Your search keyword '"Singh, Jaideep T."' showing total 9 results

1. Progress towards the FRIB-EDM[formula omitted]-Frontend: A tool to provide radioactive molecules from isotope harvesting for fundamental symmetry studies

Author

Ballof, J., Nusgart, N., Lalain, P., Au, M., Heinke, R., Leimbach, D., Stegemann, S., Schütt, M., Rothe, S., and Singh, Jaideep T.

Published

2023

2. Surface processing and discharge-conditioning of high voltage electrodes for the Ra EDM experiment

Author

Ready, Roy A., Arrowsmith-Kron, Gordon, Bailey, Kevin G., Battaglia, Dominic, Bishof, Michael, Coulter, Daniel, Dietrich, Matthew R., Fang, Ruoyu, Hanley, Brian, Huneau, Jake, Kennedy, Sean, Lalain, Peyton, Loseth, Benjamin, McGee, Kellen, Mueller, Peter, O’Connor, Thomas P., O’Kronley, Jordan, Powers, Adam, Rabga, Tenzin, Sanchez, Andrew, Schalk, Eli, Waldo, Dale, Wescott, Jacob, and Singh, Jaideep T.

Published

2021

3. Measurement of the generalized spin polarizabilities of the neutron in the low-Q2 region

Author

Sulkosky, Vincent, Peng, Chao, Chen, Jian-ping, Deur, Alexandre, Abrahamyan, Sergey, Aniol, Konrad A., Armstrong, David S., Averett, Todd, Bailey, Stephanie L., Beck, Arie, Bertin, Pierre, Butaru, Florentin, Boeglin, Werner, Camsonne, Alexandre, Cates, Gordon D., Chang, Chia-Cheh, Choi, Seonho, Chudakov, Eugene, Coman, Luminita, Cornejo, Juan C., Craver, Brandon, Cusanno, Francesco, De Leo, Raffaele, de Jager, Cornelis W., Denton, Joseph D., Dhamija, Seema, Feuerbach, Robert, Finn, John M., Frullani, Salvatore, Fuoti, Kirsten, Gao, Haiyan, Garibaldi, Franco, Gayou, Olivier, Gilman, Ronald, Glamazdin, Alexander, Glashausser, Charles, Gomez, Javier, Hansen, Jens-Ole, Hayes, David, Hersman, F. William, Higinbotham, Douglas W., Holmstrom, Timothy, Humensky, Thomas B., Hyde, Charles E., Ibrahim, Hassan, Iodice, Mauro, Jiang, Xiandong, Kaufman, Lisa J., Kelleher, Aidan, Keister, Kathryn E., Kim, Wooyoung, Kolarkar, Ameya, Kolb, Norm, Korsch, Wolfgang, Kramer, Kevin, Kumbartzki, Gerfried, Lagamba, Luigi, Lainé, Vivien, Laveissiere, Geraud, Lerose, John J., Lhuillier, David, Lindgren, Richard, Liyanage, Nilanga, Lu, Hai-Jiang, Ma, Bin, Margaziotis, Demetrius J., Markowitz, Peter, McCormick, Kathleen R., Meziane, Mehdi, Meziani, Zein-Eddine, Michaels, Robert, Moffit, Bryan, Monaghan, Peter, Nanda, Sirish, Niedziela, Jennifer, Niskin, Mikhail, Pandolfi, Ronald, Paschke, Kent D., Potokar, Milan, Puckett, Andrew, Punjabi, Vina A., Qiang, Yi, Ransome, Ronald D., Reitz, Bodo, Roché, Rikki, Saha, Arun, Shabetai, Alexander, Širca, Simon, Singh, Jaideep T., Slifer, Karl, Snyder, Ryan, Solvignon, Patricia, Stringer, Robert, Subedi, Ramesh, Tobias, William A., Ton, Ngyen, Ulmer, Paul E., Urciuoli, Guido Maria, Vacheret, Antonin, Voutier, Eric, Wang, Kebin, Wan, Lu, Wojtsekhowski, Bogdan, Woo, Seungtae, Yao, Huan, Yuan, Jing, Zhan, Xiaohui, Zheng, Xiaochao, and Zhu, Lingyan

Published

2021

4. Author Correction: Measurement of the generalized spin polarizabilities of the neutron in the low-Q2 region

Author

Sulkosky, Vincent, Peng, Chao, Chen, Jian-ping, Deur, Alexandre, Abrahamyan, Sergey, Aniol, Konrad A., Armstrong, David S., Averett, Todd, Bailey, Stephanie L., Beck, Arie, Bertin, Pierre, Butaru, Florentin, Boeglin, Werner, Camsonne, Alexandre, Cates, Gordon D., Chang, Chia-Cheh, Choi, Seonho, Chudakov, Eugene, Coman, Luminita, Cornejo, Juan C., Craver, Brandon, Cusanno, Francesco, De Leo, Raffaele, de Jager, Cornelis W., Denton, Joseph D., Dhamija, Seema, Feuerbach, Robert, Finn, John M., Frullani, Salvatore, Fuoti, Kirsten, Gao, Haiyan, Garibaldi, Franco, Gayou, Olivier, Gilman, Ronald, Glamazdin, Alexander, Glashausser, Charles, Gomez, Javier, Hansen, Jens-Ole, Hayes, David, Hersman, F. William, Higinbotham, Douglas W., Holmstrom, Timothy, Humensky, Thomas B., Hyde, Charles E., Ibrahim, Hassan, Iodice, Mauro, Jiang, Xiandong, Kaufman, Lisa J., Kelleher, Aidan, Keister, Kathryn E., Kim, Wooyoung, Kolarkar, Ameya, Kolb, Norm, Korsch, Wolfgang, Kramer, Kevin, Kumbartzki, Gerfried, Lagamba, Luigi, Lainé, Vivien, Laveissiere, Geraud, Lerose, John J., Lhuillier, David, Lindgren, Richard, Liyanage, Nilanga, Lu, Hai-Jiang, Ma, Bin, Margaziotis, Demetrius J., Markowitz, Peter, McCormick, Kathleen R., Meziane, Mehdi, Meziani, Zein-Eddine, Michaels, Robert, Moffit, Bryan, Monaghan, Peter, Nanda, Sirish, Niedziela, Jennifer, Niskin, Mikhail, Pandolfi, Ronald, Paschke, Kent D., Potokar, Milan, Puckett, Andrew, Punjabi, Vina A., Qiang, Yi, Ransome, Ronald D., Reitz, Bodo, Roché, Rikki, Saha, Arun, Shabetai, Alexander, Širca, Simon, Singh, Jaideep T., Slifer, Karl, Snyder, Ryan, Solvignon, Patricia, Stringer, Robert, Subedi, Ramesh, Tobias, William A., Ton, Ngyen, Ulmer, Paul E., Urciuoli, Guido Maria, Vacheret, Antonin, Voutier, Eric, Wang, Kebin, Wan, Lu, Wojtsekhowski, Bogdan, Woo, Seungtae, Yao, Huan, Yuan, Jing, Zhan, Xiaohui, Zheng, Xiaochao, and Zhu, Lingyan

Published

2022

5. Rare isotope-containing diamond colour centres for fundamental symmetry tests.

Author

Morris, Ian M., Klink, Kai, Singh, Jaideep T., Mendoza-Cortes, Jose L., Nicley, Shannon S., and Becker, Jonas N.

Subjects

ELECTRIC dipole moments, ARTIFICIAL diamonds, DIAMOND crystals, DIAMONDS, BAND gaps, ELECTRONIC structure, CRYSTAL defects, HUMAN information processing, BIOLOGICALLY inspired computing

Abstract

Detecting a non-zero electric dipole moment in a particle would unambiguously signify physics beyond the Standard Model. A potential pathway towards this is the detection of a nuclear Schiff moment, the magnitude of which is enhanced by the presence of nuclear octupole deformation. However, due to the low production rate of isotopes featuring such 'pear-shaped' nuclei, capturing, detecting and manipulating them efficiently is a crucial prerequisite. Incorporating them into synthetic diamond optical crystals can produce defects with defined, molecule-like structures and isolated electronic states within the diamond band gap, increasing capture efficiency, enabling repeated probing of even a single atom and producing narrow optical linewidths. In this study, we used density functional theory to investigate the formation, structure and electronic properties of crystal defects in diamond containing 229Pa , a rare isotope that is predicted to have an exceptionally strong nuclear octupole deformation. In addition, we identified and studied stable lanthanide-containing defects with similar electronic structures as non-radioactive proxies to aid in experimental methods. Our findings hold promise for the existence of such defects and can contribute to the development of a quantum information processing-inspired toolbox of techniques for studying rare isotopes. This article is part of the Theo Murphy meeting issue 'Diamond for quantum applications'. [ABSTRACT FROM AUTHOR]

Published

2024

6. Development of high-performance alkali-hybrid polarized ³He targets for electron scattering.

Author

Singh, Jaideep T., Dolph, P. A. M., Tobias, W. A., Averett, T. D., Kelleher, A., Mooney, K. E., Nelyubin, V. V., Yunxiao Wang, Yuan Zheng, and Cates, G. D.

Subjects

*ELECTRON scattering, *POLARIZATION (Nuclear physics), *HELIUM, *NEUTRONS, *OPTICAL pumping, *SPIN exchange

Abstract

Background: Polarized ³He targets have been used as effective polarized neutron targets for electron scattering experiments for over twenty years. Over the last ten years, the effective luminosity of polarized ³He targets based on spin-exchange optical pumping has increased by over an order of magnitude. This has come about because of improvements in commercially-available lasers and an improved understanding of the physics behind the polarization process. Purpose: We present the development of high-performance polarized ³He targets for use in electron scattering experiments. Improvements in the performance of polarized ³He targets, target properties, and operating parameters are documented. Methods: We utilize the technique of alkali-hybrid spin-exchange optical pumping to polarize the ³He targets. Spectrally narrowed diode lasers used for the optical pumping greatly improved the performance. A simulation of the alkali-hybrid spin-exchange optical pumping process was developed to provide guidance in the design of the targets. Data was collected during the characterization of 24 separate glass target cells, each of which was constructed while preparing for one of four experiments at Jefferson Laboratory in Newport News, Virginia. Results: From the data obtained we made determinations of the so-called X-factors that quantify a temperature-dependent and as-yet poorly understood spin-relaxation mechanism that limits the maximum achievable ³He polarization to well under 100%. The presence of the X-factor spin-relaxation mechanism was clearly evident in our data. Good agreement between the simulation and the actual target performance was obtained by including details such as off-resonant optical pumping. Included in our results is a measurement of the K−³He spin-exchange rate coefficient kKse = (7.46 ± 0.62) × 10−20 cm³/s over the temperature range 503 K to 563 K. Conclusions: In order to achieve high performance under the operating conditions described in this paper, the K to Rb alkali vapor density ratio should be about 5 ± 2 and the line width of the optical pumping lasers should be no more than 0.3 nm. Our measurements of the X-factors under these conditions seem to indicate the ³He polarization is limited to ≈ 90%. The simulation results, now benchmarked against experimental data, are useful for the design of future targets. Further work is required to better understand the temperature dependence of the X-factor spin-relaxation mechanism and the limitations of our optical pumping simulation. [ABSTRACT FROM AUTHOR]

Published

2015

7. Improved limit on the 225Ra electric dipole moment.

Author

Bishof, Michael, Parker, Richard H., Bailey, Kevin G., Greene, John P., Holt, Roy J., Kalita, Mukut R., Wolfgang Korsch, Lemke, Nathan D., Zheng-Tian Lu, Mueller, Peter, O'Connor, Thomas P., Singh, Jaideep T., and Dietrich, Matthew R.

Subjects

*RADIUM compounds, *ELECTRIC dipole moments, *SENSITIVITY analysis

Abstract

Background: Octupole-deformed nuclei, such as that of 225Ra, are expected to amplify observable atomic electric dipole moments (EDMs) that arise from time-reversal and parity-violating interactions in the nuclear medium. In 2015 we reported the first "proof-of-principle" measurement of the 225Ra atomic EDM. Purpose: This work reports on the first of several experimental upgrades to improve the statistical sensitivity of our 225Ra EDM measurements by orders of magnitude and evaluates systematic effects that contribute to current and future levels of experimental sensitivity. Method: Laser-cooled and trapped 225Ra atoms are held between two high-voltage electrodes in an ultrahigh-vacuum chamber at the center of a magnetically-shielded environment. We observe Larmor precession in a uniform magnetic field using nuclear-spin-dependent laser light scattering and look for a phase shift proportional to the applied electric field, which indicates the existence of an EDM. The main improvement to our measurement technique is an order-of-magnitude increase in spin-precession time, which is enabled by an improved vacuum system and a reduction in trap-induced heating. Results: We have measured the 225Ra atomic EDM to be less than 1.4×10-23e cm (95% confidence upper limit), which is a factor of 36 improvement over our previous result. Conclusions: Our evaluation of systematic effects shows that this measurement is completely limited by statistical uncertainty. Combining this measurement technique with planned experimental upgrades, we project a statistical sensitivity at the 1×10-28e cm level and a total systematic uncertainty at the 4×10-29e cm level. [ABSTRACT FROM AUTHOR]

Published

2016

8. Opportunities for fundamental physics research with radioactive molecules.

Author

Arrowsmith-Kron G, Athanasakis-Kaklamanakis M, Au M, Ballof J, Berger R, Borschevsky A, Breier AA, Buchinger F, Budker D, Caldwell L, Charles C, Dattani N, de Groote RP, DeMille D, Dickel T, Dobaczewski J, Düllmann CE, Eliav E, Engel J, Fan M, Flambaum V, Flanagan KT, Gaiser AN, Garcia Ruiz RF, Gaul K, Giesen TF, Ginges JSM, Gottberg A, Gwinner G, Heinke R, Hoekstra S, Holt JD, Hutzler NR, Jayich A, Karthein J, Leach KG, Madison KW, Malbrunot-Ettenauer S, Miyagi T, Moore ID, Moroch S, Navratil P, Nazarewicz W, Neyens G, Norrgard EB, Nusgart N, Pašteka LF, N Petrov A, Plaß WR, Ready RA, Pascal Reiter M, Reponen M, Rothe S, Safronova MS, Scheidenerger C, Shindler A, Singh JT, Skripnikov LV, Titov AV, Udrescu SM, Wilkins SG, and Yang X

Abstract

Molecules containing short-lived, radioactive nuclei are uniquely positioned to enable a wide range of scientific discoveries in the areas of fundamental symmetries, astrophysics, nuclear structure, and chemistry. Recent advances in the ability to create, cool, and control complex molecules down to the quantum level, along with recent and upcoming advances in radioactive species production at several facilities around the world, create a compelling opportunity to coordinate and combine these efforts to bring precision measurement and control to molecules containing extreme nuclei. In this manuscript, we review the scientific case for studying radioactive molecules, discuss recent atomic, molecular, nuclear, astrophysical, and chemical advances which provide the foundation for their study, describe the facilities where these species are and will be produced, and provide an outlook for the future of this nascent field., (© 2024 IOP Publishing Ltd.)

Published

2024

9. Rare isotope-containing diamond colour centres for fundamental symmetry tests.

Author

Morris IM, Klink K, Singh JT, Mendoza-Cortes JL, Nicley SS, and Becker JN

Abstract

Detecting a non-zero electric dipole moment in a particle would unambiguously signify physics beyond the Standard Model. A potential pathway towards this is the detection of a nuclear Schiff moment, the magnitude of which is enhanced by the presence of nuclear octupole deformation. However, due to the low production rate of isotopes featuring such 'pear-shaped' nuclei, capturing, detecting and manipulating them efficiently is a crucial prerequisite. Incorporating them into synthetic diamond optical crystals can produce defects with defined, molecule-like structures and isolated electronic states within the diamond band gap, increasing capture efficiency, enabling repeated probing of even a single atom and producing narrow optical linewidths. In this study, we used density functional theory to investigate the formation, structure and electronic properties of crystal defects in diamond containing [Formula: see text], a rare isotope that is predicted to have an exceptionally strong nuclear octupole deformation. In addition, we identified and studied stable lanthanide-containing defects with similar electronic structures as non-radioactive proxies to aid in experimental methods. Our findings hold promise for the existence of such defects and can contribute to the development of a quantum information processing-inspired toolbox of techniques for studying rare isotopes. This article is part of the Theo Murphy meeting issue 'Diamond for quantum applications'.

Published

2024