Your search keyword '"Petrova, O."' showing total 1,114 results

1. Synthesis, Structure, and Optical Properties of Lead Gallate Glasses

Author

Terekhova, A. B., Butenkov, D. A., Runina, K. I., Uslamina, M. A., Pynenkov, A. A., and Petrova, O. B.

Published

2025

2. Structure and Optical Properties of ZrO2–Sc2O3 Solid Solution System Obtained by the Coprecipitation Method

Author

Danilov, V. P., Borisova, E. S., Shukshin, V. E., Runina, K. I., Strekalov, P. V., Mayakova, M. N., and Petrova, O. B.

Published

2025

3. Calculation of Glow Discharge Parameters in a Supersonic Axisymmetric Helium Flow

Author

Timerkaev, B. A., Petrova, O. A., Sayfutdinov, A. I., and Israfilov, D. I.

Published

2024

4. Glow Discharge Initiated with Non-Uniform Gas Density with Planar and Coaxial Electrodes

Author

Timerkaev, B. A., Petrova, O. A., Saifutdinova, A. A., and Turutin, V. Yu.

Published

2024

5. Role of Carbon Dioxide in the Regulation of Adaptive Proliferation in Bacteria

Author

Petrova, O. E., Parfirova, O. I., Vorob’ev, V. N., and Gorshkov, V. Yu.

Published

2024

6. Search for $CP$-Violating Neutrino Nonstandard Interactions with the NOvA Experiment

Author

NOvA Collaboration, Acero, M. A., Acharya, B., Adamson, P., Aliaga, L., Anfimov, N., Antoshkin, A., Arrieta-Diaz, E., Asquith, L., Aurisano, A., Back, A., Balashov, N., Baldi, P., Bambah, B. A., Bat, A., Bays, K., Bernstein, R., Bezerra, T. J. C., Bhatnagar, V., Bhattarai, D., Bhuyan, B., Bian, J., Booth, A. C., Bowles, R., Brahma, B., Bromberg, C., Buchanan, N., Butkevich, A., Calvez, S., Carroll, T. J., Catano-Mur, E., Cesar, J. P., Chatla, A., Chaudhary, S., Chirco, R., Choudhary, B. C., Christensen, A., Cicala, M. F., Coan, T. E., Cooleybeck, A., Cortes-Parra, C., Coveyou, D., Cremonesi, L., Davies, G. S., Derwent, P. F., Djurcic, Z., Dolce, M., Doyle, D., Tonguino, D. Dueñas, Dukes, E. C., Dye, A., Ehrlich, R., Ewart, E., Filip, P., Franc, J., Frank, M. J., Gallagher, H. R., Gao, F., Giri, A., Gomes, R. A., Goodman, M. C., Groh, M., Group, R., Habig, A., Hakl, F., Hartnell, J., Hatcher, R., He, M., Heller, K., Hewes, V, Himmel, A., Ivaneev, Y., Ivanova, A., Jargowsky, B., Jarosz, J., Johnson, C., Judah, M., Kakorin, I., Kaplan, D. M., Kalitkina, A., Kleykamp, J., Klimov, O., Koerner, L. W., Kolupaeva, L., Kralik, R., Kumar, A., Kuruppu, C. D., Kus, V., Lackey, T., Lang, K., Lesmeister, J., Lister, A., Liu, J., Lock, J. A., Lokajicek, M., MacMahon, M., Magill, S., Mann, W. A., Manoharan, M. T., Plata, M. Manrique, Marshak, M. L., Martinez-Casales, M., Matveev, V., Mehta, B., Messier, M. D., Meyer, H., Miao, T., Mikola, V., Miller, W. H., Mishra, S., Mishra, S. R., Mislivec, A., Mohanta, R., Moren, A., Morozova, A., Mu, W., Mualem, L., Muether, M., Mulder, K., Myers, D., Naples, D., Nath, A., Nelleri, S., Nelson, J. K., Nichol, R., Niner, E., Norman, A., Norrick, A., Nosek, T., Oh, H., Olshevskiy, A., Olson, T., Ozkaynak, M., Pal, A., Paley, J., Panda, L., Patterson, R. B., Pawloski, G., Petrova, O., Petti, R., Prais, L. R., Rafique, A., Raj, V., Rajaoalisoa, M., Ramson, B., Ravelhofer, M., Rebel, B., Roy, P., Samoylov, O., Sanchez, M. C., Falero, S. Sánchez, Shanahan, P., Sharma, P., Shmakov, A., Sheshukov, A., Shukla, S., Singha, D. K., Shorrock, W., Singh, I., Singh, P., Singh, V., Smith, E., Smolik, J., Snopok, P., Solomey, N., Sousa, A., Soustruznik, K., Strait, M., Suter, L., Sutton, A., Sutton, K., Swain, S., Sweeney, C., Sztuc, A., Oregui, B. Tapia, Tas, P., Thakore, T., Thomas, J., Tiras, E., Torun, Y., Tripathi, J., Trokan-Tenorio, J., Urheim, J., Vahle, P., Vallari, Z., Vasel, J., Villamil, J. D., Vockerodt, K. J., Vrba, T., Wallbank, M., Wetstein, M., Whittington, D., Wickremasinghe, D. A., Wieber, T., Wolcott, J., Wrobel, M., Wu, S., Wu, W., Xiao, Y., Yaeggy, B., Yahaya, A., Yankelevich, A., Yonehara, K., Yu, Y., Zadorozhnyy, S., Zalesak, J., and Zwaska, R.

Subjects

High Energy Physics - Experiment, High Energy Physics - Phenomenology

Abstract

This Letter reports a search for charge-parity ($CP$) symmetry violating nonstandard interactions (NSI) of neutrinos with matter using the NOvA Experiment, and examines their effects on the determination of the standard oscillation parameters. Data from $\nu_{\mu}(\bar{\nu}_{\mu})\rightarrow\nu_{\mu}(\bar{\nu}_{\mu})$ and $\nu_{\mu}(\bar{\nu}_{\mu})\rightarrow\nu_{e}(\bar{\nu}_{e})$ oscillation channels are used to measure the effect of the NSI parameters $\varepsilon_{e\mu}$ and $\varepsilon_{e\tau}$. With 90% CL the magnitudes of the NSI couplings are constrained to be $|\varepsilon_{e\mu}| \, \lesssim 0.3$ and $|\varepsilon_{e\tau}| \, \lesssim 0.4$. A degeneracy at $|\varepsilon_{e\tau}| \, \approx 1.8$ is reported, and we observe that the presence of NSI limits sensitivity to the standard $CP$ phase $\delta_{\tiny\text{CP}}$.

Published

2024

7. Expanding neutrino oscillation parameter measurements in NOvA using a Bayesian approach

Author

NOvA Collaboration, Acero, M. A., Acharya, B., Adamson, P., Anfimov, N., Antoshkin, A., Arrieta-Diaz, E., Asquith, L., Aurisano, A., Back, A., Balashov, N., Baldi, P., Bambah, B. A., Bat, A., Bays, K., Bernstein, R., Bezerra, T. J. C., Bhatnagar, V., Bhattarai, D., Bhuyan, B., Bian, J., Booth, A. C., Bowles, R., Brahma, B., Bromberg, C., Buchanan, N., Butkevich, A., Calvez, S., Carroll, T. J., Catano-Mur, E., Cesar, J. P., Chatla, A., Chirco, R., Chaudhary, S., Choudhary, B. C., Christensen, A., Coan, T. E., Cooleybeck, A., Cremonesi, L., Davies, G. S., Derwent, P. F., Ding, P., Djurcic, Z., Dolce, M., Doyle, D., Tonguino, D. Dueñas, Dukes, E. C., Dye, A., Ehrlich, R., Elkins, M., Ewart, E., Filip, P., Franc, J., Frank, M. J., Gallagher, H. R., Gao, F., Giri, A., Gomes, R. A., Goodman, M. C., Groh, M., Group, R., Habig, A., Hakl, F., Hartnell, J., Hatcher, R., He, M., Heller, K., Hewes, V, Himmel, A., Jargowsky, B., Jarosz, J., Jediny, F., Johnson, C., Judah, M., Kakorin, I., Kaplan, D. M., Kalitkina, A., Kleykamp, J., Klimov, O., Koerner, L. W., Kolupaeva, L., Kralik, R., Kumar, A., Kuruppu, C. D., Kus, V., Lackey, T., Lang, K., Lasorak, P., Lesmeister, J., Lister, A., Liu, J., Lokajicek, M., MacMahon, M., Lock, J. A., Magill, S., Plata, M. Manrique, Mann, W. A., Manoharan, M. T., Marshak, M. L., Martinez-Casales, M., Matveev, V., Mehta, B., Messier, M. D., Meyer, H., Miao, T., Mikola, V., Miller, W. H., Mishra, S., Mishra, S. R., Mohanta, R., Moren, A., Morozova, A., Mu, W., Mualem, L., Muether, M., Mulder, K., Myers, D., Naples, D., Nath, A., Nelleri, S., Nelson, J. K., Nichol, R., Niner, E., Norman, A., Norrick, A., Nosek, T., Oh, H., Olshevskiy, A., Olson, T., Pal, A., Paley, J., Panda, L., Patterson, R. B., Pawloski, G., Petrova, O., Petti, R., Plunkett, R. K., Rafique, A., Prais, L. R., Raj, V., Rajaoalisoa, M., Ramson, B., Rebel, B., Roy, P., Samoylov, O., Sanchez, M. C., Falero, S. Sánchez, Shanahan, P., Sharma, P., Shukla, S., Sheshukov, A., Singha, D. K., Shorrock, W., Singh, I., Singh, P., Singh, V., Smith, E., Smolik, J., Snopok, P., Solomey, N., Sousa, A., Soustruznik, K., Strait, M., Suter, L., Sutton, A., Sutton, K., Swain, S., Sweeney, C., Sztuc, A., Oregui, B. Tapia, Tas, P., Thakore, T., Thomas, J., Tiras, E., Trokan-Tenorio, J., Torun, Y., Urheim, J., Vahle, P., Vallari, Z., Vockerodt, K. J., Vrba, T., Wallbank, M., Warburton, T. K., Wetstein, M., Whittington, D., Wickremasinghe, D. A., Wieber, T., Wolcott, J., Wrobel, M., Wu, S., Wu, W., Xiao, Y., Yaeggy, B., Yankelevich, A., Yonehara, K., Yu, Y., Zadorozhnyy, S., Zalesak, J., and Zwaska, R.

Subjects

High Energy Physics - Experiment, High Energy Physics - Phenomenology

Abstract

NOvA is a long-baseline neutrino oscillation experiment that measures oscillations in charged-current $\nu_{\mu} \rightarrow \nu_{\mu}$ (disappearance) and $\nu_{\mu} \rightarrow \nu_{e}$ (appearance) channels, and their antineutrino counterparts, using neutrinos of energies around 2 GeV over a distance of 810 km. In this work we reanalyze the dataset first examined in our previous paper [Phys. Rev. D 106, 032004 (2022)] using an alternative statistical approach based on Bayesian Markov Chain Monte Carlo. We measure oscillation parameters consistent with the previous results. We also extend our inferences to include the first NOvA measurements of the reactor mixing angle $\theta_{13}$ and the Jarlskog invariant. We use these results to quantify the strength of our inferences about CP violation, as well as to examine the effects of constraints from short-baseline measurements of $\theta_{13}$ using antineutrinos from nuclear reactors when making NOvA measurements of $\theta_{23}$. Our long-baseline measurement of $\theta_{13}$ is also shown to be consistent with the reactor measurements, supporting the general applicability and robustness of the PMNS framework for neutrino oscillations., Comment: 20 pages, 17 figures; version accepted by Phys. Rev. D. Data associated with this paper is available at https://doi.org/10.15484/2349444

Published

2023

8. Synthesis and Properties of Sm3+/Gd3+ Co-Doped B2O3–GeO2–Bi2O3 Glass Composition

Author

Zykova, S. S., Serkina, K. S., Runina, K. I., Avetissov, I. Ch., Petrova, O. B., and Boldyrev, K. A.

Published

2024

9. Investigation of Chemical Resistance of Oxychloride Lead Borate Glasses Doped with Neodymium and the Stability of Their Luminescent Properties in the Climatic Conditions of South-East Asia

Author

Butenkov, D. A., Berdieva, D. E., Bakaeva, A. V., Runina, K. I., Avetisov, R. I., Petrova, O. B., Do, D. T., and Ta, T. T.

Published

2024

10. Monte Carlo method for constructing confidence intervals with unconstrained and constrained nuisance parameters in the NOvA experiment

Author

Acero, M. A., Acharya, B., Adamson, P., Aliaga, L., Anfimov, N., Antoshkin, A., Arrieta-Diaz, E., Asquith, L., Aurisano, A., Back, A., Backhouse, C., Baird, M., Balashov, N., Baldi, P., Bambah, B. A., Bashar, S., Bat, A., Bays, K., Bernstein, R., Bhatnagar, V., Bhattarai, D., Bhuyan, B., Bian, J., Booth, A. C., Bowles, R., Brahma, B., Bromberg, C., Buchanan, N., Butkevich, A., Calvez, S., Carroll, T. J., Catano-Mur, E., Chatla, A., Chirco, R., Choudhary, B. C., Choudhary, S., Christensen, A., Coan, T. E., Colo, M., Cremonesi, L., Davies, G. S., Derwent, P. F., Ding, P., Djurcic, Z., Dolce, M., Doyle, D., Tonguino, D. Dueñas, Dukes, E. C., Dye, A., Ehrlich, R., Elkins, M., Ewart, E., Feldman, G. J., Filip, P., Franc, J., Frank, M. J., Gallagher, H. R., Gandrajula, R., Gao, F., Giri, A., Gomes, R. A., Goodman, M. C., Grichine, V., Groh, M., Group, R., Guo, B., Habig, A., Hakl, F., Hall, A., Hartnell, J., Hatcher, R., Hausner, H., He, M., Heller, K., Hewes, V, Himmel, A., Jargowsky, B., Jarosz, J., Jediny, F., Johnson, C., Judah, M., Kakorin, I., Kaplan, D. M., Kalitkina, A., Kleykamp, J., Klimov, O., Koerner, L. W., Kolupaeva, L., Kotelnikov, S., Kralik, R., Kullenberg, Ch., Kubu, M., Kumar, A., Kuruppu, C. D., Kus, V., Lackey, T., Lang, K., Lasorak, P., Lesmeister, J., Lin, S., Lister, A., Liu, J., Lokajicek, M., Lopez, J. M. C., Mahji, R., Magill, S., Plata, M. Manrique, Mann, W. A., Manoharan, M. T., Marshak, M. L., Martinez-Casales, M., Matveev, V., Mayes, B., Mehta, B., Messier, M. D., Meyer, H., Miao, T., Mikola, V., Miller, W. H., Mishra, S., Mishra, S. R., Mislivec, A., Mohanta, R., Moren, A., Morozova, A., Mu, W., Mualem, L., Muether, M., Mulder, K., Naples, D., Nath, A., Nayak, N., Nelleri, S., Nelson, J. K., Nichol, R., Niner, E., Norman, A., Norrick, A., Nosek, T., Oh, H., Olshevskiy, A., Olson, T., Ott, J., Pal, A., Paley, J., Panda, L., Patterson, R. B., Pawloski, G., Pershey, D., Petrova, O., Petti, R., Phan, D. D., Plunkett, R. K., Pobedimov, A., Porter, J. C. C., Rafique, A., Prais, L. R., Raj, V., Rajaoalisoa, M., Ramson, B., Rebel, B., Rojas, P., Roy, P., Ryabov, V., Samoylov, O., Sanchez, M. C., Falero, S. Sánchez, Shanahan, P., Sharma, P., Shukla, S., Sheshukov, A., Singh, I., Singh, P., Singh, V., Smith, E., Smolik, J., Snopok, P., Solomey, N., Sousa, A., Soustruznik, K., Strait, M., Suter, L., Sutton, A., Swain, S., Sweeney, C., Sztuc, A., Oregui, B. Tapia, Tas, P., Temizel, B. N., Thakore, T., Thayyullathil, R. B., Thomas, J., Tiras, E., Tripathi, J., Trokan-Tenorio, J., Torun, Y., Urheim, J., Vahle, P., Vallari, Z., Vasel, J., Vrba, T., Wallbank, M., Warburton, T. K., Wetstein, M., Whittington, D., Wickremasinghe, D. A., Wieber, T., Wolcott, J., Wrobel, M., Wu, W., Xiao, Y., Yaeggy, B., Dombara, A. Yallappa, Yankelevich, A., Yonehara, K., Yu, S., Yu, Y., Zadorozhnyy, S., Zalesak, J., Zhang, Y., and Zwaska, R.

Subjects

High Energy Physics - Experiment, Physics - Data Analysis, Statistics and Probability

Abstract

Measuring observables to constrain models using maximum-likelihood estimation is fundamental to many physics experiments. Wilks' theorem provides a simple way to construct confidence intervals on model parameters, but it only applies under certain conditions. These conditions, such as nested hypotheses and unbounded parameters, are often violated in neutrino oscillation measurements and other experimental scenarios. Monte Carlo methods can address these issues, albeit at increased computational cost. In the presence of nuisance parameters, however, the best way to implement a Monte Carlo method is ambiguous. This paper documents the method selected by the NOvA experiment, the profile construction. It presents the toy studies that informed the choice of method, details of its implementation, and tests performed to validate it. It also includes some practical considerations which may be of use to others choosing to use the profile construction., Comment: 28 pages, 14 figures

Published

2022

11. Electronic Structure of the [Cu(Salen)] Complex and the Chemical State of Its Atoms Studied by Photoelectron Spectroscopy and Quantum-Chemical Calculations

Author

Korusenko, P. M., Koroleva, A. V., Vereshchagin, A. A., Katin, K. P., Petrova, O. V., Sivkov, D. V., Levin, O. V., and Vinogradov, A. S.

Published

2024

12. Measurement of the $\nu_e-$Nucleus Charged-Current Double-Differential Cross Section at $\left< E_{\nu} \right> = $ 2.4 GeV using NOvA

Author

Acero, M. A., Adamson, P., Aliaga, L., Anfimov, N., Antoshkin, A., Arrieta-Diaz, E., Asquith, L., Aurisano, A., Back, A., Backhouse, C., Baird, M., Balashov, N., Baldi, P., Bambah, B. A., Bashar, S., Bays, K., Bernstein, R., Bhatnagar, V., Bhattarai, D., Bhuyan, B., Bian, J., Booth, A. C., Bowles, R., Brahma, B., Bromberg, C., Buchanan, N., Butkevich, A., Calvez, S., Carroll, T. J., Catano-Mur, E., Childress, S., Chatla, A., Chirco, R., Choudhary, B. C., Christensen, A., Coan, T. E., Colo, M., Cremonesi, L., Davies, G. S., Derwent, P. F., Ding, P., Djurcic, Z., Dolce, M., Doyle, D., Tonguino, D. Duenas, Dukes, E. C., Ehrlich, R., Elkins, M., Ewart, E., Feldman, G. J., Filip, P., Franc, J., Frank, M. J., Gallagher, H. R., Gandrajula, R., Gao, F., Giri, A., Gomes, R. A., Goodman, M. C., Grichine, V., Groh, M., Group, R., Guo, B., Habig, A., Hakl, F., Hall, A., Hartnell, J., Hatcher, R., Hausner, H., He, M., Heller, K., Hewes, V, Himmel, A., Jargowsky, B., Jarosz, J., Jediny, F., Johnson, C., Judah, M., Kakorin, I., Kaplan, D. M., Kalitkina, A., Keloth, R., Klimov, O., Koerner, L. W., Kolupaeva, L., Kotelnikov, S., Kralik, R., Kullenberg, Ch., Kubu, M., Kumar, A., Kuruppu, C. D., Kus, V., Lackey, T., Lang, K., Lasorak, P., Lesmeister, J., Lin, S., Lister, A., Liu, J., Lokajicek, M., Lopez, J. M. C., Mahji, R., Magill, S., Plata, M. Manrique, Mann, W. A., Manoharan, M. T., Marshak, M. L., Martinez-Casales, M., Matveev, V., Mayes, B., Messier, M. D., Meyer, H., Miao, T., Mikola, V., Miller, W. H., Mishra, S., Mishra, S. R., Mislivec, A., Mohanta, R., Moren, A., Morozova, A., Mu, W., Mualem, L., Muether, M., Mulder, K., Naples, D., Nath, A., Nayak, N., Nelleri, S., Nelson, J. K., Nichol, R., Niner, E., Norman, A., Norrick, A., Nosek, T., Oh, H., Olshevskiy, A., Olson, T., Ott, J., Pal, A., Paley, J., Panda, L., Patterson, R. B., Pawloski, G., Petrova, O., Petti, R., Phan, D. D., Plunkett, R. K., Pobedimov, A., Porter, J. C. C., Rafique, A., Prais, L. R., Raj, V., Rajaoalisoa, M., Ramson, B., Rebel, B., Rojas, P., Roy, P., Ryabov, V., Samoylov, O., Sanchez, M. C., Falero, S. Sanchez, Shanahan, P., Shukla, S., Sheshukov, A., Singh, I., Singh, P., Singh, V., Smith, E., Smolik, J., Snopok, P., Solomey, N., Sousa, A., Soustruznik, K., Strait, M., Suter, L., Sutton, A., Swain, S., Sweeney, C., Sztuc, A., Talaga, R. L., Oregui, B. Tapia, Tas, P., Temizel, B. N., Thakore, T., Thayyullathil, R. B., Thomas, J., Tiras, E., Tripathi, J., Trokan-Tenorio, J., Torun, Y., Urheim, J., Vahle, P., Vallari, Z., Vasel, J., Vrba, T., Wallbank, M., Warburton, T. K., Wetstein, M., Whittington, D., Wickremasinghe, D. A., Wieber, T., Wolcott, J., Wu, W., Xiao, Y., Yaeggy, B., Dombara, A. Yallappa, Yankelevich, A., Yonehara, K., Yu, S., Yu, Y., Zadorozhnyy, S., Zalesak, J., Zhang, Y., and Zwaska, R.

Subjects

High Energy Physics - Experiment

Abstract

The inclusive electron neutrino charged-current cross section is measured in the NOvA near detector using $8.02\times10^{20}$ protons-on-target (POT) in the NuMI beam. The sample of GeV electron neutrino interactions is the largest analyzed to date and is limited by $\simeq$ 17\% systematic rather than the $\simeq$ 7.4\% statistical uncertainties. The double-differential cross section in final-state electron energy and angle is presented for the first time, together with the single-differential dependence on $Q^{2}$ (squared four-momentum transfer) and energy, in the range 1 GeV $ \leq E_{\nu} < $6 GeV. Detailed comparisons are made to the predictions of the GENIE, GiBUU, NEUT, and NuWro neutrino event generators. The data do not strongly favor a model over the others consistently across all three cross sections measured, though some models have especially good or poor agreement in the single differential cross section vs. $Q^{2}$.

Published

2022

13. Numerical Modeling of Stress–Strain Behavior of Rock Mass in the Course of Mining of Lower Strata in a Series

Author

Rib, S. V., Petrova, O. A., Nikitina, A. M., Boloshin, V. A., and Fryanov, V. N.

Published

2023

14. meso-CF3-Difluoroboradiazaindacenes (BODIPY) as Markers for Visualization of Lysosomes

Author

Shurygina, I. A., Dremina, N. N., Trukhan, I. S., Shurygin, M. G., Tomilin, D. N., Petrova, O. V., and Sobenina, L. N.

Published

2023

15. Measurement of the Double-Differential Muon-neutrino Charged-Current Inclusive Cross Section in the NOvA Near Detector

Author

Acero, M. A., Adamson, P., Aliaga, L., Anfimov, N., Antoshkin, A., Arrieta-Diaz, E., Asquith, L., Aurisano, A., Back, A., Backhouse, C., Baird, M., Balashov, N., Baldi, P., Bambah, B. A., Bashar, S., Bays, K., Behera, B., Bernstein, R., Bhatnagar, V., Bhattarai, D., Bhuyan, B., Bian, J., Blair, J., Booth, A. C., Bowles, R., Bromberg, C., Buchanan, N., Butkevich, A., Calvez, S., Carroll, T. J., Catano-Mur, E., Choudhary, B. C., Christensen, A., Coan, T. E., Colo, M., Cremonesi, L., Davies, G. S., Derwent, P. F., Ding, P., Djurcic, Z., Dolce, M., Doyle, D., Tonguino, D. Duenas, Dukes, E. C., Duyang, H., Edayath, S., Ehrlich, R., Elkins, M., Ewart, E., Feldman, G. J., Filip, P., Franc, J., Frank, M. J., Gallagher, H. R., Gandrajula, R., Gao, F., Giri, A., Gomes, R. A., Goodman, M. C., Grichine, V., Groh, M., Group, R., Guo, B., Habig, A., Hakl, F., Hall, A., Hartnell, J., Hatcher, R., Hausner, H., He, M., Heller, K., Hewes, V, Himmel, A., Holin, A., Huang, J., Jargowsky, B., Jarosz, J., Jediny, F., Johnson, C., Judah, M., Kakorin, I., Kalitkina, A., Kalra, D., Kaplan, D. M., Keloth, R., Klimov, O., Koerner, L. W., Kolupaeva, L., Kotelnikov, S., Kralik, R., Kullenberg, Ch., Kubu, M., Kumar, A., Kuruppu, C. D., Kus, V., Lackey, T., Lang, K., Lasorak, P., Lesmeister, J., Lin, S., Lister, A., Liu, J., Lokajicek, M., Magill, S., Plata, M. Manrique, Mann, W. A., Marshak, M. L., Martinez-Casales, M., Matveev, V., Mayes, B., Méndez, D. P., Messier, M. D., Meyer, H., Miao, T., Miller, W. H., Mishra, S. R., Mislivec, A., Mohanta, R., Moren, A., Morozova, A., Mu, W., Mualem, L., Muether, M., Mulder, K., Naples, D., Nayak, N., Nelson, J. K., Nichol, R., Niner, E., Norman, A., Norrick, A., Nosek, T., Oh, H., Olshevskiy, A., Olson, T., Ott, J., Paley, J., Patterson, R. B., Pawloski, G., Petrova, O., Petti, R., Phan, D. D., Plunkett, R. K., Porter, J. C. C., Rafique, A., Raj, V., Rajaoalisoa, M., Ramson, B., Rebel, B., Rojas, P., Roy, P., Ryabov, V., Sachdev, K., Samoylov, O., Sanchez, M. C., Falero, S. Sanchez, Shanahan, P., Sheshukov, A., Singh, P., Singh, V., Smith, E., Smolik, J., Snopok, P., Solomey, N., Sousa, A., Soustruznik, K., Strait, M., Suter, L., Sutton, A., Swain, S., Sweeney, C., Sztuc, A., Oregui, B. Tapia, Tas, P., Thakore, T., Thayyullathil, R. B., Thomas, J., Tiras, E., Tripathi, J., Trokan-Tenorio, J., Tsaris, A., Torun, Y., Urheim, J., Vahle, P., Vallari, Z., Vasel, J., Vokac, P., Vrba, T., Wallbank, M., Warburton, T. K., Wetstein, M., Whittington, D., Wickremasinghe, D. A., Wojcicki, S. G., Wolcott, J., Wu, W., Xiao, Y., Dombara, A. Yallappa, Yankelevich, A., Yonehara, K., Yu, S., Yu, Y., Zadorozhnyy, S., Zalesak, J., Zhang, Y., and Zwaska, R.

Subjects

High Energy Physics - Experiment

Abstract

We report cross-section measurements of the final-state muon kinematics for \numu charged-current interactions in the NOvA near detector using an accumulated 8.09$\times10^{20}$ protons-on-target (POT) in the NuMI beam. We present the results as a double-differential cross section in the observed outgoing muon energy and angle, as well as single-differential cross sections in the derived neutrino energy, $E_\nu$, and square of the four-momentum transfer, $Q^2$. We compare the results to inclusive cross-section predictions from various neutrino event generators via $\chi^2$ calculations using a covariance matrix that accounts for bin-to-bin correlations of systematic uncertainties. These comparisons show a clear discrepancy between the data and each of the tested predictions at forward muon angle and low $Q^2$, indicating a missing suppression of the cross section in current neutrino-nucleus scattering models.

Published

2021

16. An Improved Measurement of Neutrino Oscillation Parameters by the NOvA Experiment

Author

Acero, M. A., Adamson, P., Aliaga, L., Anfimov, N., Antoshkin, A., Arrieta-Diaz, E., Asquith, L., Aurisano, A., Back, A., Backhouse, C., Baird, M., Balashov, N., Baldi, P., Bambah, B. A., Bashar, S., Bays, K., Bernstein, R., Bhatnagar, V., Bhattarai, D., Bhuyan, B., Bian, J., Blair, J., Booth, A. C., Bowles, R., Bromberg, C., Buchanan, N., Butkevich, A., Calvez, S., Carroll, T. J., Catano-Mur, E., Choudhary, B. C., Christensen, A., Coan, T. E., Colo, M., Cremonesi, L., Davies, G. S., Derwent, P. F., Ding, P., Djurcic, Z., Dolce, M., Doyle, D., Tonguino, D. Dueñas, Dukes, E. C., Duyang, H., Ehrlich, R., Elkins, M., Ewart, E., Feldman, G. J., Filip, P., Franc, J., Frank, M. J., Gallagher, H. R., Gandrajula, R., Gao, F., Giri, A., Gomes, R. A., Goodman, M. C., Grichine, V., Groh, M., Group, R., Guo, B., Habig, A., Hakl, F., Hall, A., Hartnell, J., Hatcher, R., Hausner, H., He, M., Heller, K., Hewes, V., Himmel, A., Holin, A., Huang, J., Jargowsky, B., Jarosz, J., Jediny, F., Johnson, C., Judah, M., Kakorin, I., Kaplan, D. M., Kalitkina, A., Keloth, R., Klimov, O., Koerner, L. W., Kolupaeva, L., Kotelnikov, S., Kralik, R., Kullenberg, Ch., Kubu, M., Kumar, A., Kuruppu, C. D., Kus, V., Lackey, T., Lang, K., Lasorak, P., Lesmeister, J., Lin, S., Lister, A., Liu, J., Lokajicek, M., Magill, S., Plata, M. Manrique, Mann, W. A., Marshak, M. L., Martinez-Casales, M., Matveev, V., Mayes, B., Méndez, D. P., Messier, M. D., Meyer, H., Miao, T., Miller, W. H., Mishra, S. R., Mislivec, A., Mohanta, R., Moren, A., Morozova, A., Mu, W., Mualem, L., Muether, M., Mufson, S., Mulder, K., Naples, D., Nayak, N., Nelson, J. K., Nichol, R., Niner, E., Norman, A., Norrick, A., Nosek, T., Oh, H., Olshevskiy, A., Olson, T., Ott, J., Paley, J., Patterson, R. B., Pawloski, G., Petrova, O., Petti, R., Phan, D. D., Plunkett, R. K., Porter, J. C. C., Rafique, A., Psihas, F., Raj, V., Rajaoalisoa, M., Ramson, B., Rebel, B., Rojas, P., Roy, P., Ryabov, V., Samoylov, O., Sanchez, M. C., Falero, S. Sánchez, Shanahan, P., Sheshukov, A., Singh, P., Singh, V., Smith, E., Smolik, J., Snopok, P., Solomey, N., Sousa, A., Soustruznik, K., Strait, M., Suter, L., Sutton, A., Swain, S., Sweeney, C., Sztuc, A., Talaga, R. L., Oregui, B. Tapia, Tas, P., Thakore, T., Thayyullathil, R. B., Thomas, J., Tiras, E., Tripathi, J., Trokan-Tenorio, J., Tsaris, A., Torun, Y., Urheim, J., Vahle, P., Vallari, Z., Vasel, J., Vokac, P., Vrba, T., Wallbank, M., Warburton, T. K., Wetstein, M., Whittington, D., Wickremasinghe, D. A., Wojcicki, S. G., Wolcott, J., Wu, W., Xiao, Y., Dombara, A. Yallappa, Yankelevich, A., Yonehara, K., Yu, S., Yu, Y., Zadorozhnyy, S., Zalesak, J., Zhang, Y., and Zwaska, R.

Subjects

High Energy Physics - Experiment

Abstract

We present new $\nu_\mu\rightarrow\nu_e$, $\nu_\mu\rightarrow\nu_\mu$, $\overline{\nu}_\mu\rightarrow\overline{\nu}_e$, and $\overline{\nu}_\mu\rightarrow\overline{\nu}_\mu$ oscillation measurements by the NOvA experiment, with a 50% increase in neutrino-mode beam exposure over the previously reported results. The additional data, combined with previously published neutrino and antineutrino data, are all analyzed using improved techniques and simulations. A joint fit to the $\nu_e$, $\nu_\mu$, $\overline{\nu}_e$, and $\overline{\nu}_\mu$ candidate samples within the 3-flavor neutrino oscillation framework continues to yield a best-fit point in the normal mass ordering and the upper octant of the $\theta_{23}$ mixing angle, with $\Delta m^{2}_{32} = (2.41\pm0.07)\times 10^{-3}$ eV$^2$ and $\sin^2\theta_{23} = 0.57^{+0.03}_{-0.04}$. The data disfavor combinations of oscillation parameters that give rise to a large asymmetry in the rates of $\nu_e$ and $\overline{\nu}_e$ appearance. This includes values of the CP-violating phase in the vicinity of $\delta_\text{CP} = \pi/2$ which are excluded by $>3\sigma$ for the inverted mass ordering, and values around $\delta_\text{CP} = 3\pi/2$ in the normal ordering which are disfavored at 2$\sigma$ confidence., Comment: 11 pages, 6 figures. Supplementary material attached (7 figures)

Published

2021

17. Extended search for supernova-like neutrinos in NOvA coincident with LIGO/Virgo detections

Author

Acero, M. A., Adamson, P., Aliaga, L., Anfimov, N., Antoshkin, A., Arrieta-Diaz, E., Asquith, L., Aurisano, A., Back, A., Backhouse, C., Baird, M., Balashov, N., Baldi, P., Bambah, B. A., Bashar, S., Bays, K., Bernstein, R., Bhatnagar, V., Bhuyan, B., Bian, J., Blair, J., Booth, A. C., Bowles, R., Bromberg, C., Buchanan, N., Butkevich, A., Calvez, S., Carroll, T. J., Catano-Mur, E., Choudhary, B. C., Christensen, A., Coan, T. E., Colo, M., Corwin, L., Cremonesi, L., Davies, G. S., Derwent, P. F., Ding, P., Djurcic, Z., Dolce, M., Doyle, D., Tonguino, D. Dueñas, Dukes, E. C., Duyang, H., Edayath, S., Ehrlich, R., Elkins, M., Ewart, E., Feldman, G. J., Filip, P., Franc, J., Frank, M. J., Gallagher, H. R., Gandrajula, R., Gao, F., Giri, A., Gomes, R. A., Goodman, M. C., Grichine, V., Groh, M., Group, R., Guo, B., Habig, A., Hakl, F., Hall, A., Hartnell, J., Hatcher, R., Hatzikoutelis, A., Hausner, H., Heller, K., Hewes, V, Himmel, A., Holin, A., Huang, J., Jargowsky, B., Jarosz, J., Jediny, F., Johnson, C., Judah, M., Kakorin, I., Kalra, D., Kaplan, D. M., Kalitkina, A., Keloth, R., Klimov, O., Koerner, L. W., Kolupaeva, L., Kotelnikov, S., Kralik, R., Kullenberg, Ch., Kubu, M., Kumar, A., Kuruppu, C. D., Kus, V., Lackey, T., Lang, K., Lasorak, P., Lesmeister, J., Lin, S., Lister, A., Liu, J., Lokajicek, M., Magill, S., Plata, M. Manrique, Mann, W. A., Marshak, M. L., Martinez-Casales, M., Matveev, V., Mayes, B., Méndez, D. P., Messier, M. D., Meyer, H., Miao, T., Miller, W. H., Mishra, S. R., Mislivec, A., Mohanta, R., Moren, A., Morozova, A., Mu, W., Mualem, L., Muether, M., Mufson, S., Mulder, K., Naples, D., Nayak, N., Nelson, J. K., Nichol, R., Niner, E., Norman, A., Norrick, A., Nosek, T., Oh, H., Olshevskiy, A., Olson, T., Ott, J., Paley, J., Patterson, R. B., Pawloski, G., Petrova, O., Petti, R., Phan, D. D., Plunkett, R. K., Porter, J. C. C., Rafique, A., Psihas, F., Raj, V., Rajaoalisoa, M., Ramson, B., Rebel, B., Rojas, P., Ryabov, V., Samoylov, O., Sanchez, M. C., Falero, S. Sánchez, Shanahan, P., Sheshukov, A., Singh, P., Singh, V., Smith, E., Smolik, J., Snopok, P., Solomey, N., Sousa, A., Soustruznik, K., Strait, M., Suter, L., Sutton, A., Swain, S., Sweeney, C., Oregui, B. Tapia, Tas, P., Thakore, T., Thayyullathil, R. B., Thomas, J., Tiras, E., Tripathi, J., Trokan-Tenorio, J., Tsaris, A., Torun, Y., Urheim, J., Vahle, P., Vallari, Z., Vasel, J., Vokac, P., Vrba, T., Wallbank, M., Warburton, T. K., Wetstein, M., Whittington, D., Wickremasinghe, D. A., Wojcicki, S. G., Wolcott, J., Wu, W., Xiao, Y., Dombara, A. Yallappa, Yonehara, K., Yu, S., Yu, Y., Zadorozhnyy, S., Zalesak, J., Zhang, Y., and Zwaska, R.

Subjects

High Energy Physics - Experiment, Astrophysics - High Energy Astrophysical Phenomena

Abstract

A search is performed for supernova-like neutrino interactions coincident with 76 gravitational wave events detected by the LIGO/Virgo Collaboration. For 40 of these events, full readout of the time around the gravitational wave is available from the NOvA Far Detector. For these events, we set limits on the fluence of the sum of all neutrino flavors of $F < 7(4)\times 10^{10}\mathrm{cm}^{-2}$ at 90% C.L. assuming energy and time distributions corresponding to the Garching supernova models with masses 9.6(27)$\mathrm{M}_\odot$. Under the hypothesis that any given gravitational wave event was caused by a supernova, this corresponds to a distance of $r > 29(50)$kpc at 90% C.L. Weaker limits are set for other gravitational wave events with partial Far Detector data and/or Near Detector data., Comment: 10 pages, 2 figures

Published

2021

18. Search for active-sterile antineutrino mixing using neutral-current interactions with the NOvA experiment

Author

Acero, M. A., Adamson, P., Aliaga, L., Anfimov, N., Antoshkin, A., Arrieta-Diaz, E., Asquith, L., Aurisano, A., Back, A., Backhouse, C., Baird, M., Balashov, N., Baldi, P., Bambah, B. A., Bashar, S., Bays, K., Bernstein, R., Bhatnagar, V., Bhuyan, B., Bian, J., Blair, J., Booth, A. C., Bowles, R., Bromberg, C., Buchanan, N., Butkevich, A., Calvez, S., Carroll, T. J., Catano-Mur, E., Choudhary, B. C., Christensen, A., Coan, T. E., Colo, M., Cremonesi, L., Davies, G. S., Derwent, P. F., Ding, P., Djurcic, Z., Dolce, M., Doyle, D., Tonguino, D. Dueñas, Dukes, E. C., Duyang, H., Edayath, S., Ehrlich, R., Elkins, M., Ewart, E., Feldman, G. J., Filip, P., Franc, J., Frank, M. J., Gallagher, H. R., Gandrajula, R., Gao, F., Giri, A., Gomes, R. A., Goodman, M. C., Grichine, V., Groh, M., Group, R., Guo, B., Habig, A., Hakl, F., Hall, A., Hartnell, J., Hatcher, R., Hausner, H., Heller, K., Hewes, V, Himmel, A., Holin, A., Huang, J., Jargowsky, B., Jarosz, J., Jediny, F., Johnson, C., Judah, M., Kakorin, I., Kalra, D., Kalitkina, A., Kaplan, D. M., Keloth, R., Klimov, O., Koerner, L. W., Kolupaeva, L., Kotelnikov, S., Kralik, R., Kullenberg, Ch., Kubu, M., Kumar, A., Kuruppu, C. D., Kus, V., Lackey, T., Lasorak, P., Lang, K., Lesmeister, J., Lin, S., Lister, A., Liu, J., Lokajicek, M., Magill, S., Plata, M. Manrique, Mann, W. A., Marshak, M. L., Martinez-Casales, M., Matveev, V., Mayes, B., Méndez, D. P., Messier, M. D., Meyer, H., Miao, T., Miller, W. H., Mishra, S. R., Mislivec, A., Mohanta, R., Moren, A., Morozova, A., Mu, W., Mualem, L., Muether, M., Mulder, K., Naples, D., Nayak, N., Nelson, J. K., Nichol, R., Niner, E., Norman, A., Norrick, A., Nosek, T., Oh, H., Olshevskiy, A., Olson, T., Ott, J., Paley, J., Patterson, R. B., Pawloski, G., Petrova, O., Petti, R., Phan, D. D., Plunkett, R. K., Porter, J. C. C., Rafique, A., Raj, V., Rajaoalisoa, M., Ramson, B., Rebel, B., Rojas, P., Ryabov, V., Samoylov, O., Sanchez, M. C., Falero, S. Sánchez, Shanahan, P., Sheshukov, A., Singh, P., Singh, V., Smith, E., Smolik, J., Snopok, P., Solomey, N., Sousa, A., Soustruznik, K., Strait, M., Suter, L., Sutton, A., Swain, S., Sweeney, C., Oregui, B. Tapia, Tas, P., Thakore, T., Thayyullathil, R. B., Thomas, J., Tiras, E., Tripathi, J., Trokan-Tenorio, J., Tsaris, A., Torun, Y., Urheim, J., Vahle, P., Vallari, Z., Vasel, J., Vokac, P., Vrba, T., Wallbank, M., Warburton, T. K., Wetstein, M., Whittington, D., Wickremasinghe, D. A., Wojcicki, S. G., Wolcott, J., Wu, W., Xiao, Y., Dombara, A. Yallappa, Yonehara, K., Yu, S., Yu, Y., Zadorozhnyy, S., Zalesak, J., Zhang, Y., and Zwaska, R.

Subjects

High Energy Physics - Experiment

Abstract

This Letter reports results from the first long-baseline search for sterile antineutrinos mixing in an accelerator-based antineutrino-dominated beam. The rate of neutral-current interactions in the two NOvA detectors, at distances of 1 km and 810 km from the beam source, is analyzed using an exposure of $12.51\times10^{20}$ protons-on-target from the NuMI beam at Fermilab running in antineutrino mode. A total of $121$ of neutral-current candidates are observed at the Far Detector, compared to a prediction of $122\pm11$(stat.)$\pm15$(syst.) assuming mixing between three active flavors. No evidence for $\bar{\nu}_{\mu}\rightarrow\bar{\nu}_{s}$ oscillation is observed. Interpreting this result within a 3+1 model, constraints are placed on the mixing angles ${\theta}_{24} < 25^{\circ}$ and ${\theta}_{34} < 32^{\circ}$ at the 90% C.L. for $0.05$eV$^{2} \leq \Delta m^{2}_{41} \leq 0.5$eV$^{2}$, the range of mass splittings that produces no significant oscillations at the Near Detector. These are the first 3+1 confidence limits set using long-baseline accelerator antineutrinos., Comment: 8 pages, 4 figures

Published

2021

19. Search for Slow Magnetic Monopoles with the NOvA Detector on the Surface

Author

NOvA Collaboration, Acero, M. A., Adamson, P., Aliaga, L., Alion, T., Allakhverdian, V., Anfimov, N., Antoshkin, A., Arrieta-Diaz, E., Asquith, L., Aurisano, A., Back, A., Backhouse, C., Baird, M., Balashov, N., Baldi, P., Bambah, B. A., Bashar, S., Bays, K., Bending, S., Bernstein, R., Bhatnagar, V., Bhuyan, B., Bian, J., Blair, J., Booth, A. C., Bour, P., Bowles, R., Bromberg, C., Buchanan, N., Butkevich, A., Calvez, S., Carroll, T. J., Catano-Mur, E., Childress, S., Choudhary, B. C., Coan, T. E., Colo, M., Corwin, L., Cremonesi, L., Davies, G. S., Derwent, P. F., Ding, P., Djurcic, Z., Dolce, M., Doyle, D., Tonguino, D. Dueñas, Dung, P., Dukes, E. C., Duyang, H., Edayath, S., Ehrlich, R., Elkins, M., Feldman, G. J., Filip, P., Flanagan, W., Franc, J., Frank, M. J., Gallagher, H. R., Gandrajula, R., Gao, F., Germani, S., Giri, A., Gomes, R. A., Goodman, M. C., Grichine, V., Groh, M., Group, R., Guo, B., Habig, A., Hakl, F., Hall, A., Hartnell, J., Hatcher, R., Heller, K., Hewes, V, Himmel, A., Holin, A., Huang, J., Hylen, J., Jarosz, J., Jediny, F., Johnson, C., Judah, M., Kakorin, I., Kalra, D., Kaplan, D. M., Keloth, R., Klimov, O., Koerner, L. W., Kolupaeva, L., Kotelnikov, S., Kullenberg, Ch., Kubu, M., Kumar, A., Kuruppu, C. D., Kus, V., Lackey, T., Lang, K., Li, L., Lin, S., Lister, A., Lokajicek, M., Luchuk, S., Magill, S., Mann, W. A., Marshak, M. L., Martinez-Casales, M., Matveev, V., Mayes, B., Méndez, D. P., Messier, M. D., Meyer, H., Miao, T., Miller, W. H., Mishra, S. R., Mislivec, A., Mohanta, R., Moren, A., Morozova, A., Mualem, L., Muether, M., Mufson, S., Mulder, K., Murphy, R., Musser, J., Naples, D., Nayak, N., Nelson, J. K., Nichol, R., Niner, E., Norman, A., Norrick, A., Nosek, T., Olshevskiy, A., Olson, T., Paley, J., Patterson, R. B., Pawloski, G., Petrova, O., Petti, R., Plunkett, R. K., Rafique, A., Raj, V., Ramson, B., Rebel, B., Rojas, P., Ryabov, V., Samoylov, O., Sanchez, M. C., Falero, S. Sánchez, Shanahan, P., Sheshukov, A., Singh, P., Singh, V., Smith, E., Smolik, J., Snopok, P., Solomey, N., Song, E., Sousa, A., Soustruznik, K., Strait, M., Suter, L., Sutton, A., Swain, S., Sweeney, C., Oregui, B. Tapia, Tas, P., Thayyullathil, R. B., Thomas, J., Tiras, E., Torbunov, D., Tripathi, J., Trokan-Tenorio, J., Torun, Y., Urheim, J., Vahle, P., Vallari, Z., Vasel, J., Vokac, P., Vrba, T., Wallbank, M., Wang, Z., Warburton, T. K., Wetstein, M., Whittington, D., Wickremasinghe, D. A., Wojcicki, S. G., Wolcott, J., Xiao, Y., Dombara, A. Yallappa, Yonehara, K., Yu, S., Yu, Y., Zadorozhnyy, S., Zalesak, J., Zhang, Y., and Zwaska, R.

Subjects

High Energy Physics - Experiment, Astrophysics - High Energy Astrophysical Phenomena, Physics - Instrumentation and Detectors

Abstract

We report a search for a magnetic monopole component of the cosmic-ray flux in a 95-day exposure of the NOvA experiment's Far Detector, a 14 kt segmented liquid scintillator detector designed primarily to observe GeV-scale electron neutrinos. No events consistent with monopoles were observed, setting an upper limit on the flux of $2\times 10^{-14} \mathrm{cm^{-2}s^{-1}sr^{-1}}$ at 90% C.L. for monopole speed $6\times 10^{-4} < \beta < 5\times 10^{-3}$ and mass greater than $5\times 10^{8}$ GeV. Because of NOvA's small overburden of 3 meters-water equivalent, this constraint covers a previously unexplored low-mass region., Comment: 8 pages, 7 figures

Published

2020

20. Adjusting Neutrino Interaction Models and Evaluating Uncertainties using NOvA Near Detector Data

Author

NOvA Collaboration, Acero, M. A., Adamson, P., Agam, G., Aliaga, L., Alion, T., Allakhverdian, V., Anfimov, N., Antoshkin, A., Asquith, L., Aurisano, A., Back, A., Backhouse, C., Baird, M., Balashov, N., Baldi, P., Bambah, B. A., Bashar, S., Bays, K., Bending, S., Bernstein, R., Bhatnagar, V., Bhuyan, B., Bian, J., Blair, J., Booth, A. C., Bour, P., Bowles, R., Bromberg, C., Buchanan, N., Butkevich, A., Calvez, S., Carroll, T. J., Catano-Mur, E., Childress, S., Choudhary, B. C., Coan, T. E., Colo, M., Corwin, L., Cremonesi, L., Davies, G. S., Derwent, P. F., Ding, P., Djurcic, Z., Doyle, D., Dukes, E. C., Dung, P., Duyang, H., Edayath, S., Ehrlich, R., Elkins, M., Feldman, G. J., Filip, P., Flanagan, W., Franc, J., Frank, M. J., Gallagher, H. R., Gandrajula, R., Gao, F., Germani, S., Giri, A., Gomes, R. A., Goodman, M. C., Grichine, V., Groh, M., Group, R., Guo, B., Habig, A., Hakl, F., Hartnell, J., Hatcher, R., Hatzikoutelis, A., Heller, K., Hewes, V, Himmel, A., Holin, A., Howard, B., Huang, J., Hylen, J., Jediny, F., Johnson, C., Judah, M., Kakorin, I., Kalra, D., Kaplan, D. M., Keloth, R., Klimov, O., Koerner, L. W., Kolupaeva, L., Kotelnikov, S., Kullenberg, Ch., Kumar, A., Kuruppu, C. D., Kus, V., Lackey, T., Lang, K., Li, L., Lin, S., Lokajicek, M., Luchuk, S., Maan, K., Magill, S., Mann, W. A., Marshak, M. L., Martinez-Casales, M., Matveev, V., Mayes, B., Méndez, D. P., Messier, M. D., Meyer, H., Miao, T., Miller, W. H., Mishra, S. R., Mislivec, A., Mohanta, R., Moren, A., Morozova, A., Mualem, L., Muether, M., Mufson, S., Mulder, K., Murphy, R., Musser, J., Naples, D., Nayak, N., Nelson, J. K., Nichol, R., Nikseresht, G., Niner, E., Norman, A., Norrick, A., Nosek, T., Olshevskiy, A., Olson, T., Paley, J., Patterson, R. B., Pawloski, G., Petrova, O., Petti, R., Plunkett, R. K., Rafique, A., Psihas, F., Radovic, A., Raj, V., Ramson, B., Rebel, B., Rojas, P., Ryabov, V., Samoylov, O., Sanchez, M. C., Falero, S. Sánchez, Seong, I. S., Shanahan, P., Sheshukov, A., Singh, P., Singh, V., Smith, E., Smolik, J., Snopok, P., Solomey, N., Sousa, A., Soustruznik, K., Strait, M., Suter, L., Sutton, A., Sweeney, C., Talaga, R. L., Oregui, B. Tapia, Tas, P., Thayyullathil, R. B., Thomas, J., Tiras, E., Torbunov, D., Tripathi, J., Torun, Y., Urheim, J., Vahle, P., Vallari, Z., Vasel, J., Vokac, P., Vrba, T., Wallbank, M., Warburton, T. K., Wetstein, M., Whittington, D., Wojcicki, S. G., Wolcott, J., Dombara, A. Yallappa, Yonehara, K., Yu, S., Yu, Y., Zadorozhnyy, S., Zalesak, J., Zhang, Y., and Zwaska, R.

Subjects

High Energy Physics - Experiment

Abstract

The two-detector design of the NOvA neutrino oscillation experiment, in which two functionally identical detectors are exposed to an intense neutrino beam, aids in canceling leading order effects of cross-section uncertainties. However, limited knowledge of neutrino interaction cross sections still gives rise to some of the largest systematic uncertainties in current oscillation measurements. We show contemporary models of neutrino interactions to be discrepant with data from NOvA, consistent with discrepancies seen in other experiments. Adjustments to neutrino interaction models in GENIE that improve agreement with our data are presented. We also describe systematic uncertainties on these models, including uncertainties on multi-nucleon interactions from a newly developed procedure using NOvA near detector data., Comment: Code implementing adjustments to GENIE 2.12.2 described in this paper is available at https://github.com/novaexperiment/NOvARwgt-public

Published

2020

21. Supernova neutrino detection in NOvA

Author

NOvA Collaboration, Acero, M. A., Adamson, P., Agam, G., Aliaga, L., Alion, T., Allakhverdian, V., Anfimov, N., Antoshkin, A., Arrieta-Diaz, E., Asquith, L., Aurisano, A., Back, A., Backhouse, C., Baird, M., Balashov, N., Baldi, P., Bambah, B. A., Bashar, S., Bays, K., Bending, S., Bernstein, R., Bhatnagar, V., Bhuyan, B., Bian, J., Blair, J., Booth, A. C., Bour, P., Bowles, R., Bromberg, C., Buchanan, N., Butkevich, A., Bychkov, V., Calvez, S., Carroll, T. J., Catano-Mur, E., Childress, S., Choudhary, B. C., Coan, T. E., Colo, M., Corwin, L., Cremonesi, L., Davies, G. S., Derwent, P. F., Ding, P., Djurcic, Z., Dolce, M., Doyle, D., Tonguino, D. Dueñas, Dukes, E. C., Dung, P., Duyang, H., Edayath, S., Ehrlich, R., Elkins, M., Feldman, G. J., Filip, P., Flanagan, W., Franc, J., Frank, M. J., Gallagher, H. R., Gandrajula, R., Gao, F., Germani, S., Giri, A., Gomes, R. A., Goodman, M. C., Grichine, V., Groh, M., Group, R., Guo, B., Habig, A., Hakl, F., Hall, A., Hartnell, J., Hatcher, R., Hatzikoutelis, A., Heller, K., Hewes, V, Himmel, A., Holin, A., Howard, B., Huang, J., Hylen, J., Jediny, F., Johnson, C., Judah, M., Kakorin, I., Kalra, D., Kaplan, D. M., Keloth, R., Klimov, O., Koerner, L. W., Kolupaeva, L., Kotelnikov, S., Kubu, M., Kullenberg, Ch., Kumar, A., Kuruppu, C. D., Kus, V., Lackey, T., Lang, K., Li, L., Lin, S., Lister, A., Lokajicek, M., Luchuk, S., Magill, S., Mann, W. A., Marshak, M. L., Martinez-Casales, M., Matveev, V., Mayes, B., Méndez, D. P., Messier, M. D., Meyer, H., Miao, T., Miller, W. H., Mishra, S. R., Mislivec, A., Mohanta, R., Moren, A., Morozova, A., Mualem, L., Muether, M., Mufson, S., Mulder, K., Murphy, R., Musser, J., Naples, D., Nayak, N., Nelson, J. K., Nichol, R., Nikseresht, G., Niner, E., Norman, A., Norrick, A., Nosek, T., Olshevskiy, A., Olson, T., Paley, J., Patterson, R. B., Pawloski, G., Petrova, O., Petti, R., Plunkett, R. K., Psihas, F., Rafique, A., Raj, V., Ramson, B., Rebel, B., Rojas, P., Ryabov, V., Samoylov, O., Sanchez, M. C., Falero, S. Sánchez, Seong, I. S., Shanahan, P., Sheshukov, A., Singh, P., Singh, V., Smith, E., Smolik, J., Snopok, P., Solomey, N., Sousa, A., Soustruznik, K., Strait, M., Suter, L., Sutton, A., Sweeney, C., Talaga, R. L., Oregui, B. Tapia, Tas, P., Thayyullathil, R. B., Thomas, J., Tiras, E., Torbunov, D., Tripathi, J., Tsaris, A., Torun, Y., Urheim, J., Vahle, P., Vallari, Z., Vasel, J., Vokac, P., Vrba, T., Wallbank, M., Warburton, T. K., Wetstein, M., Whittington, D., Wickremasinghe, D. A., Wojcicki, S. G., Wolcott, J., Dombara, A. Yallappa, Yonehara, K., Yu, S., Yu, Y., Zadorozhnyy, S., Zalesak, J., Zhang, Y., and Zwaska, R.

Subjects

Physics - Instrumentation and Detectors, High Energy Physics - Experiment

Abstract

The NOvA long-baseline neutrino experiment uses a pair of large, segmented, liquid-scintillator calorimeters to study neutrino oscillations, using GeV-scale neutrinos from the Fermilab NuMI beam. These detectors are also sensitive to the flux of neutrinos which are emitted during a core-collapse supernova through inverse beta decay interactions on carbon at energies of $\mathcal{O}(10~\text{MeV})$. This signature provides a means to study the dominant mode of energy release for a core-collapse supernova occurring in our galaxy. We describe the data-driven software trigger system developed and employed by the NOvA experiment to identify and record neutrino data from nearby galactic supernovae. This technique has been used by NOvA to self-trigger on potential core-collapse supernovae in our galaxy, with an estimated sensitivity reaching out to 10~kpc distance while achieving a detection efficiency of 23\% to 49\% for supernovae from progenitor stars with masses of 9.6\~M$_\odot$ to 27\~M$_\odot$, respectively., Comment: 30 pages, 17 figures

Published

2020

22. Investigation of the Stability of the Luminescent Characteristics of Phosphors of Different Nature Under the Climatic Conditions of South-East Asia

Author

Runina, K. I., Avetisov, R. I., Petrova, O. B., Avetisov, I. Kh., Do, D. T., and Ta, T. T.

Published

2023

23. Obtaining a New Film Scintillator Based on (8-oxyquinolate) Lithium: An Overview

Author

Runina, K. I., Zykova, S. S., Strekalov, P. V., Popkova, L. V., Petrova, O. B., Chepurnov, A. S., Do, D. Ch., and Ta, T. Ch.

Published

2023

24. Search for multi-messenger signals in NOvA coincident with LIGO/Virgo detections

Author

NOvA Collaboration, Acero, M. A., Adamson, P., Aliaga, L., Alion, T., Allakhverdian, V., Anfimov, N., Antoshkin, A., Asquith, L., Aurisano, A., Back, A., Backhouse, C., Baird, M., Balashov, N., Baldi, P., Bambah, B. A., Bashar, S., Bays, K., Bending, S., Bernstein, R., Bhatnagar, V., Bhuyan, B., Bian, J., Blair, J., Booth, A. C., Bour, P., Bromberg, C., Buchanan, N., Butkevich, A., Calvez, S., Carroll, T. J., Catano-Mur, E., Childress, S., Choudhary, B. C., Coan, T. E., Colo, M., Corwin, L., Cremonesi, L., Davies, G. S., Derwent, P. F., Dharmapalan, R., Ding, P., Djurcic, Z., Doyle, D., Dukes, E. C., Duyang, H., Edayath, S., Ehrlich, R., Feldman, G. J., Filip, P., Flanagan, W., Frank, M. J., Gallagher, H. R., Gandrajula, R., Gao, F., Germani, S., Giri, A., Gomes, R. A., Goodman, M. C., Grichine, V., Groh, M., Group, R., Guo, B., Habig, A., Hakl, F., Hartnell, J., Hatcher, R., Heller, K., Hewes, V, Himmel, A., Holin, A., Hylen, J., Jediny, F., Johnson, C., Judah, M., Kakorin, I., Kalra, D., Kaplan, D. M., Keloth, R., Klimov, O., Koerner, L. W., Kolupaeva, L., Kotelnikov, S., Kullenberg, Ch., Kumar, A., Kuruppu, C. D., Kus, V., Lackey, T., Lang, K., Li, L., Lin, S., Lokajicek, M., Luchuk, S., Magill, S., Mann, W. A., Marshak, M. L., Martinez-Casales, M., Matveev, V., Mayes, B., Méndez, D. P., Messier, M. D., Meyer, H., Miao, T., Miller, W. H., Mishra, S. R., Mislivec, A., Mohanta, R., Moren, A., Mualem, L., Muether, M., Mufson, S., Mulder, K., Murphy, R., Musser, J., Naples, D., Nayak, N., Nelson, J. K., Nichol, R., Niner, E., Norman, A., Norrick, A., Nosek, T., Olshevskiy, A., Olson, T., Paley, J., Patterson, R. B., Pawloski, G., Petrova, O., Petti, R., Plunkett, R. K., Rafique, A., Psihas, F., Raj, V., Rebel, B., Rojas, P., Ryabov, V., Samoylov, O., Sanchez, M. C., Falero, S. Sánchez, Shanahan, P., Sheshukov, A., Singh, P., Singh, V., Smith, E., Smolik, J., Snopok, P., Solomey, N., Sousa, A., Soustruznik, K., Strait, M., Suter, L., Sutton, A., Talaga, R. L., Oregui, B. Tapia, Tas, P., Thayyullathil, R. B., Thomas, J., Tiras, E., Torbunov, D., Tripathi, J., Torun, Y., Urheim, J., Vahle, P., Vasel, J., Vokac, P., Vrba, T., Wallbank, M., Warburton, T. K., Wetstein, M., Whittington, D., Wojcicki, S. G., Wolcott, J., Dombara, A. Yallappa, Yonehara, K., Yu, S., Yu, Y., Zadorozhnyy, S., Zalesak, J., Zhang, Y., and Zwaska, R.

Subjects

High Energy Physics - Experiment, Astrophysics - High Energy Astrophysical Phenomena

Abstract

Using the NOvA neutrino detectors, a broad search has been performed for any signal coincident with 28 gravitational wave events detected by the LIGO/Virgo Collaboration between September 2015 and July 2019. For all of these events, NOvA is sensitive to possible arrival of neutrinos and cosmic rays of GeV and higher energies. For five (seven) events in the NOvA Far (Near) Detector, timely public alerts from the LIGO/Virgo Collaboration allowed recording of MeV-scale events. No signal candidates were found., Comment: 11 pages, 6 figures; Corrected fluence limits

Published

2020

25. First measurement of neutrino oscillation parameters using neutrinos and antineutrinos by NOvA

Author

Acero, M. A., Adamson, P., Aliaga, L., Alion, T., Allakhverdian, V., Altakarli, S., Anfimov, N., Antoshkin, A., Aurisano, A., Back, A., Backhouse, C., Baird, M., Balashov, N., Baldi, P., Bambah, B. A., Bashar, S., Bays, K., Bending, S., Bernstein, R., Bhatnagar, V., Bhuyan, B., Bian, J., Blackburn, T., Blair, J., Booth, A. C., Bour, P., Bromberg, C., Buchanan, N., Butkevich, A., Calvez, S., Campbell, M., Carroll, T. J., Catano-Mur, E., Cedeno, A., Childress, S., Choudhary, B. C., Chowdhury, B., Coan, T. E., Colo, M., Cooper, J., Corwin, L., Cremonesi, L., Davies, G. S., Derwent, P. F., Ding, P., Djurcic, Z., Doyle, D., Dukes, E. C., Duyang, H., Edayath, S., Ehrlich, R., Elkins, M., Feldman, G. J., Filip, P., Flanagan, W., Frank, M. J., Gallagher, H. R., Gandrajula, R., Gao, F., Germani, S., Giri, A., Gomes, R. A., Goodman, M. C., Grichine, V., Groh, M., Group, R., Guo, B., Habig, A., Hakl, F., Hartnell, J., Hatcher, R., Hatzikoutelis, A., Heller, K., Hewes, V, Himmel, A., Holin, A., Howard, B., Huang, J., Hylen, J., Jediny, F., Johnson, C., Judah, M., Kakorin, I., Kalra, D., Kaplan, D. M., Keloth, R., Klimov, O., Koerner, L. W., Kolupaeva, L., Kotelnikov, S., Kreymer, A., Kulenberg, Ch., Kumar, A., Kuruppu, C. D., Kus, V., Lackey, T., Lang, K., Lin, S., Lokajicek, M., Lozier, J., Luchuk, S., Maan, K., Magill, S., Mann, W. A., Marshak, M. L., Martinez-Casales, M., Matveev, V., Mendez, D. P., Messier, M. D., Meyer, H., Miao, T., Miller, W. H., Mishra, S. R., Mislivec, A., Mohanta, R., Moren, A., Mualem, L., Muether, M., Mufson, S., Mulder, K., Murphy, R., Musser, J., Naples, D., Nayak, N., Nelson, J. K., Nichol, R., Nikseresht, G., Niner, E., Norman, A., Nosek, T., Olshevskiy, A., Olson, T., Paley, J., Patterson, R. B., Pawloski, G., Pershey, D., Petrova, O., Petti, R., Phan, D. D., Plunkett, R. K., Potukuchi, B., Principato, C., Psihas, F., Radovic, A., Raj, V., Rameika, R. A., Rebel, B., Rojas, P., Ryabov, V., Samoylov, O., Sanchez, M. C., Falero, S. Sanchez, Seong, I. S., Shanahan, P., Sheshukov, A., Singh, P., Singh, V., Smith, E., Smolik, J., Snopok, P., Solomey, N., Song, E., Sousa, A., Soustruznik, K., Strait, M., Suter, L., Sutton, A., Talaga, R. L., Oregui, B. Tapia, Tas, P., Thayyullathil, R. B., Thomas, J., Tiras, E., Torbunov, D., Tripathi, J., Tsaris, A., Torun, Y., Urheim, J., Vahle, P., Vasel, J., Vinton, L., Vokac, P., Vrba, T., Wallbank, M., Wang, B., Warburton, T. K., Wetstein, M., While, M., Whittington, D., Wojcicki, S. G., Wolcott, J., Yadav, N., Dombara, A. Yallappa, Yonehara, K., Yu, S., Zadorozhnyy, S., Zalesak, J., Zamorano, B., and Zwaska, R.

Subjects

High Energy Physics - Experiment

Abstract

The NOvA experiment has made a $4.4\sigma$-significant observation of $\bar\nu_{e}$ appearance in a 2 GeV $\bar\nu_{\mu}$ beam at a distance of 810 km. Using $12.33\times10^{20}$ protons on target delivered to the Fermilab NuMI neutrino beamline, the experiment recorded 27 $\bar\nu_{\mu} \rightarrow \bar\nu_{e}$ candidates with a background of 10.3 and 102 $\bar\nu_{\mu} \rightarrow \bar\nu_{\mu}$ candidates. This new antineutrino data is combined with neutrino data to measure the oscillation parameters $|\Delta m^2_{32}| = 2.48^{+0.11}_{-0.06}\times10^{-3}$ eV$^2/c^4$, $\sin^2 \theta_{23} = 0.56^{+0.04}_{-0.03}$ in the normal neutrino mass hierarchy and upper octant and excludes most values near $\delta_{\rm CP}=\pi/2$ for the inverted mass hierarchy by more than 3$\sigma$. The data favor the normal neutrino mass hierarchy by 1.9$\sigma$ and $\theta_{23}$ values in the upper octant by 1.6$\sigma$., Comment: 8 pages, 3 figures. Supplementary material attached (6 figures). To view attachments, please download and extract the gzipped tar source file listed under "Other formats". Fixed supplementary material to include just the compiled pdf not the Latex Source

Published

2019

26. Observation of seasonal variation of atmospheric multiple-muon events in the NOvA Near Detector

Author

Acero, M. A., Adamson, P., Aliaga, L., Alion, T., Allakhverdian, V., Altakarli, S., Anmov, N., Antoshkin, A., Aurisano, A., Back, A., Backhouse, C., Baird, M., Balashov, N., Baldi, P., Bambah, B. A., Bashar, S., Bays, K., Bending, S., Bernstein, R., Bhatnagar, V., Bhuyan, B., Bian, J., Blair, J., Booth, A. C., Bour, P., Bromberg, C., Buchanan, N., Butkevich, A., Calvez, S., Campbell, M., Carroll, T. J., Catano-Mur, E., Cedeno, A., Childress, S., Choudhary, B. C., Chowdhury, B., Coan, T. E., Colo, M., Corwin, L., Cremonesi, L., Davies, G. S., Derwent, P. F., Ding, P., Djurcic, Z., Doyle, D., Dukes, E. C., Duyang, H., Edayath, S., Ehrlich, R., Feldman, G. J., Filip, P., Flanagan, W., Frank, M. J., Gallagher, H. R., Gandrajula, R., Gao, F., Germani, S., Giri, A., Gomes, R. A., Goodman, M. C., Grichine, V., Groh, M., Group, R., Guo, B., Habig, A., Hakl, F., Hartnell, J., Hatcher, R., Hatzikoutelis, A., Heller, K., Hewes, V, Himmel, A., Holin, A., Howard, B., Huang, J., Hylen, J., Jediny, F., Johnson, C., Judah, M., Kakorin, I., Kalra, D., Kaplan, D. M., Keloth, R., Klimov, O., Koerner, L. W., Kolupaeva, L., Kotelnikov, S., Kreymer, A., Kulenberg, Ch., Kumar, A., Kuruppu, C. D., Kus, V., Lackey, T., Lang, K., Lin, S., Lokajicek, M., Lozier, J., Luchuk, S., Magill, S., Mann, W. A., Marshak, M. L., Matveev, V., Mendez, D. P., Messier, M. D., Meyer, H., Miao, T., Miller, W. H., Mishra, S. R., Mislivec, A., Mohanta, R., Moren, A., Mualem, L., Muether, M., Mufson, S., Mulder, K., Murphy, R., Musser, J., Naples, D., Nayak, N., Nelson, J. K., Nichol, R., Nikseresht, G., Niner, E., Norman, A., Nosek, T., Olshevskiy, A., Olson, T., Paley, J., Patterson, R. B., Pawloski, G., Petrova, O., Petti, R., Phan, D. D., Plunkett, R. K., Potukuchi, B., Principato, C., Psihas, F., Raj, V., Rameika, R. A., Rebel, B., Rojas, P., Ryabov, V., Samoylov, O., Sanchez, M. C., Schreiner, P., Seong, I. S., Shanahan, P., Sheshukov, A., Singh, P., Singh, V., Smith, E., Smolik, J., Snopok, P., Solomey, N., Song, E., Sousa, A., Soustruznik, K., Strait, M., Suter, L., Sutton, A., Talaga, R. L., Tas, P., Thayyullathil, R. B., Thomas, J., Tiras, E., Tognini, S. C., Torbunov, D., Tripathi, J., Tsaris, A., Torun, Y., Urheim, J., Vahle, P., Vasel, J., Vinton, L., Vokac, P., Vrba, T., Wallbank, M., Wang, B., Warburton, T. K., Wetstein, M., While, M., Whittington, D., Wojcicki, S. G., Wolcott, J., Yadav, N., Dombara, A. Yallappa, Yonehara, K., Yu, S., Zadorozhnyy, S., Zalesak, J., and Zwaska, R.

Subjects

Physics - Instrumentation and Detectors, Astrophysics - Earth and Planetary Astrophysics, Astrophysics - Instrumentation and Methods for Astrophysics

Abstract

Using two years of data from the NOvA Near Detector at Fermilab, we report a seasonal variation of cosmic ray induced multiple-muon event rates which has an opposite phase to the seasonal variation in the atmospheric temperature. The strength of the seasonal multipl$ increase as a function of the muon multiplicity. However, no significant dependence of the strength of the seasonal variation of the multiple-muon variation is seen as a function of the muon zenith angle, or the spatial or angular separation between the correlated muons.

Published

2019

27. Synthesis and Luminescence Properties of Neodymium-Doped Oxochloride Lead Silicate Glasses

Author

Butenkov, D. A., Slastuhina, A. M., Runina, K. I., Grishechkin, M. B., Petrova, O. B., and Levonovich, B. N.

Published

2023

28. Measurement of Neutrino-Induced Neutral-Current Coherent $\pi^0$ Production in the NOvA Near Detector

Author

Acero, M. A., Adamson, P., Aliaga, L., Alion, T., Allakhverdian, V., Anfimov, N., Antoshkin, A., Arrieta-Diaz, E., Aurisano, A., Back, A., Backhouse, C., Baird, M., Balashov, N., Baldi, P., Bambah, B. A., Basher, S., Bays, K., Behera, B., Bending, S., Bernstein, R., Bhatnagar, V., Bhuyan, B., Bian, J., Blair, J., Booth, A. C., Bolshakova, A., Bour, P., Bromberg, C., Buchanan, N., Butkevich, A., Campbell, M., Carroll, T. J., Catano-Mur, E., Childress, S., Choudhary, B. C., Chowdhury, B., Coan, T. E., Colo, M., Corwin, L., Cremonesi, L., Cronin-Hennessy, D., Davies, G. S., Derwent, P. F., Ding, P., Djurcic, Z., Doyle, D., Dukes, E. C., Dung, P., Duyang, H., Edayath, S., Ehrlich, R., Feldman, G. J., Flanagan, W., Frank, M. J., Gallagher, H. R., Gandrajula, R., Gao, F., Germani, S., Giri, A., Gomes, R. A., Goodman, M. C., Grichine, V., Groh, M., Group, R., Guo, B., Habig, A., Hakl, F., Hartnell, J., Hatcher, R., Hatzikoutelis, A., Heller, K., Himmel, A., Holin, A., Howard, B., Huang, J., Hylen, J., Jediny, F., Johnson, C., Judah, M., Kakorin, I., Kalra, D., Kaplan, D. M., Keloth, R., Klimov, O., Koerner, L. W., Kolupaeva, L., Kotelnikov, S., Kreymer, A., Kulenberg, Ch., Kumar, A., Kuruppu, C. D., Kus, V., Lackey, T., Lang, K., Lin, S., Lokajicek, M., Lozier, J., Luchuk, S., Maan, K., Magill, S., Mann, W. A., Marshak, M. L., Matveev, V., Méndez, D. P., Messier, M. D., Meyer, H., Miao, T., Miller, W. H., Mishra, S. R., Mislivec, A., Mohanta, R., Moren, A., Mualem, L., Muether, M., Mulder, K., Mufson, S., Murphy, R., Musser, J., Naples, D., Nayak, N., Nelson, J. K., Nichol, R., Niner, E., Norman, A., Nosek, T., Oksuzian, Y., Olshevskiy, A., Olson, T., Paley, J., Patterson, R. B., Pawloski, G., Pershey, D., Petrova, O., Petti, R., Plunkett, R. K., Potukuchi, B., Principato, C., Psihas, F., Raj, V., Radovic, A., Rameika, R. A., Rebel, B., Rojas, P., Ryabov, V., Sachdev, K., Samoylov, O., Sanchez, M. C., Seong, I. S., Shanahan, P., Sheshukov, A., Singh, P., Singh, V., Smith, E., Smolik, J., Snopok, P., Solomey, N., Song, E., Sousa, A., Soustruznik, K., Strait, M., Suter, L., Talaga, R. L., Tas, P., Thayyullathil, R. B., Thomas, J., Tiras, E., Torbunov, D., Tripathi, J., Tsaris, A., Torun, Y., Urheim, J., Vahle, P., Vasel, J., Vinton, L., Vokac, P., Vrba, T., Wang, B., Warburton, T. K., Wetstein, M., While, M., Whittington, D., Wojcicki, S. G., Wolcott, J., Yadav, N., Dombara, A. Yallappa, Yang, S., Yonehara, K., Yu, S., Zalesak, J., Zamorano, B., and Zwaska, R.

Subjects

High Energy Physics - Experiment

Abstract

The cross section of neutrino-induced neutral-current coherent $\pi^0$ production on a carbon-dominated target is measured in the NOvA near detector. This measurement uses a narrow-band neutrino beam with an average neutrino energy of 2.7\,GeV, which is of interest to ongoing and future long-baseline neutrino oscillation experiments. The measured, flux-averaged cross section is $\sigma = 13.8\pm0.9 (\text{stat})\pm2.3 (\text{syst}) \times 10^{-40}\,\text{cm}^2/\text{nucleus}$, consistent with model prediction. This result is the most precise measurement of neutral-current coherent $\pi^0$ production in the few-GeV neutrino energy region.

Published

2019

29. Luminescent Silica Aerogels Doped by Coordination Compound of Boron with 8-Hydroxyquinoline

Author

Suslova, E. N., Kaz’mina, K. V., Runina, K. I., Kunaev, D. A., Lebedev, A. E., Petrova, O. B., Menshutina, N. V., and Avetisov, I. Kh.

Published

2022

30. Structure and Optical Properties of ZrO2–Sc2O3 Solid Solution System Obtained by the Coprecipitation Method.

Author

Danilov, V. P., Borisova, E. S., Shukshin, V. E., Runina, K. I., Strekalov, P. V., Mayakova, M. N., and Petrova, O. B.

Subjects

RARE earth oxides, PHYSICAL & theoretical chemistry, ZIRCONIUM oxide, RAMAN scattering, HEAT treatment

Abstract

The structure of ZrO2–Sc2O3 powders in the composition range from 1 to 15 mol.% of Sc2O3 with the addition of 0.1 mol.% Eu2O3 as a spectroscopic probe was studied. The powders were obtained by the coprecipitation method and subsequent heat treatment at temperatures ranging from 500 to 1200°C. The crystal structure was identified through x-ray diffraction analysis (XRD) and Raman spectroscopy. The local structure was evaluated based on the spectral and luminescent properties of the Eu3+ ion in the powder samples. [ABSTRACT FROM AUTHOR]

Published

2025

31. Search for active-sterile neutrino mixing using neutral-current interactions in NOvA

Author

NOvA Collaboration, Adamson, P., Aliaga, L., Ambrose, D., Anfimov, N., Antoshkin, A., Arrieta-Diaz, E., Augsten, K., Aurisano, A., Backhouse, C., Baird, M., Bambah, B. A., Bays, K., Behera, B., Bending, S., Bernstein, R., Bhatnagar, V., Bhuyan, B., Bian, J., Blackburn, T., Bolshakova, A., Bromberg, C., Brown, J., Brunetti, G., Buchanan, N., Butkevich, A., Bychkov, V., Campbell, M., Catano-Mur, E., Childress, S., Choudhary, B. C., Chowdhury, B., Coan, T. E., Coelho, J. A. B., Colo, M., Cooper, J., Corwin, L., Cremonesi, L., Cronin-Hennessy, D., Davies, G. S., Davies, J. P., Derwent, P. F., Dharmapalan, R., Ding, P., Djurcic, Z., Dukes, E. C., Duyang, H., Edayath, S., Ehrlich, R., Feldman, G. J., Frank, M. J., Gabrielyan, M., Gallagher, H. R., Germani, S., Ghosh, T., Giri, A., Gomes, R. A., Goodman, M. C., Grichine, V., Groh, M., Group, R., Grover, D., Guo, B., Habig, A., Hartnell, J., Hatcher, R., Hatzikoutelis, A., Heller, K., Himmel, A., Holin, A., Howard, B., Hylen, J., Jediny, F., Judah, M., Kafka, G. K., Kalra, D., Kasahara, S. M. S., Kasetti, S., Keloth, R., Kolupaeva, L., Kotelnikov, S., Kourbanis, I., Kreymer, A., Kumar, A., Kurbanov, S., Lackey, T., Lang, K., Lee, W. M., Lin, S., Lokajicek, M., Lozier, J., Luchuk, S., Maan, K., Magill, S., Mann, W. A., Marshak, M. L., Matera, K., Matveev, V., Méndez, D. P., Messier, M. D., Meyer, H., Miao, T., Miller, W. H., Mishra, S. R., Mohanta, R., Moren, A., Mualem, L., Muether, M., Mufson, S., Murphy, R., Musser, J., Nelson, J. K., Nichol, R., Niner, E., Norman, A., Nosek, T., Oksuzian, Y., Olshevskiy, A., Olson, T., Paley, J., Patterson, R. B., Pawloski, G., Pershey, D., Petrova, O., Petti, R., Phan-Budd, S., Plunkett, R. K., Poling, R., Potukuchi, B., Principato, C., Psihas, F., Radovic, A., Rameika, R. A., Rebel, B., Reed, B., Rocco, D., Rojas, P., Ryabov, V., Sachdev, K., Sail, P., Samoylov, O., Sanchez, M. C., Schroeter, R., Sepulveda-Quiroz, J., Shanahan, P., Sheshukov, A., Singh, J., Singh, P., Singh, V., Smolik, J., Solomey, N., Song, E., Sousa, A., Soustruznik, K., Strait, M., Suter, L., Talaga, R. L., Tas, P., Thayyullathil, R. B., Thomas, J., Tian, X., Tognini, S. C., Tripathi, J., Tsaris, A., Urheim, J., Vahle, P., Vasel, J., Vinton, L., Vold, A., Vrba, T., Wang, B., Wetstein, M., Whittington, D., Wojcicki, S. G., Wolcott, J., Yadav, N., Yang, S., Zalesak, J., Zamorano, B., and Zwaska, R.

Subjects

High Energy Physics - Experiment

Abstract

We report results from the first search for sterile neutrinos mixing with active neutrinos through a reduction in the rate of neutral-current interactions over a baseline of 810\,km between the NOvA detectors. Analyzing a 14-kton detector equivalent exposure of 6.05$\times$10$^{20}$ protons-on-target in the NuMI beam at Fermilab, we observe 95 neutral-current candidates at the Far Detector compared with $83.5 \pm 9.7 \mbox{(stat.)} \pm 9.4 \mbox{(syst.)}$ events predicted assuming mixing only occurs between active neutrino species. No evidence for $\nu_{\mu} \rightarrow \nu_{s}$ transitions is found. Interpreting these results within a 3+1 model, we place constraints on the mixing angles $\theta_{24}<20.8^{\circ}$ and $\theta_{34}<31.2^{\circ}$ at the 90% C.L. for $0.05~eV^2\leq \Delta m^2_{41}\leq 0.5~eV^2$, the range of mass splittings that produce no significant oscillations over the Near Detector baseline., Comment: 8 pages, 4 figures

Published

2017

32. Constraints on Oscillation Parameters from $\nu_e$ Appearance and $\nu_\mu$ Disappearance in NOvA

Author

The NOvA Collaboration, Adamson, P., Aliaga, L., Ambrose, D., Anfimov, N., Antoshkin, A., Arrieta-Diaz, E., Augsten, K., Aurisano, A., Backhouse, C., Baird, M., Bambah, B. A., Bays, K., Behera, B., Bending, S., Bernstein, R., Bhatnagar, V., Bhuyan, B., Bian, J., Blackburn, T., Bolshakova, A., Bromberg, C., Brown, J., Brunetti, G., Buchanan, N., Butkevich, A., Bychkov, V., Campbell, M., Catano-Mur, E., Childress, S., Choudhary, B. C., Chowdhury, B., Coan, T. E., Coelho, J. A. B., Colo, M., Cooper, J., Corwin, L., Cremonesi, L., Cronin-Hennessy, D., Davies, G. S., Davies, J. P., Derwent, P. F., Dharmapalan, R., Ding, P., Djurcic, Z., Dukes, E. C., Duyang, H., Edayath, S., Ehrlich, R., Feldman, G. J., Frank, M. J., Gabrielyan, M., Gallagher, H. R., Germani, S., Ghosh, T., Giri, A., Gomes, R. A., Goodman, M. C., Grichine, V., Group, R., Grover, D., Guo, B., Habig, A., Hartnell, J., Hatcher, R., Hatzikoutelis, A., Heller, K., Himmel, A., Holin, A., Hylen, J., Jediny, F., Judah, M., Kafka, G. K., Kalra, D., Kasahara, S. M. S., Kasetti, S., Keloth, R., Kolupaeva, L., Kotelnikov, S., Kourbanis, I., Kreymer, A., Kumar, A., Kurbanov, S., Lang, K., Lee, W. M., Lin, S., Liu, J., Lokajicek, M., Lozier, J., Luchuk, S., Maan, K., Magill, S., Mann, W. A., Marshak, M. L., Matera, K., Matveev, V., Méndez, D. P., Messier, M. D., Meyer, H., Miao, T., Miller, W. H., Mishra, S. R., Mohanta, R., Moren, A., Mualem, L., Muether, M., Mufson, S., Murphy, R., Musser, J., Nelson, J. K., Nichol, R., Niner, E., Norman, A., Nosek, T., Oksuzian, Y., Olshevskiy, A., Olson, T., Paley, J., Pandey, P., Patterson, R. B., Pawloski, G., Pershey, D., Petrova, O., Petti, R., Phan-Budd, S., Plunkett, R. K., Poling, R., Potukuchi, B., Principato, C., Psihas, F., Radovic, A., Rameika, R. A., Rebel, B., Reed, B., Rocco, D., Rojas, P., Ryabov, V., Sachdev, K., Sail, P., Samoylov, O., Sanchez, M. C., Schroeter, R., Sepulveda-Quiroz, J., Shanahan, P., Sheshukov, A., Singh, J., Singh, P., Singh, V., Smolik, J., Solomey, N., Song, E., Sousa, A., Soustruznik, K., Strait, M., Suter, L., Talaga, R. L., Tamsett, M. C., Tas, P., Thayyullathil, R. B., Thomas, J., Tian, X., Tognini, S. C., Tripathi, J., Tsaris, A., Urheim, J., Vahle, P., Vasel, J., Vinton, L., Vold, A., Vrba, T., Wang, B., Wetstein, M., Whittington, D., Wojcicki, S. G., Wolcott, J., Yadav, N., Yang, S., Zalesak, J., Zamorano, B., and Zwaska, R.

Subjects

High Energy Physics - Experiment

Abstract

Results are reported from an improved measurement of $\nu_\mu \rightarrow \nu_e$ transitions by the NOvA experiment. Using an exposure equivalent to $6.05\times10^{20}$ protons-on-target 33 $\nu_e$ candidates were observed with a background of $8.2\pm0.8$ (syst.). Combined with the latest NOvA $\nu_\mu$ disappearance data and external constraints from reactor experiments on $\sin^22\theta_{13}$, the hypothesis of inverted mass hierarchy with $\theta_{23}$ in the lower octant is disfavored at greater than $93\%$ C.L. for all values of $\delta_{CP}$., Comment: 6 pages, 4 figures

Published

2017

33. Measurement of the neutrino mixing angle $\theta_{23}$ in NOvA

Author

The NOvA Collaboration, Adamson, P., Aliaga, L., Ambrose, D., Anfimov, N., Antoshkin, A., Arrieta-Diaz, E., Augsten, K., Aurisano, A., Backhouse, C., Baird, M., Bambah, B. A., Bays, K., Behera, B., Bending, S., Bernstein, R., Bhatnagar, V., Bhuyan, B., Bian, J., Blackburn, T., Bolshakova, A., Bromberg, C., Brown, J., Brunetti, G., Buchanan, N., Butkevich, A., Bychkov, V., Campbell, M., Catano-Mur, E., Childress, S., Choudhary, B. C., Chowdhury, B., Coan, T. E., Coelho, J. A. B., Colo, M., Cooper, J., Corwin, L., Cremonesi, L., Cronin-Hennessy, D., Davies, G. S., Davies, J. P., Derwent, P. F., Desai, S., Dharmapalan, R., Ding, P., Djurcic, Z., Dukes, E. C., Duyang, H., Edayath, S., Ehrlich, R., Feldman, G. J., Gabrielyan, M., Gallagher, H. R., Germani, S., Ghosh, T., Giri, A., Gomes, R. A., Goodman, M. C., Grichine, V., Group, R., Grover, D., Guo, B., Habig, A., Hartnell, J., Hatcher, R., Hatzikoutelis, A., Heller, K., Himmel, A., Holin, A., Hylen, J., Jediny, F., Judah, M., Kafka, G. K., Kalra, D., Kasahara, S. M. S., Kasetti, S., Keloth, R., Kolupaeva, L., Kotelnikov, S., Kourbanis, I., Kreymer, A., Kumar, A., Kurbanov, S., Lang, K., Lee, W. M., Lin, S., Liu, J., Lokajicek, M., Lozier, J., Luchuk, S., Maan, K., Magill, S., Mann, W. A., Marshak, M. L., Matera, K., Matveev, V., Méndez, D. P., Messier, M. D., Meyer, H., Miao, T., Miller, W. H., Mishra, S. R., Mohanta, R., Moren, A., Mualem, L., Muether, M., Mufson, S., Murphy, R., Musser, J., Nelson, J. K., Nichol, R., Niner, E., Norman, A., Nosek, T., Oksuzian, Y., Olshevskiy, A., Olson, T., Paley, J., Pandey, P., Patterson, R. B., Pawloski, G., Pershey, D., Petrova, O., Petti, R., Phan-Budd, S., Plunkett, R. K., Poling, R., Potukuchi, B., Principato, C., Psihas, F., Radovic, A., Rameika, R. A., Rebel, B., Reed, B., Rocco, D., Rojas, P., Ryabov, V., Sachdev, K., Sail, P., Samoylov, O., Sanchez, M. C., Schroeter, R., Sepulveda-Quiroz, J., Shanahan, P., Sheshukov, A., Singh, J., Singh, P., Singh, V., Smolik, J., Solomey, N., Song, E., Sousa, A., Soustruznik, K., Strait, M., Suter, L., Talaga, R. L., Tamsett, M. C., Tas, P., Thayyullathil, R. B., Thomas, J., Tian, X., Tognini, S. C., Tripathi, J., Tsaris, A., Urheim, J., Vahle, P., Vasel, J., Vinton, L., Vold, A., Vrba, T., Wang, B., Wetstein, M., Whittington, D., Wojcicki, S. G., Wolcott, J., Yadav, N., Yang, S., Zalesak, J., Zamorano, B., and Zwaska, R.

Subjects

High Energy Physics - Experiment

Abstract

This Letter reports new results on muon neutrino disappearance from NOvA, using a 14 kton detector equivalent exposure of $6.05\times10^{20}$ protons-on-target from the NuMI beam at the Fermi National Accelerator Laboratory. The measurement probes the muon-tau symmetry hypothesis that requires maximal mixing ($\theta_{23} = \pi/4$). Assuming the normal mass hierarchy, we find $\Delta m^2 = (2.67 \pm 0.11)\times 10^{-3}$ eV$^2$ and $\sin^2 \theta_{23}$ at the two statistically degenerate values $0.404^{+0.030}_{-0.022}$ and $0.624^{+0.022}_{-0.030}$, both at the 68% confidence level. Our data disfavor the maximal mixing scenario with 2.6 $\sigma$ significance., Comment: 7 pages, 3 figures

Published

2017

34. Infrared Luminescent Hybrid Materials Based on Inorganic Glass Matrices

Author

Runina, K. I., Popkova, L. V., Khomyakov, A. V., Avetisov, R. I., Petrova, O. B., and Avetisov, I. Kh.

Published

2021

35. Synthesis and Properties of Nd-Doped Chlorofluorosilicate Lead Glasses

Author

Butenkov, D. A., Runina, K. I., and Petrova, O. B.

Published

2021

36. Transparent Glass-Ceramic Materials Based on Lead Fluoroborate Glasses Co-Activated by Eu/Gd

Author

Velichkina, D. A., Runina, K. I., Zykova, M. P., and Petrova, O. B.

Published

2021

37. Fluorescence Quenching of 3,5-Diphenyl-8-CF3-BODIPY Luminophores Bearing Aminophenyl Substituents by Aromatic Molecules

Author

Gadomska, A. V., Nevidimov, A. V., Tovstun, S. A., Petrova, O. V., Sobenina, L. N., Trofimov, B. A., and Razumov, V. F.

Published

2021

38. Morphological characteristics of the pineal gland of newborn rats under conditions of chronic prenatal hypoxia

Author

Pshychenko V. V, Cherno V. S., Chebotar L. D., Larycheva O. M., Petrova O. I., Pshychenko V. V, Cherno V. S., Chebotar L. D., Larycheva O. M., and Petrova O. I.

Abstract

Prenatal ontogeny is a period of high sensitivity to the influence of stress factors. Prenatal hypoxia is one of the most common and clinically significant stress factors that cause mortality and disability among newborns. Prenatal hypoxia during critical periods of brain formation leads to pathomorphological changes in brain structures, accompanied by behavioral disorders and learning abilities, neurological disorders, and disruption of adaptation processes. Since the pineal gland is actively involved in adaptation processes in response to stress factors, the aim of our study was to study the morphological and functional changes in the pineal gland of newborn rats after exposure to chronic prenatal hypoxia. Experimental studies were conducted on the offspring of female Wistar rats of both sexes. Experimental animals were divided into 2 groups: control and experimental. The first (control) group was formed by 6 newborn animals from females that were in normal vivarium conditions without the influence of additional factors. The second group was formed by 6 newborn animals from female rats, which were injected subcutaneously with a sodium nitrite solution at a dose of 50 mg/kg every day from the 16th to the 21st day of pregnancy. Prenatal hypoxia is accompanied by morphological changes in the parenchyma and vascular bed of the pineal gland. It was established that in the peripheral regions of the parenchyma, stromal components, light cells with vacuolated cytoplasm, and glial cells were identified. The central zone of the parenchyma is formed by a mass of undifferentiated immature pinealocytes. n the central zones of the pineal gland, we also found areas with signs of focal and complete lysis of pinealocytes, manifested by discoloration of the nuclear substance and nucleolus and the formation of nuclear "shadows" with their subsequent dissolution. Microscopic examination of the blood bed of the pineal gland revealed marked signs of extra-organ blood circulation disord

Published

2024

39. Search for CP-violating Neutrino Non-Standard Interactions with the NOvA Experiment

Author

NOvA Collaboration, Acero, M. A., Acharya, B., Adamson, P., Aliaga, L., Anfimov, N., Antoshkin, A., Arrieta-Diaz, E., Asquith, L., Aurisano, A., Back, A., Balashov, N., Baldi, P., Bambah, B. A., Bat, A., Bays, K., Bernstein, R., Bezerra, T. J. C., Bhatnagar, V., Bhattarai, D., Bhuyan, B., Bian, J., Booth, A. C., Bowles, R., Brahma, B., Bromberg, C., Buchanan, N., Butkevich, A., Calvez, S., Carroll, T. J., Catano-Mur, E., Cesar, J. P., Chatla, A., Chaudhary, S., Chirco, R., Choudhary, B. C., Christensen, A., Cicala, M. F., Coan, T. E., Cooleybeck, A., Cortes-Parra, C., Coveyou, D., Cremonesi, L., Davies, G. S., Derwent, P. F., Djurcic, Z., Dolce, M., Doyle, D., Tonguino, D. Dueñas, Dukes, E. C., Dye, A., Ehrlich, R., Ewart, E., Filip, P., Franc, J., Frank, M. J., Gallagher, H. R., Gao, F., Giri, A., Gomes, R. A., Goodman, M. C., Groh, M., Group, R., Habig, A., Hakl, F., Hartnell, J., Hatcher, R., He, M., Heller, K., Hewes, V, Himmel, A., Ivaneev, Y., Ivanova, A., Jargowsky, B., Jarosz, J., Johnson, C., Judah, M., Kakorin, I., Kaplan, D. M., Kalitkina, A., Kleykamp, J., Klimov, O., Koerner, L. W., Kolupaeva, L., Kralik, R., Kumar, A., Kuruppu, C. D., Kus, V., Lackey, T., Lang, K., Lesmeister, J., Lister, A., Liu, J., Lock, J. A., Lokajicek, M., MacMahon, M., Magill, S., Mann, W. A., Manoharan, M. T., Plata, M. Manrique, Marshak, M. L., Martinez-Casales, M., Matveev, V., Mehta, B., Messier, M. D., Meyer, H., Miao, T., Mikola, V., Miller, W. H., Mishra, S., Mishra, S. R., Mislivec, A., Mohanta, R., Moren, A., Morozova, A., Mu, W., Mualem, L., Muether, M., Mulder, K., Myers, D., Naples, D., Nath, A., Nelleri, S., Nelson, J. K., Nichol, R., Niner, E., Norman, A., Norrick, A., Nosek, T., Oh, H., Olshevskiy, A., Olson, T., Ozkaynak, M., Pal, A., Paley, J., Panda, L., Patterson, R. B., Pawloski, G., Petrova, O., Petti, R., Prais, L. R., Rafique, A., Raj, V., Rajaoalisoa, M., Ramson, B., Ravelhofer, M., Rebel, B., Roy, P., Samoylov, O., Sanchez, M. C., Falero, S. Sánchez, Shanahan, P., Sharma, P., Shmakov, A., Sheshukov, A., Shukla, S., Singha, D. K., Shorrock, W., Singh, I., Singh, P., Singh, V., Smith, E., Smolik, J., Snopok, P., Solomey, N., Sousa, A., Soustruznik, K., Strait, M., Suter, L., Sutton, A., Sutton, K., Swain, S., Sweeney, C., Sztuc, A., Oregui, B. Tapia, Tas, P., Thakore, T., Thomas, J., Tiras, E., Torun, Y., Tripathi, J., Trokan-Tenorio, J., Urheim, J., Vahle, P., Vallari, Z., Vasel, J., Villamil, J. D., Vockerodt, K. J., Vrba, T., Wallbank, M., Wetstein, M., Whittington, D., Wickremasinghe, D. A., Wieber, T., Wolcott, J., Wrobel, M., Wu, S., Wu, W., Xiao, Y., Yaeggy, B., Yahaya, A., Yankelevich, A., Yonehara, K., Yu, Y., Zadorozhnyy, S., Zalesak, J., Zwaska, R., NOvA Collaboration, Acero, M. A., Acharya, B., Adamson, P., Aliaga, L., Anfimov, N., Antoshkin, A., Arrieta-Diaz, E., Asquith, L., Aurisano, A., Back, A., Balashov, N., Baldi, P., Bambah, B. A., Bat, A., Bays, K., Bernstein, R., Bezerra, T. J. C., Bhatnagar, V., Bhattarai, D., Bhuyan, B., Bian, J., Booth, A. C., Bowles, R., Brahma, B., Bromberg, C., Buchanan, N., Butkevich, A., Calvez, S., Carroll, T. J., Catano-Mur, E., Cesar, J. P., Chatla, A., Chaudhary, S., Chirco, R., Choudhary, B. C., Christensen, A., Cicala, M. F., Coan, T. E., Cooleybeck, A., Cortes-Parra, C., Coveyou, D., Cremonesi, L., Davies, G. S., Derwent, P. F., Djurcic, Z., Dolce, M., Doyle, D., Tonguino, D. Dueñas, Dukes, E. C., Dye, A., Ehrlich, R., Ewart, E., Filip, P., Franc, J., Frank, M. J., Gallagher, H. R., Gao, F., Giri, A., Gomes, R. A., Goodman, M. C., Groh, M., Group, R., Habig, A., Hakl, F., Hartnell, J., Hatcher, R., He, M., Heller, K., Hewes, V, Himmel, A., Ivaneev, Y., Ivanova, A., Jargowsky, B., Jarosz, J., Johnson, C., Judah, M., Kakorin, I., Kaplan, D. M., Kalitkina, A., Kleykamp, J., Klimov, O., Koerner, L. W., Kolupaeva, L., Kralik, R., Kumar, A., Kuruppu, C. D., Kus, V., Lackey, T., Lang, K., Lesmeister, J., Lister, A., Liu, J., Lock, J. A., Lokajicek, M., MacMahon, M., Magill, S., Mann, W. A., Manoharan, M. T., Plata, M. Manrique, Marshak, M. L., Martinez-Casales, M., Matveev, V., Mehta, B., Messier, M. D., Meyer, H., Miao, T., Mikola, V., Miller, W. H., Mishra, S., Mishra, S. R., Mislivec, A., Mohanta, R., Moren, A., Morozova, A., Mu, W., Mualem, L., Muether, M., Mulder, K., Myers, D., Naples, D., Nath, A., Nelleri, S., Nelson, J. K., Nichol, R., Niner, E., Norman, A., Norrick, A., Nosek, T., Oh, H., Olshevskiy, A., Olson, T., Ozkaynak, M., Pal, A., Paley, J., Panda, L., Patterson, R. B., Pawloski, G., Petrova, O., Petti, R., Prais, L. R., Rafique, A., Raj, V., Rajaoalisoa, M., Ramson, B., Ravelhofer, M., Rebel, B., Roy, P., Samoylov, O., Sanchez, M. C., Falero, S. Sánchez, Shanahan, P., Sharma, P., Shmakov, A., Sheshukov, A., Shukla, S., Singha, D. K., Shorrock, W., Singh, I., Singh, P., Singh, V., Smith, E., Smolik, J., Snopok, P., Solomey, N., Sousa, A., Soustruznik, K., Strait, M., Suter, L., Sutton, A., Sutton, K., Swain, S., Sweeney, C., Sztuc, A., Oregui, B. Tapia, Tas, P., Thakore, T., Thomas, J., Tiras, E., Torun, Y., Tripathi, J., Trokan-Tenorio, J., Urheim, J., Vahle, P., Vallari, Z., Vasel, J., Villamil, J. D., Vockerodt, K. J., Vrba, T., Wallbank, M., Wetstein, M., Whittington, D., Wickremasinghe, D. A., Wieber, T., Wolcott, J., Wrobel, M., Wu, S., Wu, W., Xiao, Y., Yaeggy, B., Yahaya, A., Yankelevich, A., Yonehara, K., Yu, Y., Zadorozhnyy, S., Zalesak, J., and Zwaska, R.

Abstract

This Letter reports a search for charge-parity (CP) symmetry violating non-standard interactions (NSI) of neutrinos with matter using the NOvA Experiment, and examines their effects on the determination of the standard oscillation parameters. Data from $\nu_{\mu}(\bar{\nu}_{\mu})\rightarrow\nu_{\mu}(\bar{\nu}_{\mu})$ and $\nu_{\mu}(\bar{\nu}_{\mu})\rightarrow\nu_{e}(\bar{\nu}_{e})$ oscillation channels are used to measure the effect of the NSI parameters $\varepsilon_{e\mu}$ and $\varepsilon_{e\tau}$. With 90% C.L. the magnitudes of the NSI couplings are constrained to be $|\varepsilon_{e\mu}| \, \lesssim 0.3$ and $|\varepsilon_{e\tau}| \, \lesssim 0.4$. A degeneracy at $|\varepsilon_{e\tau}| \, \approx 1.8$ is reported, and we observe that the presence of NSI limits sensitivity to the standard CP phase $\delta_{\tiny\text{CP}}$.

Published

2024

40. Delayed Effects of Surgery during Early Pregnancy on Brain Development in OXYS Rats

Author

Rozhkova, I. N., Brusentsev, E. Yu., Igonina, T. N., Ragaeva, D. S., Petrova, O. M., Naprimerov, V. A., Tikhonova, M. A., Amstislavskaya, T. G., and Amstislavsky, S. Ya.

Published

2020

41. Synthesis and Spectral Properties of Glasses in the System Bismuth Oxide – Germanium Oxide – Cerium Oxide

Author

Serkina, K. S., Savenko, L. M., Stepanova, I. V., and Petrova, O. B.

Published

2021

42. High-energy spectrum and zenith-angle distribution of atmospheric neutrinos

Author

Sinegovsky, S. I., Petrova, O. N., and Sinegovskaya, T. S.

Subjects

Astrophysics - High Energy Astrophysical Phenomena, High Energy Physics - Experiment, High Energy Physics - Phenomenology

Abstract

High-energy neutrinos, arising from decays of mesons produced through the collisions of cosmic ray particles with air nuclei, form the background in the astrophysical neutrino detection problem. An ambiguity in high-energy behavior of pion and especially kaon production cross sections for nucleon-nucleus collisions may affect essentially the calculated neutrino flux. We present results of the calculation of the energy spectrum and zenith-angle distribution of the muon and electron atmospheric neutrinos in the energy range 10 GeV to 10 PeV. The calculation was performed with usage of known hadronic models (QGSJET-II-03, SIBYLL 2.1, Kimel & Mokhov) for two of the primary spectrum parametrizations, by Gaisser & Honda and by Zatsepin & Sokolskaya. The comparison of the calculated muon neutrino spectrum with the IceCube40 experiment data make it clear that even at energies above 100 TeV the prompt neutrino contribution is not so apparent because of tangled uncertainties of the strange (kaons) and charm (D-mesons) particle production cross sections. An analytic description of calculated neutrino fluxes is presented., Comment: Talk presented at the 32nd ICRC (Beijing, China, 11-18 Aug. 2011), 4 pages, 7 figures

Published

2011

43. PRODUCTION AND RESEARCH OF SORBENTS FROM FOOD PLANT WASTES FOR WATER PURIFICATION

Author

Idrisheva, Zh. K., primary, Daumova, G. K., additional, Daniyarova, M. D., additional, Petrova, O. A., additional, and Denissov, I. V., additional

Published

2024

44. On the temporality and modality of the internal predicates of lexical meanings (on the material of personal names)

Author

Eryomin, A. N., primary and Petrova, O. O., additional

Published

2024

45. MORPHOLOGICAL CHARACTERISTICS OF THE PINEAL GLAND OF NEWBORN RATS UNDER CONDITIONS OF CHRONIC PRENATAL HYPOXIA

Author

Pshychenko, V. V., primary, Cherno, V. S., additional, Chebotar, L. D., additional, Larycheva, O. M., additional, and Petrova, O. I., additional

Published

2024

46. MORPHOFUNCTIONAL STATE OF THE RATS’ EPIPHYSIS UNDER CONDITIONS OF HEAVY METAL SALTS INTOXICATION AND CORRECTION WITH MELATONIN

Author

Pshychenko, V. V., primary, Cherno, V. S., additional, Chebotar, L. D., additional, Larycheva, O. M., additional, and Petrova, O. I., additional

Published

2024

47. Synthesis and Properties of Sm3+/Gd3+ Co-Doped B2O3–GeO2–Bi2O3 Glass Composition.

Author

Zykova, S. S., Serkina, K. S., Runina, K. I., Avetissov, I. Ch., Petrova, O. B., and Boldyrev, K. A.

Subjects

GERMANATE glasses, RARE earth ions, BORON oxide, BISMUTH trioxide, DOPING agents (Chemistry)

Abstract

Within the scope of the study, glasses co-doped with Sm3+/Gd3+ based on the B2O3–GeO2–Bi2O3 system were synthesized, covering compositions of 40B2O3–40GeO2–(15 – 17)Bi2O3–(3 – 2)Sm2O3–(2 – 1)Gd2O3 and 42.5B2O3–42.5GeO2–(11.25 – 12.75)Bi2O3–(2.25 – 1.50)Sm2O3–(1.500 – 0.075)Gd2O3. An assessment of luminescent characteristics was carried out within the temperature range of 298 – 673 K. Spectral bands of photoluminescence associated with transitions between various Stark sublevels of Sm3+ ions were identified. Redistribution of the fluorescence intensity ratio corresponding to 4G5/2 → 6H9/2 ( λ PL max = 645 nm) and 4G5/2 → 6H7/2 ( λ PL max = 597 nm) transitions was observed. Based on the obtained data, calculations of the fluorescence intensity ratio FIR, as well as relative sensitivity SR, were carried out. The obtained results indicate the promising potential of these glasses as luminescent thermometric materials. [ABSTRACT FROM AUTHOR]

Published

2024

48. Physico-Chemical and Texture Properties of Gelatin-Free Jelly Desserts

Author

Nepovinnykh N., Petrova O., Belova N., and Yeganehzad S.

Subjects

jelly desserts, non-starch polysaccharides, gelatin, iota-carrageenan, xanthan gum, locust bean gum, konjac glucomannan, Food processing and manufacture, TP368-456

Abstract

The research features the technological challenge of producing jelly desserts by replacing gelatin by non-starch polysaccharides of plant, bacterial, and algal origin (separately or in binary mixtures) in order to overcome religious and ethical constraints. The authors focused on the texture which is responsible for gel network formation of desserts. Hydrocolloids are widely used in many food formulations to improve quality attributes and shelf-life. The polysaccharides under analysis included alginate, pectin, iota-carrageenan, konjac glucomannan, xanthan, and guar gum, separately or in binary mixtures. The experiment made it possible to determine polysaccharides and their optimal concentrations (konjac glucomannan 0.4 % : xanthan gum 0.6 %; locust bean gum 0.2 % : xanthan gum 0.8 %; iota-carrageenan 0.4 %) as gelling agents for the production of desserts without gelatin. Formation of a gel network in desserts occurs as a result of a complex interaction of hydrocolloids, milk fat, and sugar. Structure formation of jelly desserts with polysaccharides occurs already at 18 ± 2°C in 20–40 minutes. In contrast, the structure formation of the control sample occurred at 4 ± 2°C in 2–3 hours. Sensory evaluation of the products was conducted by panellists according to the following criteria: taste, colour, consistency, aroma, and appearance. The paper also describes an analysis of texture indicators. The shelf-life was assessed according to moisture content and water activity as 24 hours at 4 ± 2°C. Several economically-viable new formulations were identified: they successfully reproduced the essential attributes of well-established and widely-consumed traditional gelatin desserts.

Published

2019

49. Synchrotron, X-Ray, and Electron Microscopic Studies of Catalyst Systems Based on Multiwalled Carbon Nanotubes Modified by Copper Nanoparticles

Author

Sivkov, V. N., Ob’’edkov, A. M., Petrova, O. V., Nekipelov, S. V., Mingaleva, A. E., Kremlev, K. V., Kaverin, B. S., Semenov, N. M., Kadomtseva, A. V., Gusev, S. A., Yunin, P. A., and Tatarskii, D. A.

Published

2020

50. Development and Aging of the Mammalian Reproductive System

Author

Amstislavsky, S. Ya., Brusentsev, E. Yu., Petrova, O. M., Naprimerov, V. A., and Levinson, A. L.

Published

2020