CITATIONS of our listed papers

Home

0.1 J. Jeknić-Dugić, M. Arsenijević, M. Dugić, "Quantum Structures: A View of the Quantum World", LAP Lambert Academic Publishing, Saarbrucken, Germany, 2013

Cited by:

D. Rakovic, NEUREL 2015, DOI: 10.11.09/NEUREL.2014.7011473

N. L. Harshman, in Quantum Structural Studies, World Scientific Publ. 2015, pp.373-400

G. Bellomo, A. Plastino, A. R. Plastino, Phys. Rev. A 93, 062322 (2016)

S. Fortin, O. Lombardi, A Top-Down View of the Classical Limit of Quantum Theory, in Quantum structural studies: classical emergence from the quantum level, eds. RE Kastner, J Jeknić-Dugić, G Jaroszkiewicz, World Scientific, 2017, pp. 435-468

G. Bellomo, PhD Thesis (in Spanish), 2017, http://sedici.unlp.edu.ar/handle/10915/59648

Q. Ruyant, Primitive ontology or primitive relations?, 2017, http://philsci-archive.pitt.edu/12120/

N. L. Harshman, 2019, Symmetry, structure and emergent subsystems, in: Quantum Worlds, (eds.) O. Lombardi et al, Oxford University Press, pp. 294-322.

S. Fortin, O. Lombardi, IJQF 4, 247 (2018)

E. Gillis, Interaction-induced wave function collapse respects conservation laws, arXiv:1803.02687v5 [quant-ph]

S. Fortin, O. Lombardi, The correspondence principle and the understanding of decoherence, Found. Phys. (2019)

E. Gillis, 2021, Decoherence, collapse, and conservation laws arXiv: 2102.11370 [quant-ph]

E. J. Gillis, arXiv 2108.08342

0.2 Kastner R E, Jeknic-Dugic J and Jaroszkiewicz G, Eds. 2017 Quantum Structural Studies (Singapore: World Scientific, 2017)

Cited by:

V. I. Yukalov et al, Laser Phys. 29, 065502 (2019)

Y. Cai et al, Entanglement for any definition of two subsystems, arXiv 20060.7165v1 [quant-ph]

M. Dugić, J. Jeknić, What is “System”: Some Decoherence-Theory Arguments, International Journal of Theoretical Physics December 2006, Volume 45, Issue 12, pp 2215-2225

Cited by:

A. Stokes, Phys. Rev. A 86, 012511 (2012)
E.B.Fel'dman, A.I. Zenchuk, Quant. Inf. Proc. 13 (2014) 201 - 225
J.-M. Schwindt, Nothing happens in the Universe of the Everett Interpretation, arXiv:1210.8447 [quant-ph]
R. E. Kastner, Physics Today 68(5), 8 (2015)
C. Fields, “Any additive Hamiltonian yields quantum theory”, arXiv:1411.3405v2 [quant-ph]
C. Fields, “Is dark energy an artifact of decoherence?”, arXiv:1502.03424 [quant-ph]
Y. Kanada-En'yo, Phys. Rev. C, 91, 034303 (2015)

Y. Kanada En'yo, Prog. Theor. Exper, Phys. 2015, 043D04

E. Dietrich, C. Fields, Axiomathes 25, 409 (2015)

A. Stokes, P. Deb, A. Beige, J. Mod. Optics 2017, http://dx.doi.org/10.1080/09500340.2017.1295108

C. Fields, Systems 4, 32 (2016)

Q. Ruyant, Primitive ontology or primitive relations?, 2017, http://philsci-archive.pitt.edu/12120/

A. Malecic, 2017, ISSS Journals 61st Meeting of the International Society for the Systems Sciences

C. Fields, Philosophies 3, 29 (2018)

Z. Lasmar et al, Phys. Rev. A 98 062105 (2018)

C. Fields, Results in Physics 12, 1888 (2019)

E. Gillis, Interaction-induced wave function collapse respects conservation laws arXiv:1803.02687v5 [quant-ph]

C. Fields, J. F. Glazebrook, Symmetry 12, 810 (2020)

E. Gillis, 2021, Decoherence, collapse, and conservation laws arXiv: 2102.11370 [quant-ph]

C. Fields et al, Symmetry 13, 408 (2021)

E. J. Gillis, arXiv 2108.08342

J. Jeknić-Dugić, M. Dugić, Multiple System-Decomposition Method for Avoiding Quantum Decoherence, Chin. Phys. Lett. 2008, Vol. 25 Issue (2): 371-374

Cited by:

A. Kowalewska-Kudłaszyk, W. Leoński, J. Peřina Jr., Phys. Rev. A 83, 052326 (2011)
A.Kowalewska-Kudlaszyk, Optics Commun., 285, 5543 (2012)

M. Dugić, J. Jeknić-Dugić, What Is “System”: The Information-Theoretic Arguments, International Journal of Theoretical Physics March 2008, Volume 47, Issue 3, pp 805-813

Cited by:

E.B.Fel'dman, A.I. Zenchuk, Quant. Inf. Proc. 13 (2014) 201 - 225
C. Fields, “Any additive Hamiltonian yields quantum theory”, arXiv:1411.3405v2 [quant-ph]
C. Fields, “Is dark energy an artifact of decoherence?”, arXiv:1502.03424 [quant-ph]
E. Dietrich, C. Fields, Axiomathes 25, 409 (2015)

C. Fields, Systems 4, 32 (2016)

C. Fields, D. D. Hoffman, C. Prakash, R. Prentner, Constructivist Foundations 12, 265 (2017)

C. Fields, D. D. Hoffman, C. Prakash, R. Prentner, Constructivist Foundations 12, 284 (2017)

C. Fields, Philosophies 3, 29 (2018)

Z. Lasmar et al, Phys. Rev. A 98, 062105 (2018)

C. Fields, Results in Physics 12, 1888 (2019)

C. Fields, J. F. Glazebrook, Symmetry 12, 810 (2020)

C. Fields et al, Symmetry 13, 408 (2021)

S. Fortin and O. Lombardi, PhilSci arxiv, 19257

M. Pasqualini, S. Fortin, PhilSci arxiv, 19471

M. Dugić, J. Jeknić-Dugić, Parallel decoherence in composite quantum systems, Pramana: J. Phys. August 2012, Volume 79, Issue 2, pp 199-209

Cited by:

Oleg Lychkovskiy, Phys. Rev. A 87, 022112 (2013)
Ruth E. Kastner, Studies in History and Philosophy of Science Part B: Studies in History and Philosophy of Modern Physics, 48 A, 56 (2014)
C. Fields, “Any additive Hamiltonian yields quantum theory”, arXiv:1411.3405v2 [quant-ph]
C. Fields, “Is dark energy an artifact of decoherence?”, arXiv:1502.03424 [quant-ph]
R. Kastner, 2016, "The illusory appeal of decoherence in the Everettian picture: affirming the consequence", arXiv:1603.04845 [quant-ph]

J. Rosaler, Studies in History and Philosophy of Science Part B: Studies in History and Philosophy of Modern Physics 53, 54 (2016)

C. Fields, Systems 4, 32 (2016)

R. Kastner, From quantum to classical physics: the role of distinguishability, in: Quantum Worlds, (eds.) O. Lombardi et al, Oxford University Press, 2019, pp. 205-221.

R. Kastner, On the status of the measurement problem arXiv:1709.09367 [quant-ph]

E. Nelson, C. J. Riedel, Classical branches and entanglement structure in the wave function of cosmological fluctuations arXiv:1711.05719v1 [quant-ph]

C. Fields, Philosophies 3, 29 (2018)

Z. Lasmar et al, Phys. Rev. A 98, 062195 (2018)

S. Fortin, O. Lombardi, The correspondence principle and the understanding of decoherence, Found. Phys. (2019)

R. Kastner, Int. J. Quant. Foundations 6, 24 (2020)

M. Arsenijević, J. Jeknić-Dugić, M. Dugić, Zero Discord for Markovian Bipartite Systems arXiv:1204.2789v3

Cited by:

S. Alipour, A. Mani, A. T. Rezakhani, Phys. Rev. A 85, 052108 (2012)
F. Altintas, A. Kurt, R. Eryigit, Physics Letters A 377 (2012) pp. 53-59
J.-S. Xu, C.-F. Li, Int. J. Mod. Phys. B 27, 1345054 (2013)

M. Dugić, M. Arsenijević, J. Jeknić-Dugić, Quantum correlations relativity for continuous variable systems, Science China Physics, Mechanics and Astronomy April 2013, Volume 56, Issue 4, pp 732-736

Cited by:

B.-K. Zhao, S.X. Zhao, Int. J. Theor. Phys. DOI:10.107/s10773-015-2807-8

W. Li, Z. Meng, X. Yu, J. Zhang, Sci. China Phys. Mech. Astron. 58, 104201 (2015)
Shao-Hua Xiang, Yu-Jing Zhao, Xi-Xiang Zhu, Ke-Hui Song, Int. J. Theor. Phys. 54, 2881 (2015)
E.B.Fel'dman, A.I. Zenchuk, Quant. Inf. Proc. 13 (2014) 201 - 225
Sheng, Yu-Bo; Qu, Chang-Cheng; Yang, Ou-Yang; et al., Int. J. Theor. Phys., 53, 2033 (2014)
Yan, Siqing; Guo, Yu; Hou, Jinchuan, Chin. Sci. Bulletin, 59, 279 (2014)
Zhihua Guo, Huaixin Cao, Shixian Qu, Information Sciences, 289 (2014) 262–272
Wang Sheng-Fang, Liu Yi-Min, Li Guo-Feng, Liu Xian-Song, Zhang Zhan-Jun, Commun. Theor. Phys. 60, 405 (2013)
R. Kastner, 2016, "The illusory appeal of decoherence in the Everettian picture: affirming the consequence", arXiv:1603.04845 [quant-ph]

B-K Zhao, S-X Zhao, Int. J. Theor. Phys. 55, 1695 (2016)

S. Chatterjee, S. Sazim, I. Chakrabarty, Phys. Rev. A 93, 042309 (2016)

A. Kumar, Phys Rev. A 96, 012332 (2017)

Z. Lasmar et al, Phys. Rev. A 98, 0621905 (2018)

M. Arsenijević, J. Jeknić-Dugić and M. Dugić, Asymptotic dynamics of the alternate degrees of freedom for a two-mode system: An analytically solvable model, Chinese Phys. B 22 020302 (2013)

Cited by:

E.B.Fel'dman, A.I. Zenchuk, Quant. Inf. Proc. 13 (2014) 201 - 225

M. Arsenijević, J. Jeknić-Dugić, M. Dugić, A Limitation of the Nakajima-Zwanzig projection method, arXiv:1301.1005v6

Cited by:

E.B.Fel'dman, A.I. Zenchuk, Quant. Inf. Proc. 13 (2014) 201 - 225

J. Jeknić-Dugić. M. Dugić, A. Francom, Quantum Structures of a Model-Universe: Questioning the Everett Interpretation of Quantum Mechanics, International Journal of Theoretical Physics January 2014, Volume 53, Issue 1, pp 169-180

Cited by:

[early draft, arXiv:1109.6424] J.-M. Schwindt, Nothing happens in the Universe of the Everett Interpretation, arXiv:1210.8447 [quant-ph]
R. E. Kastner, Physics Today 68(5), 8 (2015)
L. Marchildon, Stud. Hist. Philos. Sc. B: Stud. Hist. and Philos. Mod. Phys. 52, 274 (2015)

A. Sudbery, Time, chance and quantum theory, in Probing the meaning and structure of quantum mechanics: superpositions, semantics, dynamics and identity, eds. D. Aerts, C. de Ronde, H. Freytes, R. Giuntini, World Scientific, Singapore, 2016. pp. 324-339. arXiv

R. Kastner, 2016, "The illusory appeal of decoherence in the Everettian picture: affirming the consequence", arXiv:1603.04845 [quant-ph]

A. Malečić, 2017, Footprints of general systems theory, Systems Res, and Behav. Sci. Vol 34, Issue 3, 2017, pp. 631-626

E. Nelson, C. J. Riedel, Classical branches and entanglement structure in the wave function of cosmological fluctuations arXiv:1711.05719v1 [quant-ph]

A. Malecic, 2017, ISSS Journals 61st Meeting of the International Society for the Systems Sciences

O. C. Stoica, 2021, arXiv.org 2102.08620 [quant-ph]

M. Arsenijević, M. Dugić, Nonexistence of the Classical Trajectories in the Stern-Gerlach Experiment, Acta Phys. Polonica 117, 760 (2010)

Cited by:

J. Greve, Physics Essays 29, 435 (2016)

V. M. Ristić, M. M. Radulović, T. B. Miladinović, Int. J. Theor. Phys. 50, 3602 (2011)

[citation of the early draft, arXiv:0809.4376] N. O. Cherkashyna, K. V. Usenko, Ukr. J. Phys. 54, 645 (2009)

Jasmina Jeknić-Dugić, Miroljub Dugić, Allen Francom, Momir Arsenijević, Quantum Structures of the Hydrogen Atom, Open Access Library Journal 1, e501 (2014)

Cited by:

S. N. Filippov, J. Russ. Laser Res. 35, 484 (2014)
R. E. Kastner, Physics Today 68(5), 8 (2015)
M. Kupczynski, Int. J. Quantum Inform. 14(4), 1640003 (2016)

S. N. Filippov, Quantum Computing, Itogi Nauki i Tehniki, Ser. Sovrem. Mat. Pril. Temat. Obz. 138, 99 (2017)

A. Fadillah,, D. Salirawati, 2018, AIP Conference Proceedings 2021, 080002

Z. Lasmar et al, Phys. Rev. A 98, 062105 (2018)

S. N. Fillipov, J. Math. Sci. 241, 210 (2019)

12. J. Jeknić-Dugić, M. Arsenijević, M. Dugić, A local-time-induced unique pointer basis, Proceedings of the Royal Society A 460, 2014.0283 (2014)

Cited by:

P. L. Simeonov, Prog. Biophys. Molec Biol. 119, 271 (2015)
T. Diagana, Communications in Mathematical Analysis,19,1 (2016)

H. Kitada, Communications in Mathematical Analysis 19, 6 (2016)

X.-K. Guo, 2017, S-Matrix interpretation in categorical quantum mechanics arXiv:1708.09383 [quant-ph]

A. Malecic, 2017, ISSS Journals 61st Meeting of the International Society for the Systems Society

    13. M. Arsenijevic, J. Jeknic-Dugic, D. Todorovic, M. Dugic, 2015, Entanglement relativity in the foundations of the open quantum                  systems theory, in "New Research on Quantum Entanglement", Lori Watson (ed.), Nova Science Publishers, pp 99-116; arXiv

            Cited by:

N. L. Harshman, Symmetry and natural quantum structures for three-particles in one-dimension, in Quantum structural studies: classical emergence from the quantum level, eds. RE Kastner, J Jeknic-Dugic, G. Jaroszkiewicz, World Scientific, Singapore, 2017, pp. 373-400 arXiv

Z. Lasmar et al, Phys. Rev. A 98, 062105 (2018)

14. M. Arsenijević, J. Jeknić-Dugić, M. Dugić, A Top-Down versus a Bottom-up Hidden variables description of the Stern-Gerlach Experiment, in Quantum structural studies. Classical emergence from the quantum level. eds. RE Kastner, J Jeknić-Dugić, G Jaroszkiewicz, World Scientific, Singapore, 2017, pp.468-484

Cited by:

V. Allori, Primitive Ontology and the Classical World, in Quantum structural studies: classical emergence from the quantum level, eds. RE Kastner, J. Jeknic-Dugic, G. Jaroszkiewicz, World Scientific, Singapore, 2017, pp. 175-200

R. E. Kastner, Bound States as fundamental Quantum Structures, in Quantum structural studies: classical emergence form the quantum level, eds. RE Kastner, J Jeknic-Dugic, G Jaroszkiewicz, Wordl Scientific, Singapore, 2017, pp. 427-432

S. Fortin and O. Lombardi, A Top-Down View of the Classical Limit of Quantum Mechanics, in Quantum structural studies: classical emergence from the quantum level, eds. RE Kastner, J Jeknic-Dugic, G Jaroszkiewicz, World Scientific, 2017, pp. 435-468

S. Fortin, O. Lombardi, IJQF 4, 247 (2018)

15. D. Raković et al, 2014, On macroscopic quantum phenomena in biomolecules and cells: from Levinthal to Hopfield, BioMed Res. Intern. Article ID 580491,

Cited by:

M. Piel et al, Appraisal 11, 42 (2017)

D.K.F. Meijer, H. Geesink, Open J. Biophys. 8, 117 (2018)

A. Stekhin et al, Clin. Practice 15, 663-670 (2018)

K. B. Bec, J. Grabska, C. W. Huck, Analitica Chim. Acta 1133, 150 (2020)

A. Bandyopadhyay, S. Basu, BBA-Proteins and proteomics 1868, 140474 (2020)

16. J. Jeknić-Dugić, M. Arsenijević, M. Dugić, Dynamical emergence of Markovianity in the Local Time Scheme, Proc. Roy. Soc. A 472, 20160041 (2016)

Cited by:

X.-K. Guo, 2017, S-Matrix interpretation in categorical quantum mechanics, arXiv:1708.09383[quant-ph]

17. H. Kitada, et al, A minimalist approach to conceptualization of time in quantum theory, Phys. Lett. A 380, 3970 (2016)

Cited by:

A. Schild, Phys. Rev. A 98, 052113 (2018)

18. M. Arsenijević, J. Jeknić-Dugić, M. Dugić,2017, Generalized Kraus operators for the one-qubit depolarizing channel, Braz. J. Phys. 47, 339

Cited by:

R. Tannous, 2018, Master Thesis, Waterloo University, https://uwspace.uwaterloo.ca/bitstream/handle/10012/13671/Tannous_Ramy.pdf?sequence=1&isAllowed=y

R. Bavontaweepanya, J. Phys. Conf. Ser. 1144, 012047 (2018)

S. Thammamasuwan et al., J. Phys. Conf. Ser. 1144, 012037 (2018)

P. Arnault et al, 2020, J. Phys. A: Math. Theor. 53, 205303 (2020)

A. He et al, Phys. Rev. A 102, 012426 (2020)

J. Denis, J. Martin, arXiv 2106.11680 [quant-ph]

M. L. W. Basso, J. Maziero, arxiv.org 2107.13468 [quant-ph]

19. M. Arsenijević, J. Jeknić-Dugić, M. Dugić, 2018, Complete positivity on the subsystems level, Int. J. Theor. Phys. 57, 3492

Cited by:

Z. Lasmar et al, Phys. Rev. A 98, 062105 (2018)

20. M. Arsenijevic et al, Kraus operators for a pair of interacting qubits: a case study, Braz. J. Phys. 48, 232 (2018)

Cited by:

P. Udayakumar, P. Kumar-Eslami, Quantum Inf. Process. 18, 361 (2019)

N. Milazzo et al, Phys. Rev. A 102, 052406 (2020), arXiv

G. McCaul et al, Phys. Rev. Res. 3, 013017 (2021), arXiv

G. Narang et al, 2020, Qu. Inf. Process. 19, 396 (2020)

Home