoria, Herrmann, Sven, Hird, Thomas, Hogan, Jason, Holst, Bodil, Holynski, Michael, Hussain, Kamran, Janson, Gregor, Jeglič, Peter, Jelezko, Fedor, Kagan, Michael, Kalliokoski, Matti, Kasevich, Mark, Kehagias, Alex, Kilian, Eva, Koley, Soumen, Konrad, Bernd, Kopp, Joachim, Kornakov, Georgy, Kovachy, Tim, Krutzik, Markus, Kumar, Mukesh, Kumar, Pradeep, Laemmerzahl, Claus, Landsberg, Greg, Langlois, Mehdi, Lanigan, Bryony, Lellouch, Samuel, Leone, Bruno, Lafitte, Christophe Le Poncin, Lewicki, Marek, Leykauf, Bastian, Lezeik, Ali, Lombriser, Lucas, López, Luis, Asamar, Elias López, Monjaraz, Cristian López, Luciano, Gaetano, Mohammed, Mohammed Mahmoud, Maleknejad, Azadeh, Markus, Krutzik, Marteau, Jacques, Massonnet, Didier, Mazumdar, Anupam, McCabe, Christopher, Meister, Matthias, Menu, Jonathan, Messineo, Giuseppe, Micalizio, Salvatore, Millington, Peter, Milosevic, Milan, Mitchell, Jeremiah, Montero, Mario, Morley, Gavin, Müller, Jürgen, Müstecaplıoğlu, Özgür, Ni, Wei-Tou, Noller, Johannes, Odžak, Senad, Oi, Daniel, Omar, Yasser, Pahl, Julia, Paling, Sean, Pandey, Saurabh, Pappas, George, Pareek, Vinay, Pasatembou, Elizabeth, Pelucchi, Emanuele, Santos, Franck Pereira dos, Piest, Baptist, Pikovski, Igor, Pilaftsis, Apostolos, Plunkett, Robert, Poggiani, Rosa, Prevedelli, Marco, Puputti, Julia, Veettil, Vishnupriya Puthiya, Quenby, John, Rafelski, Johann, Rajendran, Surjeet, Rasel, Ernst Maria, Sfar, Haifa Rejeb, Reynaud, Serge, Richaud, Andrea, Rodzinka, Tangui, Roura, Albert, Rudolph, Jan, Sabulsky, Dylan, Safronova, Marianna, Santamaria, Luigi, Schilling, Manuel, Schkolnik, Vladimir, Schleich, Wolfgang, Schlippert, Dennis, Schneider, Ulrich, Schreck, Florian, Schubert, Christian, Schwersenz, Nico, Semakin, Aleksei, Sergijenko, Olga, Shao, Lijing, Shipsey, Ian, Singh, Rajeev, Smerzi, Augusto, Sopuerta, Carlos F., Spallicci, Alessandro, Stefanescu, Petruta, Stergioulas, Nikolaos, Ströhle, Jannik, Struckmann, Christian, Tentindo, Silvia, Throssell, Henry, Tino, Guglielmo M., Tinsley, Jonathan, Mircea, Ovidiu Tintareanu, Tkalčec, Kimberly, Tolley, Andrew, Tornatore, Vincenza, Torres-Orjuela, Alejandro, Treutlein, Philipp, Trombettoni, Andrea, Tsai, Yu-Dai, Ufrecht, Christian, Ulmer, Stefan, Valuch, Daniel, Vaskonen, Ville, Aceves, Veronica Vazquez, Vitanov, Nikolay, Vogt, Christian, von Klitzing, Wolf, Vukics, András, Walser, Reinhold, Wang, Jin, Warburton, Niels, Webber-Date, Alexander, Wenzlawski, André, Werner, Michael, Williams, Jason, Windapssinger, Patrcik, Wolf, Peter, Wörner, Lisa, Xuereb, André, Yahia, Mohamed, Cruzeiro, Emmanuel Zambrini, Zarei, Moslem, Zhan, Mingsheng, Zhou, Lin, Zupan, Jure, and Zupanič, Erik

Subjects

High Energy Physics - Experiment, Astrophysics - Instrumentation and Methods for Astrophysics, General Relativity and Quantum Cosmology, High Energy Physics - Phenomenology, Physics - Atomic Physics

Abstract

This document presents a summary of the 2023 Terrestrial Very-Long-Baseline Atom Interferometry Workshop hosted by CERN. The workshop brought together experts from around the world to discuss the exciting developments in large-scale atom interferometer (AI) prototypes and their potential for detecting ultralight dark matter and gravitational waves. The primary objective of the workshop was to lay the groundwork for an international TVLBAI proto-collaboration. This collaboration aims to unite researchers from different institutions to strategize and secure funding for terrestrial large-scale AI projects. The ultimate goal is to create a roadmap detailing the design and technology choices for one or more km-scale detectors, which will be operational in the mid-2030s. The key sections of this report present the physics case and technical challenges, together with a comprehensive overview of the discussions at the workshop together with the main conclusions., Comment: Summary of the Terrestrial Very-Long-Baseline Atom Interferometry Workshop held at CERN: https://indico.cern.ch/event/1208783/

Published

2023

8. Active stabilization of kilogauss magnetic fields to the ppm level for magnetoassociation on ultranarrow Feshbach resonances

Author

Borkowski, Mateusz, Reichsöllner, Lukas, Thekkeppatt, Premjith, Barbé, Vincent, van Roon, Tijs, van Druten, Klaasjan, and Schreck, Florian

Subjects

Physics - Atomic Physics

Abstract

Feshbach association of ultracold molecules using narrow resonances requires exquisite control of the applied magnetic field. Here we present a magnetic field control system to deliver magnetic fields of over 1000 G with ppm-level precision integrated into an ultracold-atom experimental setup. We combine a battery-powered current-stabilized power supply with active feedback stabilization of the magnetic field using fluxgate magnetic field sensors. As a real-world test we perform microwave spectroscopy of ultracold Rb atoms and demonstrate an upper limit on our magnetic field stability of 2.4(3) mG at 1050 G [2.3(3) ppm relative] as determined from the spectral feature., Comment: 9 pages, 4 figures, corrected references and abstract

Published

2023

9. Laser cooling for quantum gases

Author

Schreck, Florian and van Druten, Klaasjan

Subjects

Condensed Matter - Quantum Gases, Physics - Atomic Physics

Abstract

Laser cooling exploits the physics of light scattering to cool atomic and molecular gases to close to absolute zero. It is the crucial initial step for essentially all atomic gas experiments in which Bose-Einstein condensation and, more generally, quantum degeneracy is reached. The ongoing development of laser-cooling methods has allowed more elements to be brought to quantum degeneracy, with each additional atomic species offering its own experimental opportunities. Improved methods are opening new avenues, for example, reaching Bose-Einstein condensation purely through laser cooling as well as the realization of continuous Bose-Einstein condensation. Here we review these recent innovations in laser cooling and provide an outlook on methods that may enable new ways of creating quantum gases., Comment: 13 pages, 4 figures

Published

2022

10. Narrow-line imaging of single strontium atoms in shallow optical tweezers

Author

Urech, Alexander, Knottnerus, Ivo H. A., Spreeuw, Robert J. C., and Schreck, Florian

Subjects

Physics - Atomic Physics, Condensed Matter - Quantum Gases

Abstract

Single strontium atoms held in optical tweezers have so far only been imaged using the broad $^{1\hspace{-0.3ex}}S_0$-$^{1\hspace{-0.3ex}}P_1$ transition. For Yb, use of the narrow (183 kHz-wide) $^{1\hspace{-0.3ex}}S_0$-$^{3\hspace{-0.3ex}}P_1$ transition for simultaneous imaging and cooling has been demonstrated in tweezers with a magic wavelength for the imaging transition. We demonstrate high-fidelity imaging of single Sr atoms using its even narrower (7.4 kHz-wide) $^{1\hspace{-0.3ex}}S_0$ - $^{3\hspace{-0.3ex}}P_1$ transition. The atoms are trapped in \textit{non}-magic-wavelength tweezers. We detect the photons scattered during Sisyphus cooling, thus keeping the atoms near the motional ground state of the tweezer throughout imaging. The fidelity of detection is 0.9991(4) with a survival probability of 0.97(2). An atom in a tweezer can be held under imaging conditions for 79(3) seconds allowing for hundreds of images to be taken, limited mainly by background gas collisions. We detect atoms in an arrary of 36 tweezers with 813.4-nm light and trap depths of 135(20) $\mu$K. This trap depth is three times shallower than typically used for imaging on the broad $^{1\hspace{-0.3ex}}S_0$ - $^{1\hspace{-0.3ex}}P_1$ transition. Narrow-line imaging opens the possibility to even further reduce this trap depth, as long as all trap frequencies are kept larger than the imaging transition linewidth. Imaging using a narrow-linewidth transition in a non-magic-wavelength tweezer also allows for selective imaging of a given tweezer. As a demonstration, we selectively image (hide) a single tweezer from the array. This provides a useful tool for quantum error correction protocols., Comment: 11 pages, 6 figures

Published

2022

11. Cold Atoms in Space: Community Workshop Summary and Proposed Road-Map

Author

Alonso, Ivan, Alpigiani, Cristiano, Altschul, Brett, Araujo, Henrique, Arduini, Gianluigi, Arlt, Jan, Badurina, Leonardo, Balaz, Antun, Bandarupally, Satvika, Barone, Barry C Barish Michele, Barsanti, Michele, Bass, Steven, Bassi, Angelo, Battelier, Baptiste, Baynham, Charles F. A., Beaufils, Quentin, Belic, Aleksandar, Berge, Joel, Bernabeu, Jose, Bertoldi, Andrea, Bingham, Robert, Bize, Sebastien, Blas, Diego, Bongs, Kai, Bouyer, Philippe, Braitenberg, Carla, Brand, Christian, Braxmaier, Claus, Bresson, Alexandre, Buchmueller, Oliver, Budker, Dmitry, Bugalho, Luıs, Burdin, Sergey, Callegari, Luigi Cacciapuoti Simone, Calmet, Xavier, Calonico, Davide, Canuel, Benjamin, Caramete, Laurentiu-Ioan, Carraz, Olivier, Cassettari, Donatella, Chakraborty, Pratik, Chattopadhyay, Swapan, Chauhan, Upasna, Chen, Xuzong, Chen, Yu-Ao, Chiofalo, Maria Luisa, Coleman, Jonathon, Corgier, Robin, Cotter, J. P., Cruise, A. Michael, Cui, Yanou, Davies, Gavin, De Roeck, Albert, Demarteau, Marcel, Derevianko, Andrei, Di Clemente, Marco, Djordjevic, Goran S., Donadi, Sandro, Dore, Olivier, Dornan, Peter, Doser, Michael, Drougakis, Giannis, Dunningham, Jacob, Easo, Sajan, Eby, Joshua, Elertas, Gedminas, Ellis, John, Evans, David, Examilioti, Pandora, Fadeev, Pavel, Fanı, Mattia, Fassi, Farida, Fattori, Marco, Fedderke, Michael A., Felea, Daniel, Feng, Chen-Hao, Ferreras, Jorge, Flack, Robert, Flambaum, Victor V., Forsberg, Rene, Fromhold, Mark, Gaaloul, Naceur, Garraway, Barry M., Georgousi, Maria, Geraci, Andrew, Gibble, Kurt, Gibson, Valerie, Gill, Patrick, Giudice, Gian F., Goldwin, Jon, Gould, Oliver, Grachov, Oleg, Graham, Peter W., Grasso, Dario, Griffin, Paul F., Guerlin, Christine, Gundogan, Mustafa, Gupta, Ratnesh K, Haehnelt, Martin, Hanımeli, Ekim T., Hawkins, Leonie, Hees, Aurelien, Henderson, Victoria A., Herr, Waldemar, Herrmann, Sven, Hird, Thomas, Hobson, Richard, Hock, Vincent, Hogan, Jason M., Holst, Bodil, Holynski, Michael, Israelsson, Ulf, Jeglic, Peter, Jetzer, Philippe, Juzeliunas, Gediminas, Kaltenbaek, Rainer, Kamenik, Jernej F., Kehagias, Alex, Kirova, Teodora, Kiss-Toth, Marton, Koke, Sebastian, Kolkowitz, Shimon, Kornakov, Georgy, Kovachy, Tim, Krutzik, Markus, Kumar, Mukesh, Kumar, Pradeep, Lammerzahl, Claus, Landsberg, Greg, Poncin-Lafitte, Christophe Le, Leibrandt, David R., Leveque, Thomas, Lewicki, Marek, Li, Rui, Lipniacka, Anna, Liu, Christian Lisdat Mia, Lopez-Gonzalez, J. L., Loriani, Sina, Louko, Jorma, Luciano, Giuseppe Gaetano, Lundblad, Nathan, Maddox, Steve, Mahmoud, M. A., Maleknejad, Azadeh, March-Russell, John, Massonnet, Didier, McCabe, Christopher, Meister, Matthias, Meznarsic, Tadej, Micalizio, Salvatore, Migliaccio, Federica, Millington, Peter, Milosevic, Milan, Mitchell, Jeremiah, Morley, Gavin W., Muller, Jurgen, Murphy, Eamonn, Mustecaplıoglu, Ozgur E., OShea, Val, Oi, Daniel K. L., Olson, Judith, Pal, Debapriya, Papazoglou, Dimitris G., Pasatembou, Elizabeth, Paternostro, Mauro, Pawlowski, Krzysztof, Pelucchi, Emanuele, Santos, Franck Pereira dos, Peters, Achim, Pikovski, Igor, Pilaftsis, Apostolos, Pinto, Alexandra, Prevedelli, Marco, Puthiya-Veettil, Vishnupriya, Quenby, John, Rafelski, Johann, Rasel, Ernst M., Ravensbergen, Cornelis, Reguzzoni, Mirko, Richaud, Andrea, Riou, Isabelle, Rothacher, Markus, Roura, Albert, Ruschhaupt, Andreas, Sabulsky, Dylan O., Safronova, Marianna, Saltas, Ippocratis D., Salvi, Leonardo, Sameed, Muhammed, Saurabh, Pandey, Schaffer, Stefan, Schiller, Stephan, Schilling, Manuel, Schkolnik, Vladimir, Schlippert, Dennis, Schmidt, Piet O., Schnatz, Harald, Schneider, Jean, Schneider, Ulrich, Schreck, Florian, Schubert, Christian, Shayeghi, Armin, Sherrill, Nathaniel, Shipsey, Ian, Signorini, Carla, Singh, Rajeev, Singh, Yeshpal, Skordis, Constantinos, Smerzi, Augusto, Sopuerta, Carlos F., Sorrentino, Fiodor, Sphicas, Paraskevas, Stadnik, Yevgeny V., Stefanescu, Petruta, Tarallo, Marco G., Tentindo, Silvia, Tino, Guglielmo M., Tinsley, Jonathan N., Tornatore, Vincenza, Treutlein, Philipp, Trombettoni, Andrea, Tsai, Yu-Dai, Tuckey, Philip, Uchida, Melissa A, Valenzuela, Tristan, Bossche, Mathias Van Den, Vaskonen, Ville, Verma, Gunjan, Vetrano, Flavio, Vogt, Christian, von Klitzing, Wolf, Waller, Pierre, Walser, Reinhold, Williams, Eric Wille Jason, Windpassinger, Patrick, Wittrock, Ulric, Wolf, Peter, Woltmann, Marian, Worner, Lisa, Xuereb, Andre, Yahia, Mohamed, Yazgan, Efe, Yu, Nan, Zahzam, Nassim, Cruzeiro, Emmanuel Zambrini, Zhan, Mingsheng, Zou, Xinhao, Zupan, Jure, and Zupanic, Erik

Subjects

Astrophysics - Instrumentation and Methods for Astrophysics, General Relativity and Quantum Cosmology, High Energy Physics - Experiment, High Energy Physics - Phenomenology, Physics - Atomic Physics

Abstract

We summarize the discussions at a virtual Community Workshop on Cold Atoms in Space concerning the status of cold atom technologies, the prospective scientific and societal opportunities offered by their deployment in space, and the developments needed before cold atoms could be operated in space. The cold atom technologies discussed include atomic clocks, quantum gravimeters and accelerometers, and atom interferometers. Prospective applications include metrology, geodesy and measurement of terrestrial mass change due to, e.g., climate change, and fundamental science experiments such as tests of the equivalence principle, searches for dark matter, measurements of gravitational waves and tests of quantum mechanics. We review the current status of cold atom technologies and outline the requirements for their space qualification, including the development paths and the corresponding technical milestones, and identifying possible pathfinder missions to pave the way for missions to exploit the full potential of cold atoms in space. Finally, we present a first draft of a possible road-map for achieving these goals, that we propose for discussion by the interested cold atom, Earth Observation, fundamental physics and other prospective scientific user communities, together with ESA and national space and research funding agencies., Comment: Summary of the Community Workshop on Cold Atoms in Space and corresponding Road-map: https://indico.cern.ch/event/1064855/

Published

2022

12. Solving correlation clustering with QAOA and a Rydberg qudit system: a full-stack approach

Author

Weggemans, Jordi R., Urech, Alexander, Rausch, Alexander, Spreeuw, Robert, Boucherie, Richard, Schreck, Florian, Schoutens, Kareljan, Minář, Jiří, and Speelman, Florian

Subjects

Quantum Physics, Condensed Matter - Quantum Gases, Physics - Atomic Physics

Abstract

We study the correlation clustering problem using the quantum approximate optimization algorithm (QAOA) and qudits, which constitute a natural platform for such non-binary problems. Specifically, we consider a neutral atom quantum computer and propose a full stack approach for correlation clustering, including Hamiltonian formulation of the algorithm, analysis of its performance, identification of a suitable level structure for ${}^{87}{\rm Sr}$ and specific gate design. We show the qudit implementation is superior to the qubit encoding as quantified by the gate count. For single layer QAOA, we also prove (conjecture) a lower bound of $0.6367$ ($0.6699$) for the approximation ratio on 3-regular graphs. Our numerical studies evaluate the algorithm's performance by considering complete and Erd\H{o}s-R\'enyi graphs of up to 7 vertices and clusters. We find that in all cases the QAOA surpasses the Swamy bound $0.7666$ for the approximation ratio for QAOA depths $p \geq 2$. Finally, by analysing the effect of errors when solving complete graphs we find that their inclusion severely limits the algorithm's performance., Comment: 30+12 pages, 14 figures, accepted into Quantum

Published

2021

13. A steady-state magneto-optical trap of fermionic strontium on a narrow-line transition

Author

Escudero, Rodrigo González, Chen, Chun-Chia, Bennetts, Shayne, Pasquiou, Benjamin, and Schreck, Florian

Subjects

Physics - Atomic Physics

Abstract

A steady-state magneto-optical trap (MOT) of fermionic strontium atoms operating on the 7.5 kHz-wide ${^1\mathrm{S}_0} - {^3\mathrm{P}_1}$ transition is demonstrated. This MOT features $8.4 \times 10^{7}$ atoms, a loading rate of $1.3\times 10^{7}$atoms/s, and an average temperature of 12 $\mu$K. These parameters make it well suited to serve as a source of atoms for continuous-wave superradiant lasers operating on strontium's mHz-wide clock transition. Such lasers have only been demonstrated using pulsed Sr sources, limiting their range of applications. Our MOT makes an important step toward continuous operation of these devices, paving the way for continuous-wave active optical clocks., Comment: 11 pages, 7 figures

Published

2021

14. State selective cooling of $\mathrm{SU}(N)$ Fermi-gases

Author

Müller, Aaron Merlin, Lajkó, Miklós, Schreck, Florian, Mila, Frédéric, and Minář, Jiří

Subjects

Condensed Matter - Quantum Gases, Condensed Matter - Strongly Correlated Electrons, Quantum Physics

Abstract

We investigate a species selective cooling process of a trapped $\mathrm{SU}(N)$ Fermi gas using entropy redistribution during adiabatic loading of an optical lattice. Using high-temperature expansion of the Hubbard model, we show that when a subset $N_A < N$ of the single-atom levels experiences a stronger trapping potential in a certain region of space, the dimple, it leads to improvement in cooling as compared to a $\mathrm{SU}(N_A)$ Fermi gas only. We show that optimal performance is achieved when all atomic levels experience the same potential outside the dimple and we quantify the cooling for various $N_A$ by evaluating the dependence of the final entropy densities and temperatures as functions of the initial entropy. Furthermore, considering ${}^{87}{\rm Sr}$ and ${}^{173}{\rm Yb}$ for specificity, we provide a quantitative discussion of how the state selective trapping can be achieved with readily available experimental techniques., Comment: 8+3 pages, 4+1 figures

Published

2021

15. Continuous Bose-Einstein condensation

Author

Chen, Chun-Chia, Escudero, Rodrigo González, Minář, Jiří, Pasquiou, Benjamin, Bennetts, Shayne, and Schreck, Florian

Subjects

Condensed Matter - Quantum Gases, Physics - Atomic Physics

Abstract

Bose-Einstein condensates (BECs) are macroscopic coherent matter waves that have revolutionized quantum science and atomic physics. They are essential to quantum simulation and sensing, for example underlying atom interferometers in space and ambitious tests of Einstein's equivalence principle. The key to dramatically increasing the bandwidth and precision of such matter-wave sensors lies in sustaining a coherent matter wave indefinitely. Here we demonstrate continuous Bose-Einstein condensation by creating a continuous-wave (CW) condensate of strontium atoms that lasts indefinitely. The coherent matter wave is sustained by amplification through Bose-stimulated gain of atoms from a thermal bath. By steadily replenishing this bath while achieving 1000x higher phase-space densities than previous works, we maintain the conditions for condensation. This advance overcomes a fundamental limitation of all atomic quantum gas experiments to date: the need to execute several cooling stages time-sequentially. Continuous matter-wave amplification will make possible CW atom lasers, atomic counterparts of CW optical lasers that have become ubiquitous in technology and society. The coherence of such atom lasers will no longer be fundamentally limited by the atom number in a BEC and can ultimately reach the standard quantum limit. Our development provides a new, hitherto missing piece of atom optics, enabling the construction of continuous coherent matter-wave devices. From infrasound gravitational wave detectors to optical clocks, the dramatic improvement in coherence, bandwidth and precision now within reach will be decisive in the creation of a new class of quantum sensors., Comment: 17 pages, 10 figures

Published

2020

16. Continuous guided strontium beam with high phase-space density

Author

Chen, Chun-Chia, Bennetts, Shayne, Escudero, Rodrigo González, Pasquiou, Benjamin, and Schreck, Florian

Subjects

Physics - Atomic Physics, Quantum Physics

Abstract

A continuous guided atomic beam of $^{88}\mathrm{Sr}$ with a phase-space density exceeding $10^{-4}$ in the moving frame and a flux of $3 \times 10^{7} \, \mathrm{at \, s^{-1}}$ is demonstrated. This phase-space density is around three orders of magnitude higher than previously reported for steady-state atomic beams. We detail the architecture necessary to produce this ultracold atom source and characterize its output after $\sim 4 \, \mathrm{cm}$ of propagation. With radial temperatures of less than $1 \,\mu \mathrm{K}$ and a velocity of $8.4 \, \mathrm{cm \, s^{-1}}$ this source is ideal for a range of applications. For example, it could be used to replenish the gain medium of an active optical superradiant clock or be employed to overcome the Dick effect that can limit the performance of pulsed-mode atom interferometers, atomic clocks and ultracold atom based sensors in general. Finally, this result represents a significant step towards the development of a steady-state atom laser., Comment: 9 pages, 4 figures

Published

2019

17. Microscope objective for imaging atomic strontium with 0.63 micrometer resolution

Author

Knottnerus, Ivo, Pyatchenkov, Sergey, Onishchenko, Oleksiy, Urech, Alexander, Siviloglou, Georgios A., and Schreck, Florian

Subjects

Physics - Instrumentation and Detectors, Physics - Optics

Abstract

Imaging and manipulating individual atoms with submicrometer separation can be instrumental for quantum simulation of condensed matter Hamiltonians and quantum computation with neutral atoms. Quantum gas microscope experiments in most cases rely on quite costly solutions. Here we present an open-source design of a microscope objective for atomic strontium consisting solely of off-the-shelf lenses that is diffraction-limited for 461${\,}$nm light. A prototype built with a simple stacking design is measured to have a resolution of 0.63(4)${\,\mu}$m, which is in agreement with the predicted value. This performance, together with the near diffraction-limited performance for 532${\,}$nm light makes this design useful for both quantum gas microscopes and optical tweezer experiments with strontium. Our microscope can easily be adapted to experiments with other atomic species such as erbium, ytterbium, and dysprosium, as well as Rydberg experiments with rubidium.

Published

2019

18. Chapter Six - The path to continuous Bose-Einstein condensation

Author

Chen, Chun-Chia, Bennetts, Shayne, and Schreck, Florian

Published

2023

19. The frequency of the ultranarrow ${^1\text{S}_0} - {^3\text{P}_2}$ transition in $^{87}\text{Sr}$

Author

Onishchenko, Oleksiy, Pyatchenkov, Sergey, Urech, Alexander, Chen, Chun-Chia, Bennetts, Shayne, Siviloglou, Georgios A., and Schreck, Florian

Subjects

Physics - Atomic Physics, Condensed Matter - Quantum Gases

Abstract

We determine the frequency of the ultranarrow $^{87}\text{Sr}$ ${^{1}\text{S}_{0}} - {^{3}\text{P}_{2}}$ transition by spectroscopy of an ultracold gas. This transition is referenced to four molecular iodine lines that are observed by Doppler-free saturation spectroscopy of hot iodine vapor. The frequency differences between the Sr and the I$_2$ transitions are measured with an uncertainty of 250 kHz. The absolute frequency of the $^{87}\text{Sr}$ ${^{1}\text{S}_{0}} - {^{3}\text{P}_{2}}$ ($\text{F}'=7/2$) transition is 446648775(30) MHz and limited in accuracy by the iodine reference. This work prepares the use of the Sr ${^{1}\text{S}_{0}} - {^{3}\text{P}_{2}}$ transition for quantum simulation and computation., Comment: 8 pages, 6 figures

Published

2018

20. Visualising the connection between edge states and the mobility edge in adiabatic and non-adiabatic topological charge transport

Author

Lizunova, Mariya A., Schreck, Florian, Smith, Cristiane Morais, and van Wezel, Jasper

Subjects

Condensed Matter - Strongly Correlated Electrons

Abstract

The ability to pump quantised amounts of charge is one of the hallmarks of topological materials. An archetypical example is Laughlin's gauge argument for transporting an integer number of electrons between the edges of a quantum Hall cylinder upon insertion of a magnetic flux quantum. This is mathematically equivalent to the equally famous suggestion of Thouless' that an integer number of electrons are pumped between two ends of a one-dimensional quantum wire upon sliding a charge-density wave over a single wave length. We use the correspondence between these descriptions to visualise the detailed dynamics of the electron flow during a single pumping cycle, which is difficult to do directly in the quantum Hall setup, because of the gauge freedom inherent to its description. We find a close correspondence between topological edge states and the mobility edges in charge-density wave, quantum Hall, and other topological systems. We illustrate this connection by describing an alternative, non-adiabatic mode of topological transport that displaces precisely the opposite amount of charge as compared to the adiabatic pump. We discuss possible experimental realisations in the context of ultracold atoms and photonic waveguide experiments., Comment: Final version

Published

2018

21. Sisyphus Optical Lattice Decelerator

Author

Chen, Chun-Chia, Bennetts, Shayne, Escudero, Rodrigo González, Schreck, Florian, and Pasquiou, Benjamin

Subjects

Physics - Atomic Physics, Condensed Matter - Quantum Gases, Quantum Physics

Abstract

We experimentally demonstrate a variation on a Sisyphus cooling technique that was proposed for cooling antihydrogen. In our implementation, atoms are selectively excited to an electronic state whose energy is spatially modulated by an optical lattice, and the ensuing spontaneous decay completes one Sisyphus cooling cycle. We characterize the cooling efficiency of this technique on a continuous beam of Sr, and compare it with radiation pressure based laser cooling. We demonstrate that this technique provides similar atom number for lower end temperatures, provides additional cooling per scattering event and is compatible with other laser cooling methods. This method can be instrumental in bringing new exotic species and molecules to the ultracold regime., Comment: 11 pages, 11 figures

Published

2018

22. The RbSr $^2\Sigma^+$ ground state investigated via spectroscopy of hot & ultracold molecules

Author

Ciamei, Alessio, Szczepkowski, Jacek, Bayerle, Alex, Barbé, Vincent, Reichsöllner, Lukas, Tzanova, Slava M., Chen, Chun-Chia, Pasquiou, Benjamin, Grochola, Anna, Kowalczyk, Pawel, Jastrzebski, Wlodzimierz, and Schreck, Florian

Subjects

Physics - Atomic Physics, Physics - Chemical Physics

Abstract

We report on spectroscopic studies of hot and ultracold RbSr molecules, and combine the results in an analysis that allows us to fit a potential energy curve (PEC) for the X(1)$^2\Sigma^+$ ground state bridging the short-to-long-range domains. The ultracold RbSr molecules are created in a $\mu$K sample of Rb and Sr atoms and probed by two-colour photoassociation spectroscopy. The data yield the long-range dispersion coefficients $C_6$ and $C_8$, along with the total number of supported bound levels. The hot RbSr molecules are created in a $1000 \,$K gas mixture of Rb and Sr in a heat-pipe oven and probed by thermoluminescence and laser-induced fluorescence spectroscopy. We compare the hot molecule data with spectra we simulated using previously published PECs determined by three different ab-initio theoretical methods. We identify several band heads corresponding to radiative decay from the B(2)$^2\Sigma^+$ state to the deepest bound levels of X(1)$^2\Sigma^+$. We determine a mass-scaled high-precision model for X(1)$^2\Sigma^+$ by fitting all data using a single fit procedure. The corresponding PEC is consistent with all data, thus spanning short-to-long internuclear distances and bridging an energy gap of about 75% of the potential well depth, still uncharted by any experiment. We benchmark ab-initio PECs against our results, and give the PEC fit parameters for both X(1)$^2\Sigma^+$ and B(2)$^2\Sigma^+$ states. As first outcomes of our analysis, we calculate the $s$-wave scattering properties for all stable isotopic combinations and corroborate the locations of Fano-Feshbach resonances between alkali Rb and closed-shell Sr atoms recently observed [Barb\'e et al., Nat. Phys., 2018, DOI:10.1038/s41567-018-0169-x]. These results should greatly contribute to the generation of ultracold alkali$-$alkaline-earth dimers, whose applications range from quantum simulation to quantum chemistry., Comment: 24 pages, 13 figures, 10 tables

Published

2018

23. The path to continuous Bose-Einstein condensation

Author

Chen, Chun-Chia, primary, Bennetts, Shayne, additional, and Schreck, Florian, additional

Published

2023

24. Observation of Feshbach resonances between alkali and closed-shell atoms

Author

Barbé, Vincent, Ciamei, Alessio, Pasquiou, Benjamin, Reichsöllner, Lukas, Schreck, Florian, Żuchowski, Piotr S., and Hutson, Jeremy M.

Subjects

Physics - Atomic Physics, Condensed Matter - Quantum Gases

Abstract

Magnetic Feshbach resonances are an invaluable tool for controlling ultracold atoms and molecules. They can be used to tune atomic interactions and have been used extensively to explore few- and many-body phenomena. They can also be used for magnetoassociation, in which pairs of atoms are converted into molecules by ramping an applied magnetic field across a resonance. Pairs of open-shell atoms, such as the alkalis, chromium, and some lanthanides, exhibit broad resonances because the corresponding molecule has multiple electronic states. However, molecules formed between alkali and closed-shell atoms have only one electronic state and no broad resonances. Narrow resonances have been predicted in such systems, but until now have eluded observation. Here we present the first observation of magnetic Feshbach resonances in a system containing a closed-shell atom, Sr, interacting with an alkali atom, Rb. These resonances pave the way to creating an ultracold gas of strongly polar, open-shell molecules, which will open up new possibilities for designing quantum many-body systems and for tests of fundamental symmetries., Comment: 5 pages, 3 figures, 2 tables

Published

2017

25. Observation of Bose-enhanced photoassociation products

Author

Ciamei, Alessio, Bayerle, Alex, Pasquiou, Benjamin, and Schreck, Florian

Subjects

Condensed Matter - Quantum Gases, Physics - Atomic Physics

Abstract

We produce ${^{84}\mathrm{Sr}_2}$ molecules using Bose-enhanced Raman photoassociation. We apply the stimulated Raman adiabatic passage (STIRAP) technique on a Bose-Einstein condensate (BEC) to produce more than $8 \times 10^3$ ultracold molecules. This chemical reaction is only made possible because of the Bose enhancement of the optical transition dipole moment between the initial atomic state and an intermediate molecular state. We study the effect of Bose enhancement by measuring the transition Rabi frequency in a BEC and by comparing it with measurements for two atoms in sites of a Mott insulator. By breaking the dimers' bond and directly observing the separated atoms, we measure the molecular inelastic collision rate parameters. We discuss the possibility of applying Bose-enhanced STIRAP to convert a BEC of atoms into a BEC of molecules, and argue that the required efficiency for STIRAP is within experimental reach., Comment: 8 pages, 4 figures, 1 table

Published

2017

26. A steady-state magneto-optical trap with 100 fold improved phase-space density

Author

Bennetts, Shayne, Chen, Chun-Chia, Pasquiou, Benjamin, and Schreck, Florian

Subjects

Physics - Atomic Physics, Condensed Matter - Quantum Gases

Abstract

We demonstrate a continuously loaded $^{88}\mathrm{Sr}$ magneto-optical trap (MOT) with a steady-state phase-space density of $1.3(2) \times 10^{-3}$. This is two orders of magnitude higher than reported in previous steady-state MOTs. Our approach is to flow atoms through a series of spatially separated laser cooling stages before capturing them in a MOT operated on the 7.4-kHz linewidth Sr intercombination line using a hybrid slower+MOT configuration. We also demonstrate producing a Bose-Einstein condensate at the MOT location, despite the presence of laser cooling light on resonance with the 30-MHz linewidth transition used to initially slow atoms in a separate chamber. Our steady-state high phase-space density MOT is an excellent starting point for a continuous atom laser and dead-time free atom interferometers or clocks., Comment: 11 pages, 5 figures

Published

2017

27. Efficient production of long-lived ultracold Sr$_2$ molecules

Author

Ciamei, Alessio, Bayerle, Alex, Chen, Chun-Chia, Pasquiou, Benjamin, and Schreck, Florian

Subjects

Condensed Matter - Quantum Gases, Physics - Atomic Physics

Abstract

We associate Sr atom pairs on sites of a Mott insulator optically and coherently into weakly-bound ground-state molecules, achieving an efficiency above 80\%. This efficiency is 2.5 times higher than in our previous work [S. Stellmer, B. Pasquiou, R. Grimm, and F. Schreck, Phys. Rev. Lett. 109, 115302 (2012)] and obtained through two improvements. First, the lifetime of the molecules is increased beyond one minute by using an optical lattice wavelength that is further detuned from molecular transitions. Second, we compensate undesired dynamic light shifts that occur during the stimulated Raman adiabatic passage (STIRAP) used for molecule association. We also characterize and model STIRAP, providing insights into its limitations. Our work shows that significant molecule association efficiencies can be achieved even for atomic species or mixtures that lack Feshbach resonances suitable for magnetoassociation., Comment: 16 pages, 13 figures, 2 tables; new reference added in introduction, corrected typos and improved reference Bibtex items

Published

2017

28. The potential and global outlook of integrated photonics for quantum technologies

Author

Pelucchi, Emanuele, Fagas, Giorgos, Aharonovich, Igor, Englund, Dirk, Figueroa, Eden, Gong, Qihuang, Hannes, Hübel, Liu, Jin, Lu, Chao-Yang, Matsuda, Nobuyuki, Pan, Jian-Wei, Schreck, Florian, Sciarrino, Fabio, Silberhorn, Christine, Wang, Jianwei, and Jöns, Klaus D.

Published

2022

29. Terrestrial very-long-baseline atom interferometry: Workshop summary

Author

Abend, Sven, primary, Allard, Baptiste, additional, Alonso, Iván, additional, Antoniadis, John, additional, Araújo, Henrique, additional, Arduini, Gianluigi, additional, Arnold, Aidan S., additional, Asano, Tobias, additional, Augst, Nadja, additional, Badurina, Leonardo, additional, Balaž, Antun, additional, Banks, Hannah, additional, Barone, Michele, additional, Barsanti, Michele, additional, Bassi, Angelo, additional, Battelier, Baptiste, additional, Baynham, Charles F. A., additional, Beaufils, Quentin, additional, Belić, Aleksandar, additional, Beniwal, Ankit, additional, Bernabeu, Jose, additional, Bertinelli, Francesco, additional, Bertoldi, Andrea, additional, Biswas, Ikbal Ahamed, additional, Blas, Diego, additional, Boegel, Patrick, additional, Bogojević, Aleksandar, additional, Böhm, Jonas, additional, Böhringer, Samuel, additional, Bongs, Kai, additional, Bouyer, Philippe, additional, Brand, Christian, additional, Brimis, Apostolos, additional, Buchmueller, Oliver, additional, Cacciapuoti, Luigi, additional, Calatroni, Sergio, additional, Canuel, Benjamin, additional, Caprini, Chiara, additional, Caramete, Ana, additional, Caramete, Laurentiu, additional, Carlesso, Matteo, additional, Carlton, John, additional, Casariego, Mateo, additional, Charmandaris, Vassilis, additional, Chen, Yu-Ao, additional, Chiofalo, Maria Luisa, additional, Cimbri, Alessia, additional, Coleman, Jonathon, additional, Constantin, Florin Lucian, additional, Contaldi, Carlo R., additional, Cui, Yanou, additional, Ros, Elisa Da, additional, Davies, Gavin, additional, Rosendo, Esther del Pino, additional, Deppner, Christian, additional, Derevianko, Andrei, additional, Rham, Claudia de, additional, Roeck, Albert De, additional, Derr, Daniel, additional, Di Pumpo, Fabio, additional, Djordjevic, Goran S., additional, Döbrich, Babette, additional, Domokos, Peter, additional, Dornan, Peter, additional, Doser, Michael, additional, Drougakis, Giannis, additional, Dunningham, Jacob, additional, Duspayev, Alisher, additional, Easo, Sajan, additional, Eby, Joshua, additional, Efremov, Maxim, additional, Ekelof, Tord, additional, Elertas, Gedminas, additional, Ellis, John, additional, Evans, David, additional, Fadeev, Pavel, additional, Fanì, Mattia, additional, Fassi, Farida, additional, Fattori, Marco, additional, Fayet, Pierre, additional, Felea, Daniel, additional, Feng, Jie, additional, Friedrich, Alexander, additional, Fuchs, Elina, additional, Gaaloul, Naceur, additional, Gao, Dongfeng, additional, Gardner, Susan, additional, Garraway, Barry, additional, Gauguet, Alexandre, additional, Gerlach, Sandra, additional, Gersemann, Matthias, additional, Gibson, Valerie, additional, Giese, Enno, additional, Giudice, Gian F., additional, Glasbrenner, Eric P., additional, Gündoğan, Mustafa, additional, Haehnelt, Martin, additional, Hakulinen, Timo, additional, Hammerer, Klemens, additional, Hanımeli, Ekim T., additional, Harte, Tiffany, additional, Hawkins, Leonie, additional, Hees, Aurelien, additional, Heise, Jaret, additional, Henderson, Victoria A., additional, Herrmann, Sven, additional, Hird, Thomas M., additional, Hogan, Jason M., additional, Holst, Bodil, additional, Holynski, Michael, additional, Hussain, Kamran, additional, Janson, Gregor, additional, Jeglič, Peter, additional, Jelezko, Fedor, additional, Kagan, Michael, additional, Kalliokoski, Matti, additional, Kasevich, Mark, additional, Kehagias, Alex, additional, Kilian, Eva, additional, Koley, Soumen, additional, Konrad, Bernd, additional, Kopp, Joachim, additional, Kornakov, Georgy, additional, Kovachy, Tim, additional, Krutzik, Markus, additional, Kumar, Mukesh, additional, Kumar, Pradeep, additional, Lämmerzahl, Claus, additional, Landsberg, Greg, additional, Langlois, Mehdi, additional, Lanigan, Bryony, additional, Lellouch, Samuel, additional, Leone, Bruno, additional, Poncin-Lafitte, Christophe Le, additional, Lewicki, Marek, additional, Leykauf, Bastian, additional, Lezeik, Ali, additional, Lombriser, Lucas, additional, Luis Lopez-Gonzalez, J., additional, Lopez Asamar, Elias, additional, Monjaraz, Cristian López, additional, Luciano, Giuseppe Gaetano, additional, Mahmoud, M. A., additional, Maleknejad, Azadeh, additional, Marteau, Jacques, additional, Massonnet, Didier, additional, Mazumdar, Anupam, additional, McCabe, Christopher, additional, Meister, Matthias, additional, Menu, Jonathan, additional, Messineo, Giuseppe, additional, Micalizio, Salvatore, additional, Millington, Peter, additional, Milosevic, Milan, additional, Mitchell, Jeremiah, additional, Montero, Mario, additional, Morley, Gavin W., additional, Müller, Jürgen, additional, ioğlu, Özgür E. Müstecapl, additional, Ni, Wei-Tou, additional, Noller, Johannes, additional, Odžak, Senad, additional, Oi, Daniel K. L., additional, Omar, Yasser, additional, Pahl, Julia, additional, Paling, Sean, additional, Pandey, Saurabh, additional, Pappas, George, additional, Pareek, Vinay, additional, Pasatembou, Elizabeth, additional, Pelucchi, Emanuele, additional, Pereira dos Santos, Franck, additional, Piest, Baptist, additional, Pikovski, Igor, additional, Pilaftsis, Apostolos, additional, Plunkett, Robert, additional, Poggiani, Rosa, additional, Prevedelli, Marco, additional, Puputti, Julia, additional, Veettil, Vishnupriya Puthiya, additional, Quenby, John, additional, Rafelski, Johann, additional, Rajendran, Surjeet, additional, Rasel, Ernst M., additional, Sfar, Haifa Rejeb, additional, Reynaud, Serge, additional, Richaud, Andrea, additional, Rodzinka, Tangui, additional, Roura, Albert, additional, Rudolph, Jan, additional, Sabulsky, Dylan O., additional, Safronova, Marianna S., additional, Santamaria, Luigi, additional, Schilling, Manuel, additional, Schkolnik, Vladimir, additional, Schleich, Wolfgang P., additional, Schlippert, Dennis, additional, Schneider, Ulrich, additional, Schreck, Florian, additional, Schubert, Christian, additional, Schwersenz, Nico, additional, Semakin, Aleksei, additional, Sergijenko, Olga, additional, Shao, Lijing, additional, Shipsey, Ian, additional, Singh, Rajeev, additional, Smerzi, Augusto, additional, Sopuerta, Carlos F., additional, Spallicci, Alessandro D. A. M., additional, Stefanescu, Petruta, additional, Stergioulas, Nikolaos, additional, Ströhle, Jannik, additional, Struckmann, Christian, additional, Tentindo, Silvia, additional, Throssell, Henry, additional, Tino, Guglielmo M., additional, Tinsley, Jonathan N., additional, Tintareanu Mircea, Ovidiu, additional, Tkalčec, Kimberly, additional, Tolley, Andrew. J., additional, Tornatore, Vincenza, additional, Torres-Orjuela, Alejandro, additional, Treutlein, Philipp, additional, Trombettoni, Andrea, additional, Tsai, Yu-Dai, additional, Ufrecht, Christian, additional, Ulmer, Stefan, additional, Valuch, Daniel, additional, Vaskonen, Ville, additional, Vázquez-Aceves, Verónica, additional, Vitanov, Nikolay V., additional, Vogt, Christian, additional, Klitzing, Wolf von, additional, Vukics, András, additional, Walser, Reinhold, additional, Wang, Jin, additional, Warburton, Niels, additional, Webber-Date, Alexander, additional, Wenzlawski, André, additional, Werner, Michael, additional, Williams, Jason, additional, Windpassinger, Patrick, additional, Wolf, Peter, additional, Woerner, Lisa, additional, Xuereb, André, additional, Yahia, Mohamed E., additional, Cruzeiro, Emmanuel Zambrini, additional, Zarei, Moslem, additional, Zhan, Mingsheng, additional, Zhou, Lin, additional, Zupan, Jure, additional, and Zupanič, Erik, additional

Published

2024

30. Reservoir spectroscopy of 5s5p $^3$P$_2$ - 5s$n$d $^3$D$_{1,2,3}$ transitions in strontium

Author

Stellmer, Simon and Schreck, Florian

Subjects

Physics - Atomic Physics, Condensed Matter - Quantum Gases

Abstract

We perform spectroscopy on the optical dipole transitions 5s5p $^3$P$_2$ - 5s$n$d $^3$D$_{1,2,3}$, $n \in (5,6)$, for all stable isotopes of atomic strontium. We develop a new spectroscopy scheme, in which atoms in the metastable $^3$P$_2$ state are stored in a reservoir before being probed. The method presented here increases the attained precision and accuracy by two orders of magnitude compared to similar experiments performed in a magneto-optical trap or discharge. We show how the state distribution and velocity spread of atoms in the reservoir can be tailored to increase the spectroscopy performance. The absolute transition frequencies are measured with an accuracy of 2 MHz. The isotope shifts are given to within 200 kHz. We calculate the $A$ and $Q$ parameters for the hyperfine structure of the fermionic isotope at the MHz-level. Furthermore, we investigate the branching ratios of the $^3$D$_{J}$ states into the $^3$P$_{J}$ states and discuss immediate implications on schemes of optical pumping and fluorescence detection., Comment: 15 pages, 7 figures, 4 tables

Published

2014

31. Terrestrial very-long-baseline atom interferometry: Workshop summary

Author

Abend, Sven, Allard, Baptiste, Alonso, Iván, Antoniadis, John, Araújo, Henrique, Arduini, Gianluigi, Arnold, Aidan S., Asano, Tobias, Augst, Nadja, Badurina, Leonardo, Balaž, Antun, Banks, Hannah, Barone, Michele, Barsanti, Michele, Bassi, Angelo, Battelier, Baptiste, Baynham, Charles F. A., Beaufils, Quentin, Belić, Aleksandar, Beniwal, Ankit, Bernabeu, Jose, Bertinelli, Francesco, Bertoldi, Andrea, Biswas, Ikbal Ahamed, Blas, Diego, Boegel, Patrick, Bogojević, Aleksandar, Böhm, Jonas, Böhringer, Samuel, Bongs, Kai, Bouyer, Philippe, Brand, Christian, Brimis, Apostolos, Buchmueller, Oliver, Cacciapuoti, Luigi, Calatroni, Sergio, Canuel, Benjamin, Caprini, Chiara, Caramete, Ana, Caramete, Laurentiu, Carlesso, Matteo, Carlton, John, Casariego, Mateo, Charmandaris, Vassilis, Chen, Yu-Ao, Chiofalo, Maria Luisa, Cimbri, Alessia, Coleman, Jonathon, Constantin, Florin Lucian, Contaldi, Carlo R., Cui, Yanou, Ros, Elisa Da, Davies, Gavin, Rosendo, Esther del Pino, Deppner, Christian, Derevianko, Andrei, Rham, Claudia de, Roeck, Albert De, Derr, Daniel, Di Pumpo, Fabio, Djordjevic, Goran S., Döbrich, Babette, Domokos, Peter, Dornan, Peter, Doser, Michael, Drougakis, Giannis, Dunningham, Jacob, Duspayev, Alisher, Easo, Sajan, Eby, Joshua, Efremov, Maxim, Ekelof, Tord, Elertas, Gedminas, Ellis, John, Evans, David, Fadeev, Pavel, Fanì, Mattia, Fassi, Farida, Fattori, Marco, Fayet, Pierre, Felea, Daniel, Feng, Jie, Friedrich, Alexander, Fuchs, Elina, Gaaloul, Naceur, Gao, Dongfeng, Gardner, Susan, Garraway, Barry, Gauguet, Alexandre, Gerlach, Sandra, Gersemann, Matthias, Gibson, Valerie, Giese, Enno, Giudice, Gian F., Glasbrenner, Eric P., Gündoğan, Mustafa, Haehnelt, Martin, Hakulinen, Timo, Hammerer, Klemens, Hanımeli, Ekim T., Harte, Tiffany, Hawkins, Leonie, Hees, Aurelien, Heise, Jaret, Henderson, Victoria A., Herrmann, Sven, Hird, Thomas M., Hogan, Jason M., Holst, Bodil, Holynski, Michael, Hussain, Kamran, Janson, Gregor, Jeglič, Peter, Jelezko, Fedor, Kagan, Michael, Kalliokoski, Matti, Kasevich, Mark, Kehagias, Alex, Kilian, Eva, Koley, Soumen, Konrad, Bernd, Kopp, Joachim, Kornakov, Georgy, Kovachy, Tim, Krutzik, Markus, Kumar, Mukesh, Kumar, Pradeep, Lämmerzahl, Claus, Landsberg, Greg, Langlois, Mehdi, Lanigan, Bryony, Lellouch, Samuel, Leone, Bruno, Poncin-Lafitte, Christophe Le, Lewicki, Marek, Leykauf, Bastian, Lezeik, Ali, Lombriser, Lucas, Luis Lopez-Gonzalez, J., Lopez Asamar, Elias, Monjaraz, Cristian López, Luciano, Giuseppe Gaetano, Mahmoud, M. A., Maleknejad, Azadeh, Marteau, Jacques, Massonnet, Didier, Mazumdar, Anupam, McCabe, Christopher, Meister, Matthias, Menu, Jonathan, Messineo, Giuseppe, Micalizio, Salvatore, Millington, Peter, Milosevic, Milan, Mitchell, Jeremiah, Montero, Mario, Morley, Gavin W., Müller, Jürgen, ioğlu, Özgür E. Müstecapl, Ni, Wei-Tou, Noller, Johannes, Odžak, Senad, Oi, Daniel K. L., Omar, Yasser, Pahl, Julia, Paling, Sean, Pandey, Saurabh, Pappas, George, Pareek, Vinay, Pasatembou, Elizabeth, Pelucchi, Emanuele, Pereira dos Santos, Franck, Piest, Baptist, Pikovski, Igor, Pilaftsis, Apostolos, Plunkett, Robert, Poggiani, Rosa, Prevedelli, Marco, Puputti, Julia, Veettil, Vishnupriya Puthiya, Quenby, John, Rafelski, Johann, Rajendran, Surjeet, Rasel, Ernst M., Sfar, Haifa Rejeb, Reynaud, Serge, Richaud, Andrea, Rodzinka, Tangui, Roura, Albert, Rudolph, Jan, Sabulsky, Dylan O., Safronova, Marianna S., Santamaria, Luigi, Schilling, Manuel, Schkolnik, Vladimir, Schleich, Wolfgang P., Schlippert, Dennis, Schneider, Ulrich, Schreck, Florian, Schubert, Christian, Schwersenz, Nico, Semakin, Aleksei, Sergijenko, Olga, Shao, Lijing, Shipsey, Ian, Singh, Rajeev, Smerzi, Augusto, Sopuerta, Carlos F., Spallicci, Alessandro D. A. M., Stefanescu, Petruta, Stergioulas, Nikolaos, Ströhle, Jannik, Struckmann, Christian, Tentindo, Silvia, Throssell, Henry, Tino, Guglielmo M., Tinsley, Jonathan N., Tintareanu Mircea, Ovidiu, Tkalčec, Kimberly, Tolley, Andrew. J., Tornatore, Vincenza, Torres-Orjuela, Alejandro, Treutlein, Philipp, Trombettoni, Andrea, Tsai, Yu-Dai, Ufrecht, Christian, Ulmer, Stefan, Valuch, Daniel, Vaskonen, Ville, Vázquez-Aceves, Verónica, Vitanov, Nikolay V., Vogt, Christian, Klitzing, Wolf von, Vukics, András, Walser, Reinhold, Wang, Jin, Warburton, Niels, Webber-Date, Alexander, Wenzlawski, André, Werner, Michael, Williams, Jason, Windpassinger, Patrick, Wolf, Peter, Woerner, Lisa, Xuereb, André, Yahia, Mohamed E., Cruzeiro, Emmanuel Zambrini, Zarei, Moslem, Zhan, Mingsheng, Zhou, Lin, Zupan, Jure, Zupanič, Erik, Abend, Sven, Allard, Baptiste, Alonso, Iván, Antoniadis, John, Araújo, Henrique, Arduini, Gianluigi, Arnold, Aidan S., Asano, Tobias, Augst, Nadja, Badurina, Leonardo, Balaž, Antun, Banks, Hannah, Barone, Michele, Barsanti, Michele, Bassi, Angelo, Battelier, Baptiste, Baynham, Charles F. A., Beaufils, Quentin, Belić, Aleksandar, Beniwal, Ankit, Bernabeu, Jose, Bertinelli, Francesco, Bertoldi, Andrea, Biswas, Ikbal Ahamed, Blas, Diego, Boegel, Patrick, Bogojević, Aleksandar, Böhm, Jonas, Böhringer, Samuel, Bongs, Kai, Bouyer, Philippe, Brand, Christian, Brimis, Apostolos, Buchmueller, Oliver, Cacciapuoti, Luigi, Calatroni, Sergio, Canuel, Benjamin, Caprini, Chiara, Caramete, Ana, Caramete, Laurentiu, Carlesso, Matteo, Carlton, John, Casariego, Mateo, Charmandaris, Vassilis, Chen, Yu-Ao, Chiofalo, Maria Luisa, Cimbri, Alessia, Coleman, Jonathon, Constantin, Florin Lucian, Contaldi, Carlo R., Cui, Yanou, Ros, Elisa Da, Davies, Gavin, Rosendo, Esther del Pino, Deppner, Christian, Derevianko, Andrei, Rham, Claudia de, Roeck, Albert De, Derr, Daniel, Di Pumpo, Fabio, Djordjevic, Goran S., Döbrich, Babette, Domokos, Peter, Dornan, Peter, Doser, Michael, Drougakis, Giannis, Dunningham, Jacob, Duspayev, Alisher, Easo, Sajan, Eby, Joshua, Efremov, Maxim, Ekelof, Tord, Elertas, Gedminas, Ellis, John, Evans, David, Fadeev, Pavel, Fanì, Mattia, Fassi, Farida, Fattori, Marco, Fayet, Pierre, Felea, Daniel, Feng, Jie, Friedrich, Alexander, Fuchs, Elina, Gaaloul, Naceur, Gao, Dongfeng, Gardner, Susan, Garraway, Barry, Gauguet, Alexandre, Gerlach, Sandra, Gersemann, Matthias, Gibson, Valerie, Giese, Enno, Giudice, Gian F., Glasbrenner, Eric P., Gündoğan, Mustafa, Haehnelt, Martin, Hakulinen, Timo, Hammerer, Klemens, Hanımeli, Ekim T., Harte, Tiffany, Hawkins, Leonie, Hees, Aurelien, Heise, Jaret, Henderson, Victoria A., Herrmann, Sven, Hird, Thomas M., Hogan, Jason M., Holst, Bodil, Holynski, Michael, Hussain, Kamran, Janson, Gregor, Jeglič, Peter, Jelezko, Fedor, Kagan, Michael, Kalliokoski, Matti, Kasevich, Mark, Kehagias, Alex, Kilian, Eva, Koley, Soumen, Konrad, Bernd, Kopp, Joachim, Kornakov, Georgy, Kovachy, Tim, Krutzik, Markus, Kumar, Mukesh, Kumar, Pradeep, Lämmerzahl, Claus, Landsberg, Greg, Langlois, Mehdi, Lanigan, Bryony, Lellouch, Samuel, Leone, Bruno, Poncin-Lafitte, Christophe Le, Lewicki, Marek, Leykauf, Bastian, Lezeik, Ali, Lombriser, Lucas, Luis Lopez-Gonzalez, J., Lopez Asamar, Elias, Monjaraz, Cristian López, Luciano, Giuseppe Gaetano, Mahmoud, M. A., Maleknejad, Azadeh, Marteau, Jacques, Massonnet, Didier, Mazumdar, Anupam, McCabe, Christopher, Meister, Matthias, Menu, Jonathan, Messineo, Giuseppe, Micalizio, Salvatore, Millington, Peter, Milosevic, Milan, Mitchell, Jeremiah, Montero, Mario, Morley, Gavin W., Müller, Jürgen, ioğlu, Özgür E. Müstecapl, Ni, Wei-Tou, Noller, Johannes, Odžak, Senad, Oi, Daniel K. L., Omar, Yasser, Pahl, Julia, Paling, Sean, Pandey, Saurabh, Pappas, George, Pareek, Vinay, Pasatembou, Elizabeth, Pelucchi, Emanuele, Pereira dos Santos, Franck, Piest, Baptist, Pikovski, Igor, Pilaftsis, Apostolos, Plunkett, Robert, Poggiani, Rosa, Prevedelli, Marco, Puputti, Julia, Veettil, Vishnupriya Puthiya, Quenby, John, Rafelski, Johann, Rajendran, Surjeet, Rasel, Ernst M., Sfar, Haifa Rejeb, Reynaud, Serge, Richaud, Andrea, Rodzinka, Tangui, Roura, Albert, Rudolph, Jan, Sabulsky, Dylan O., Safronova, Marianna S., Santamaria, Luigi, Schilling, Manuel, Schkolnik, Vladimir, Schleich, Wolfgang P., Schlippert, Dennis, Schneider, Ulrich, Schreck, Florian, Schubert, Christian, Schwersenz, Nico, Semakin, Aleksei, Sergijenko, Olga, Shao, Lijing, Shipsey, Ian, Singh, Rajeev, Smerzi, Augusto, Sopuerta, Carlos F., Spallicci, Alessandro D. A. M., Stefanescu, Petruta, Stergioulas, Nikolaos, Ströhle, Jannik, Struckmann, Christian, Tentindo, Silvia, Throssell, Henry, Tino, Guglielmo M., Tinsley, Jonathan N., Tintareanu Mircea, Ovidiu, Tkalčec, Kimberly, Tolley, Andrew. J., Tornatore, Vincenza, Torres-Orjuela, Alejandro, Treutlein, Philipp, Trombettoni, Andrea, Tsai, Yu-Dai, Ufrecht, Christian, Ulmer, Stefan, Valuch, Daniel, Vaskonen, Ville, Vázquez-Aceves, Verónica, Vitanov, Nikolay V., Vogt, Christian, Klitzing, Wolf von, Vukics, András, Walser, Reinhold, Wang, Jin, Warburton, Niels, Webber-Date, Alexander, Wenzlawski, André, Werner, Michael, Williams, Jason, Windpassinger, Patrick, Wolf, Peter, Woerner, Lisa, Xuereb, André, Yahia, Mohamed E., Cruzeiro, Emmanuel Zambrini, Zarei, Moslem, Zhan, Mingsheng, Zhou, Lin, Zupan, Jure, and Zupanič, Erik

Abstract

This document presents a summary of the 2023 Terrestrial Very-Long-Baseline Atom Interferometry Workshop hosted by CERN. The workshop brought together experts from around the world to discuss the exciting developments in large-scale atom interferometer (AI) prototypes and their potential for detecting ultralight dark matter and gravitational waves. The primary objective of the workshop was to lay the groundwork for an international TVLBAI proto-collaboration. This collaboration aims to unite researchers from different institutions to strategize and secure funding for terrestrial large-scale AI projects. The ultimate goal is to create a roadmap detailing the design and technology choices for one or more kilometer--scale detectors, which will be operational in the mid-2030s. The key sections of this report present the physics case and technical challenges, together with a comprehensive overview of the discussions at the workshop together with the main conclusions.

Published

2024

32. Observation of a Strong Atom-Dimer Attraction in a Mass-Imbalanced Fermi-Fermi Mixture

Author

Jag, Michael, Zaccanti, Matteo, Cetina, Marko, Lous, Rianne S., Schreck, Florian, Grimm, Rudolf, Petrov, Dmitry S., and Levinsen, Jesper

Subjects

Condensed Matter - Quantum Gases

Abstract

We investigate a mixture of ultracold fermionic $^{40}$K atoms and weakly bound $^{6}$Li$^{40}$K dimers on the repulsive side of a heteronuclear atomic Feshbach resonance. By radio-frequency spectroscopy we demonstrate that the normally repulsive atom-dimer interaction is turned into a strong attraction. The phenomenon can be understood as a three-body effect in which two heavy $^{40}$K fermions exchange the light $^{6}$Li atom, leading to attraction in odd partial-wave channels (mainly p-wave). Our observations show that mass imbalance in a fermionic system can profoundly change the character of interactions as compared to the well-established mass-balanced case.

Published

2013

33. Degenerate quantum gases of strontium

Author

Stellmer, Simon, Schreck, Florian, and Killian, Thomas C.

Subjects

Condensed Matter - Quantum Gases, Physics - Atomic Physics

Abstract

Degenerate quantum gases of alkaline-earth-like elements open new opportunities in research areas ranging from molecular physics to the study of strongly correlated systems. These experiments exploit the rich electronic structure of these elements, which is markedly different from the one of other species for which quantum degeneracy has been attained. Specifically, alkaline-earth-like atoms, such as strontium, feature metastable triplet states, narrow intercombination lines, and a non-magnetic, closed-shell ground state. This review covers the creation of quantum degenerate gases of strontium and the first experiments performed with this new system. It focuses on laser-cooling and evaporation schemes, which enable the creation of Bose-Einstein condensates and degenerate Fermi gases of all strontium isotopes, and shows how they are used for the investigation of optical Feshbach resonances, the study of degenerate gases loaded into an optical lattice, as well as the coherent creation of Sr_2 molecules., Comment: Review paper, 43 pages, 24 figures, 249 references

Published

2013

34. Quantum degenerate mixtures of strontium and rubidium atoms

Author

Pasquiou, Benjamin, Bayerle, Alex, Tzanova, Slava, Stellmer, Simon, Szczepkowski, Jacek, Parigger, Mark, Grimm, Rudolf, and Schreck, Florian

Subjects

Condensed Matter - Quantum Gases, Physics - Atomic Physics

Abstract

We report on the realization of quantum degenerate gas mixtures of the alkaline-earth element strontium with the alkali element rubidium. A key ingredient of our scheme is sympathetic cooling of Rb by Sr atoms that are continuously laser cooled on a narrow linewidth transition. This versatile technique allows us to produce ultracold gas mixtures with a phase-space density of up to 0.06 for both elements. By further evaporative cooling we create double Bose-Einstein condensates of 87Rb with either 88Sr or 84Sr, reaching more than 10^5 condensed atoms per element for the 84Sr-87Rb mixture. These quantum gas mixtures constitute an important step towards the production of a quantum gas of polar, open-shell RbSr molecules., Comment: 9 pages, 5 figures

Published

2013

35. Laser cooling to quantum degeneracy

Author

Stellmer, Simon, Pasquiou, Benjamin, Grimm, Rudolf, and Schreck, Florian

Subjects

Condensed Matter - Quantum Gases, Physics - Atomic Physics

Abstract

We report on Bose-Einstein condensation (BEC) in a gas of strontium atoms, using laser cooling as the only cooling mechanism. The condensate is formed within a sample that is continuously Doppler cooled to below 1\muK on a narrow-linewidth transition. The critical phase-space density for BEC is reached in a central region of the sample, in which atoms are rendered transparent for laser cooling photons. The density in this region is enhanced by an additional dipole trap potential. Thermal equilibrium between the gas in this central region and the surrounding laser cooled part of the cloud is established by elastic collisions. Condensates of up to 10^5 atoms can be repeatedly formed on a timescale of 100ms, with prospects for the generation of a continuous atom laser., Comment: 18 pages, 13 figures, 3 tables

Published

2013

36. Production of quantum degenerate strontium gases: Larger, better, faster, colder

Author

Stellmer, Simon, Grimm, Rudolf, and Schreck, Florian

Subjects

Condensed Matter - Quantum Gases, Physics - Atomic Physics

Abstract

We report on an improved scheme to generate Bose-Einstein condensates (BECs) and degenerate Fermi gases of strontium. This scheme allows us to create quantum gases with higher atom number, a shorter time of the experimental cycle, or deeper quantum degeneracy than before. We create a BEC of 84-Sr exceeding 10^7 atoms, which is a 30-fold improvement over previously reported experiments. We increase the atom number of 86-Sr BECs to 2.5x10^4 (a fivefold improvement), and refine the generation of attractively interacting 88-Sr BECs. We present a scheme to generate 84-Sr BECs with a cycle time of 2s, which, to the best of our knowledge, is the shortest cycle time of BEC experiments ever reported. We create deeply-degenerate 87-Sr Fermi gases with T/T_F as low as 0.10(1), where the number of populated nuclear spin states can be set to any value between one and ten. Furthermore, we report on a total of five different double-degenerate Bose-Bose and Bose-Fermi mixtures. These studies prepare an excellent starting point for applications of strontium quantum gases anticipated in the near future., Comment: 18 pages, 10 figures, title music by Daft Punk

Published

2012

37. Creation of ultracold Sr2 molecules in the electronic ground state

Author

Stellmer, Simon, Pasquiou, Benjamin, Grimm, Rudolf, and Schreck, Florian

Subjects

Condensed Matter - Quantum Gases, Physics - Atomic Physics

Abstract

We report on the creation of ultracold 84Sr2 molecules in the electronic ground state. The molecules are formed from atom pairs on sites of an optical lattice using stimulated Raman adiabatic passage (STIRAP). We achieve a transfer efficiency of 30% and obtain 4x10^4 molecules with full control over the external and internal quantum state. STIRAP is performed near the narrow 1S0-3P1 intercombination transition, using a vibrational level of the 0u potential as intermediate state. In preparation of our molecule association scheme, we have determined the binding energies of the last vibrational levels of the 0u, 1u excited-state, and the 1\Sigma_g^+ ground-state potentials. Our work overcomes the previous limitation of STIRAP schemes to systems with Feshbach resonances, thereby establishing a route that is applicable to many systems beyond bi-alkalis., Comment: 7 pages, 7 figures, 3 tables

Published

2012

38. Metastability and Coherence of Repulsive Polarons in a Strongly Interacting Fermi Mixture

Author

Kohstall, Christoph, Zaccanti, Matteo, Jag, Michael, Trenkwalder, Andreas, Massignan, Pietro, Bruun, Georg M., Schreck, Florian, and Grimm, Rudolf

Subjects

Condensed Matter - Quantum Gases

Abstract

Ultracold Fermi gases with tuneable interactions represent a unique test bed to explore the many-body physics of strongly interacting quantum systems. In the past decade, experiments have investigated a wealth of intriguing phenomena, and precise measurements of ground-state properties have provided exquisite benchmarks for the development of elaborate theoretical descriptions. Metastable states in Fermi gases with strong repulsive interactions represent an exciting new frontier in the field. The realization of such systems constitutes a major challenge since a strong repulsive interaction in an atomic quantum gas implies the existence of a weakly bound molecular state, which makes the system intrinsically unstable against decay. Here, we exploit radio-frequency spectroscopy to measure the complete excitation spectrum of fermionic 40K impurities resonantly interacting with a Fermi sea of 6Li atoms. In particular, we show that a well-defined quasiparticle exists for strongly repulsive interactions. For this "repulsive polaron" we measure its energy and its lifetime against decay. We also probe its coherence properties by measuring the quasiparticle residue. The results are well described by a theoretical approach that takes into account the finite effective range of the interaction in our system. We find that a non-zero range of the order of the interparticle spacing results in a substantial lifetime increase. This major benefit for the stability of the repulsive branch opens up new perspectives for investigating novel phenomena in metastable, repulsively interacting fermion systems., Comment: 11 pages, 9 figures

Published

2011

39. Detection and manipulation of nuclear spin states in fermionic strontium

Author

Stellmer, Simon, Grimm, Rudolf, and Schreck, Florian

Subjects

Condensed Matter - Quantum Gases

Abstract

Fermionic 87Sr has a nuclear spin of I=9/2, higher than any other element with similar electronic structure. This large nuclear spin has many applications in quantum simulation and computation, for which preparation and detection of the spin state are requirements. For an ultracold 87Sr cloud, we show two complementary methods to characterize the spin-state mixture: optical Stern-Gerlach state separation and state-selective absorption imaging. We use these methods to optimize the preparation of a variety of spin-state mixtures by optical pumping and to measure an upper bound of the 87Sr spin relaxation rate., Comment: 8 pages, 6 figures

Published

2011

40. Bose-Einstein condensation of 86Sr

Author

Stellmer, Simon, Tey, Meng Khoon, Grimm, Rudolf, and Schreck, Florian

Subjects

Condensed Matter - Quantum Gases

Abstract

We report on the attainment of Bose-Einstein condensation of 86Sr. This isotope has a scattering length of about +800 a0 and thus suffers from fast three-body losses. To avoid detrimental atom loss, evaporative cooling is performed at low densities around 3x10^12 cm^-3 in a large volume optical dipole trap. We obtain almost pure condensates of 5x10^3 atoms., Comment: 4 pages, 3 figures

Published

2010

41. Double-degenerate Bose-Fermi mixture of strontium

Author

Tey, Meng Khoon, Stellmer, Simon, Grimm, Rudolf, and Schreck, Florian

Subjects

Condensed Matter - Quantum Gases

Abstract

We report on the attainment of a spin-polarized Fermi sea of 87-Sr in thermal contact with a Bose-Einstein condensate (BEC) of 84-Sr. Interisotope collisions thermalize the fermions with the bosons during evaporative cooling. A degeneracy of T/T_F=0.30(5) is reached with 2x10^4 87-Sr atoms together with an almost pure 84-Sr BEC of 10^5 atoms., Comment: 5 pages, 5 figures

Published

2010

42. Bose-Einstein Condensation of Strontium

Author

Stellmer, Simon, Tey, Meng Khoon, Huang, Bo, Grimm, Rudolf, and Schreck, Florian

Subjects

Condensed Matter - Quantum Gases

Abstract

We report on the attainment of Bose-Einstein condensation with ultracold strontium atoms. We use the 84Sr isotope, which has a low natural abundance but offers excellent scattering properties for evaporative cooling. Accumulation in a metastable state using a magnetic-trap, narrowline cooling, and straightforward evaporative cooling in an optical trap lead to pure condensates containing 1.5x10^5 atoms. This puts 84Sr in a prime position for future experiments on quantum-degenerate gases involving atomic two-electron systems., Comment: 4 pages, 3 figures; minor editorial changes

Published

2009

43. Compact high-spectral purity frequency combs for Strontium quantum clock

Author

Boughdachi, Sana, primary, Brodschelm, Andreas, additional, Wilk, Rafal, additional, and Schreck, Florian, additional

Published

2024

44. Science in Medieval Fiction. The Case of Konráðs saga keisarasonar

Author

Schreck, Florian, primary

Published

2021

45. Simultaneous Magneto-Optical Trapping of Two Lithium Isotopes

Author

Mewes, Marc-Oliver, Ferrari, Gabriele, Schreck, Florian, Sinatra, Alice, and Salomon, Christophe

Subjects

Physics - Atomic Physics

Abstract

We confine 4 10^8 fermionic 6Li atoms simultaneously with 9 10^9 bosonic 7Li atoms in a magneto-optical trap based on an all-semiconductor laser system. We optimize the two-isotope sample for sympathetic evaporative cooling. This is an essential step towards the production of a quantum-degenerate gas of fermionic lithium atoms., Comment: 4 pages, 3 figures

Published

1999

46. SAGE: A proposal for a space atomic gravity explorer

Author

Tino, Guglielmo M., Bassi, Angelo, Bianco, Giuseppe, Bongs, Kai, Bouyer, Philippe, Cacciapuoti, Luigi, Capozziello, Salvatore, Chen, Xuzong, Chiofalo, Maria L., Derevianko, Andrei, Ertmer, Wolfgang, Gaaloul, Naceur, Gill, Patrick, Graham, Peter W., Hogan, Jason M., Iess, Luciano, Kasevich, Mark A., Katori, Hidetoshi, Klempt, Carsten, Lu, Xuanhui, Ma, Long-Sheng, Müller, Holger, Newbury, Nathan R., Oates, Chris W., Peters, Achim, Poli, Nicola, Rasel, Ernst M., Rosi, Gabriele, Roura, Albert, Salomon, Christophe, Schiller, Stephan, Schleich, Wolfgang, Schlippert, Dennis, Schreck, Florian, Schubert, Christian, Sorrentino, Fiodor, Sterr, Uwe, Thomsen, Jan W., Vallone, Giuseppe, Vetrano, Flavio, Villoresi, Paolo, von Klitzing, Wolf, Wilkowski, David, Wolf, Peter, Ye, Jun, Yu, Nan, and Zhan, Mingsheng

Published

2019

47. Neutral atoms in tweezer arrays for hybrid quantum computing

Author

Venderbosch, Marijn L., Guo, Zhichao, van Herk, Rik A.H., Janse van Rensburg, Deon, Knottnerus, Ivo, Tseng, Y., Urech, Alexander, Spreeuw, R.J.C., Schreck, Florian, Vredenbregt, Edgar J.D., Lous, Rianne S., Kokkelmans, Servaas J.J.M.F, Venderbosch, Marijn L., Guo, Zhichao, van Herk, Rik A.H., Janse van Rensburg, Deon, Knottnerus, Ivo, Tseng, Y., Urech, Alexander, Spreeuw, R.J.C., Schreck, Florian, Vredenbregt, Edgar J.D., Lous, Rianne S., and Kokkelmans, Servaas J.J.M.F

Abstract

Neutral atoms trapped in optical tweezers show promise as an implementation of quantum computation. For example, the number of qubits can be scaled naturally by increasing the tweezer laser power. In Eindhoven, we are constructing a tweezer machine that features strontium- 88 atoms in an array of optical tweezers. The chosen qubit states are 1S0 and 3P0, which are connected by the doubly forbidden clock transition. Siteselective control of the clock laser onto the qubits will be done with the help of acousto-optic deflectors. Entanglement will be generated by coupling the 3P0 state to a 3S1 Rydberg state using 317 nm laser pulses. The quantum processor will run hybrid variational type algorithms, for example pulse-based optimization algorithms, whereby the quantum processor runs in tandem with a classical processor. On the poster, we will show recent progress towards this goal: we elaborate on the design of the apparatus and show experimental results on trapping ultra-cold strontium atoms in “blue” and “red” magneto-optical traps.

Published

2023

48. Automatic Relocking ECDL in Optical Tweezer Machine for Quantum Computing and Simulation

Author

Zarei, Mehrdad, primary, Knottnerus, Ivo, additional, Urech, Alex, additional, Schreck, Florian, additional, Zawada, Michał, additional, and Morzyński, Piotr, additional

Published

2023

49. Neutral atoms in tweezer arrays for hybrid Rydberg quantum computing

Author

GUO, Zhichao, primary, Janse van Rensburg, Deon, primary, van Herk, Rik, primary, Venderbosch, Marijn, primary, Knottnerus, Ivo, primary, Urech, Alexander, primary, Chih Tseng, Yu, primary, de Keijzer, Robert, primary, Mohan, Madhav, primary, Postema, Jasper, primary, J Spreeuw, Robert, primary, Schreck, Florian, primary, Lous, Rianne, primary, Vredenbregt, Edgar, primary, and Kokkelmans, Servaas, primary

Published

2023

50. Compact high-spectral purity frequency combs for Strontium quantum clock

Author

Jollivet, Clémence, Boughdachi, Sana, Brodschelm, Andreas, Wilk, Rafał, and Schreck, Florian

Published

2024