Publications

Year of Publication: 2021

1 Bassi, Angelo Oxford Research Encyclopedia of PhysicsPhilosophy of Quantum Mechanics: Dynamical Collapse Theories. Oxford University Press, 2021.

2 Fadeev, Pavel, et al. "Ferromagnetic gyroscopes for tests of fundamental physics." Quantum Science and Technology. 6.2 (2021): 024006.

3 Donadi, Sandro, et al. "Underground test of gravity-related wave function collapse." Nature Physics. 17.1 (2021): 74-78.

4 Giordani, Taira, et al. "Entanglement transfer, accumulation and retrieval via quantum-walk-based qubit–qudit dynamics." New Journal of Physics. 23.2 (2021): 023012.

5 Sgroi, Pierpaolo, Massimo G. Palma, and Mauro Paternostro. "Reinforcement Learning Approach to Nonequilibrium Quantum Thermodynamics." Physical Review Letters. 126.2 (2021).

6 Gasbarri, Giulio, et al. "Prospects for near-field interferometric tests of collapse models." Physical Review A. 103.2 (2021).

7 Adler, Stephen L., Angelo Bassi, and Matteo Carlesso. "The continuous spontaneous localization layering effect from a lattice perspective." Journal of Physics A: Mathematical and Theoretical. 54.8 (2021): 085303.

Year of Publication: 2020

8 Mehic, Miralem, et al. "Quantum Key Distribution." ACM Computing Surveys. 53.5 (2020): 1-41.

9 Román-Ancheyta, Ricardo, Barış Çakmak, and Özgür E. Müstecaplıoğlu. "Spectral signatures of non-thermal baths in quantum thermalization." Quantum Science and Technology. 5.1 (2020): 015003.

10 Sansone, Francesco, et al. "LaserCube optical communication terminal for nano and micro satellites." Acta Astronautica. 173 (2020): 310-319.

11 Polnik, Mateusz, et al. "Scheduling of space to ground quantum key distributionAbstract." EPJ Quantum Technology. 7.1 (2020).

12 Mazzarella, Luca, et al. "QUARC: Quantum Research Cubesat—A Constellation for Quantum Communication." Cryptography. 4.1 (2020): 7.

13 Zicari, Giorgio, Matteo Brunelli, and Mauro Paternostro. "Assessing the role of initial correlations in the entropy production rate for nonequilibrium harmonic dynamics." Physical Review Research. 2.4 (2020).

14 Harney, Cillian, et al. "Entanglement classification via neural network quantum states." New Journal of Physics. 22.4 (2020): 045001.

15 Plávala, Martin, and Mário Ziman. "Popescu-Rohrlich box implementation in general probabilistic theory of processes." Physics Letters A. 384.16 (2020): 126323.

16 Piscicchia, Kristian, et al. "Search for a remnant violation of the Pauli exclusion principle in a Roman lead target." The European Physical Journal C. 80.6 (2020).

17 Díaz, María García, Giacomo Guarnieri, and Mauro Paternostro. "Quantum Work Statistics with Initial Coherence." Entropy. 22.11 (2020): 1223.

18 Piscicchia, K., et al. Fundamental Theories of PhysicsDo Wave Functions Jump?Sneaking a Look at Ghirardi’s Cards: Collapse Models Mapped with the Spontaneous Radiation. Eds. Valia Allori, et al. Vol. 198. Cham: Springer International Publishing, 2020.

19 Piscicchia, K, et al. "High precision test of the Pauli Exclusion Principle for electrons." Journal of Physics: Conference Series. 1586 (2020): 012016.

20 De Paolis, L, et al. "The key role of the Silicon Drift Detectors in testing the Pauli Exclusion Principle for electrons: the VIP-2 experiment." Journal of Physics: Conference Series. 1548 (2020): 012033.

21 Mancino, Luca, et al. "Nonequilibrium readiness and precision of Gaussian quantum thermometers." Physical Review Research. 2.3 (2020).

22 Marton, J., et al. "VIP-2 - Testing spin-statistics for electrons with high sensitivity." Journal of Physics: Conference Series. 1468 (2020): 012230.

23 Rossi, Massimiliano, et al. "Experimental Assessment of Entropy Production in a Continuously Measured Mechanical Resonator." Physical Review Letters. 125.8 (2020).

24 Piscicchia, Kristian, et al. "VIP-2 —High-Sensitivity Tests on the Pauli Exclusion Principle for Electrons." Entropy. 22.11 (2020): 1195.

25 Adler, Stephen L., Angelo Bassi, and Luca Ferialdi. "Minimum measurement time: lower bound on the frequency cutoff for collapse models." Journal of Physics A: Mathematical and Theoretical. 53.21 (2020): 215302.

26 Ferialdi, Luca, and Angelo Bassi. "Continuous spontaneous localization reduction rate for rigid bodies." Physical Review A. 102.4 (2020).

27 Lochan, Kinjalk, et al. "Detecting Acceleration-Enhanced Vacuum Fluctuations with Atoms Inside a Cavity." Physical Review Letters. 125.24 (2020).

28 Vinante, A., et al. "Ultralow Mechanical Damping with Meissner-Levitated Ferromagnetic Microparticles." Physical Review Applied. 13.6 (2020).

29 Vinante, A., et al. "Narrowing the Parameter Space of Collapse Models with Ultracold Layered Force Sensors." Physical Review Letters. 125.10 (2020).

30 Vinante, A., et al. "Testing dissipative collapse models with a levitated micromagnet." Physical Review Research. 2.4 (2020).

31 Leedumrongwatthanakun, Saroch, et al. "Programmable linear quantum networks with a multimode fibre." Nature Photonics. 14.3 (2020): 139-142.

32 Carlesso, Matteo, and Mauro Paternostro Fundamental Theories of PhysicsDo Wave Functions Jump?Opto-Mechanical Test of Collapse Models. Eds. Valia Allori, et al. Vol. 198. Cham: Springer International Publishing, 2020.

33 Lorenzo, Salvatore, Mauro Paternostro, and Massimo G. Palma. "Anti-Zeno-based dynamical control of the unfolding of quantum Darwinism." Physical Review Research. 2.1 (2020).

34 Belenchia, Alessio, et al. "Entropy production in continuously measured Gaussian quantum systemsAbstract." npj Quantum Information. 6.1 (2020).

35 Abah, Obinna, Mauro Paternostro, and Eric Lutz. "Shortcut-to-adiabaticity quantum Otto refrigerator." Physical Review Research. 2.2 (2020).

36 Zicari, Giorgio, Matteo Brunelli, and Mauro Paternostro. "Assessing the role of initial correlations in the entropy production rate for nonequilibrium harmonic dynamics." Physical Review Research. 2.4 (2020).

37 Giordani, Taira, et al. "Machine Learning-Based Classification of Vector Vortex Beams." Physical Review Letters. 124.16 (2020).

38 Kong, Jia, et al. "Measurement-induced, spatially-extended entanglement in a hot, strongly-interacting atomic system." Nature Communications. 11.1 (2020).

39 Tóth, Géza Entanglement detection and quantum metrology in quantum optical systems. Vol. PhD. Doctor of the Hung. Acad. of Sci., PhD., 2020.

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40 Tóth, Géza. "Stretching the limits of multiparticle entanglement." Quantum Views. 4 (2020): 30.

41 Tóth, Géza, et al. "Activating Hidden Metrological Usefulness." Physical Review Letters. 125.2 (2020).

42 Zheng, Di, et al. "Room temperature test of the continuous spontaneous localization model using a levitated micro-oscillator." Physical Review Research. 2.1 (2020).

Year of Publication: 2019

43 Tuncer, Aslı, et al. "Work and heat value of bound entanglement." Quantum Information Processing. 18.12 (2019).

44 Kohlrus, Jan, David Edward Bruschi, and Ivette Fuentes. "Quantum-metrology estimation of spacetime parameters of the Earth outperforming classical precision." Physical Review A. 99.3 (2019).

45 Bassi, Angelo Gravitational decoherence and gravitational-wave function collapse. Eds. Selim M. Shahriar, and Jacob Scheuer. Optical, Opto-Atomic, and Entanglement-Enhanced Precision MetrologyOptical, Opto-Atomic, and Entanglement-Enhanced Precision Metrology. San Francisco, United States: SPIE, 2019.

46 Paternostro, M, et al. "Out of equilibrium thermodynamics of quantum harmonic chains." Journal of Statistical Mechanics: Theory and Experiment. 2019.10 (2019): 104014.

47 Kovalenko, Olena, et al. "Feasibility of quantum key distribution with macroscopically bright coherent light." Optics Express. 27.25 (2019): 36154.

48 Dağ, Ceren B., et al. "Temperature Control in Dissipative Cavities by Entangled DimersTemperature Control in Dissipative Cavities by Entangled Dimers." The Journal of Physical Chemistry C. 123.7 (2019): 4035-4043.

49 Diósi, Lajos. "Spontaneous Wave Function Collapse with Frame Dragging and Induced Gravity." Quantum Reports. 1.2 (2019): 277-286.

50 Lorenzo, Salvatore, Mauro Paternostro, and Massimo G. Palma. "Reading a Qubit Quantum State with a Quantum Meter: Time Unfolding of Quantum Darwinism and Quantum Information Flux." Open Systems & Information Dynamics. 26.04 (2019): 1950023.

51 Curceanu, Catalina, et al. "Collapse models tested in the LNGS underground laboratories." International Journal of Quantum Information. 17.08 (2019): 1941011.

52 Manatuly, Angsar, et al. "Collectively enhanced thermalization via multiqubit collisions." Physical Review E. 99.4 (2019).

53 Branford, Dominic, et al. "Quantum enhanced estimation of diffusion." Physical Review A. 100.2 (2019).

54 Marton, J., et al. "VIP2 in LNGS - Testing the Pauli Exclusion Principle for electrons with high sensitivity." Journal of Physics: Conference Series. 1275 (2019): 012028.

55 Marton, J., et al. "VIP2 at Gran Sasso - Test of the validity of the spin statistics theorem for electrons with X-ray spectroscopy." Journal of Physics: Conference Series. 1342 (2019): 012087.

56 Diósi, Lajos. "Planck length challenges non-relativistic quantum mechanics of large masses." Journal of Physics: Conference Series. 1275 (2019): 012007.

57 Goldwater, Daniel, et al. "Quantum Spectrometry for Arbitrary Noise." Physical Review Letters. 123.23 (2019).

58 Carlesso, Matteo, and Angelo Bassi Current tests of collapse models: How far can we push the limits of quantum mechanics?. Quantum Information and MeasurementQuantum Information and Measurement (QIM) V: Quantum Technologies. RomeWashington, D.C.: OSA, 2019.

59 Ferialdi, Luca, et al. "Optimal control for feedback cooling in cavityless levitated optomechanics." New Journal of Physics. 21.7 (2019): 073019.

60 Ottaviani, Carlo, et al. "Multipartite entanglement swapping and mechanical cluster states." Physical Review A. 99.3 (2019).

61 Çakmak, Barış, et al. "Robust multipartite entanglement generation via a collision model." Physical Review A. 99.1 (2019).

62 Pezzutto, Marco, Mauro Paternostro, and Yasser Omar. "An out-of-equilibrium non-Markovian quantum heat engine." Quantum Science and Technology. 4.2 (2019): 025002.

63 Campbell, Steve, et al. "Collisional unfolding of quantum Darwinism." Physical Review A. 99.4 (2019).

64 Abah, Obinna, et al. "Energetic cost of quantum control protocols." New Journal of Physics. 21.10 (2019): 103048.

65 Rodrigues, Franklin L. S., et al. "Thermodynamics of Weakly Coherent Collisional Models." Physical Review Letters. 123.14 (2019).

66 Belenchia, Alessio, et al. "Talbot-Lau effect beyond the point-particle approximation." Physical Review A. 100.3 (2019).

67 Carlesso, Matteo, and Sandro Donadi Collapse Models: Main Properties and the State of Art of the Experimental Tests. Eds. Bassano Vacchini, Heinz-Peter Breuer, and Angelo Bassi. Vol. 237. Springer Proceedings in Physics, 237. Cham: Springer International Publishing, 2019.

68 Carlesso, Matteo, et al. "Testing the gravitational field generated by a quantum superposition." New Journal of Physics (2019).

69 Adler, Stephen L., et al. "Testing continuous spontaneous localization with Fermi liquids." Physical Review D. 99.10 (2019).

Year of Publication: 2018

70 Vostrosablin, Nikita, et al. "Quantum optomechanical transducer with ultrashort pulses." New Journal of Physics. 20.8 (2018): 083042.

71 Jacobsen, Christian S., et al. "Complete elimination of information leakage in continuous-variable quantum communication channels." npj Quantum Information. 4.1 (2018).

72 Hardal, Ali Ü. C., Mauro Paternostro, and Özgür E. Müstecaplıoğlu. "Phase-space interference in extensive and nonextensive quantum heat engines." Physical Review E. 97.4 (2018).

73 Marton, Johann, et al. STEAM-H: Science, Technology, Engineering, Agriculture, Mathematics & HealthQuantum Foundations, Probability and InformationUnderground Test of Quantum Mechanics: The VIP2 Experiment. Eds. Andrei Khrennikov, and Bourama Toni. Cham: Springer International Publishing, 2018.

74 Blair, Enrique P., Géza Tóth, and Craig S. Lent. "Entanglement loss in molecular quantum-dot qubits due to interaction with the environment." Journal of Physics: Condensed Matter. 30.19 (2018): 195602.

75 Bisztray, Tamas, and László Bacsárdi. "The Evolution of Free-Space Quantum Key Distribution." Infocommunications journal.1 (2018): 22-30.

76 Belenchia, Alessio, et al. "Quantum superposition of massive objects and the quantization of gravity." Physical Review D. 98.12 (2018).

77 Milotti, Edoardo, et al. "On the Importance of Electron Diffusion in a Bulk-Matter Test of the Pauli Exclusion Principle." Entropy. 20.7 (2018): 515.

78 Usenko, Vladyslav C.. "Unidimensional continuous-variable quantum key distribution using squeezed states." Physical Review A. 98.3 (2018).

79 Bruschi, David Edward, and André Xuereb. "‘Mechano-optics’: an optomechanical quantum simulator." New Journal of Physics. 20.6 (2018): 065004.

80 Usenko, Vladyslav C., et al. "Stabilization of transmittance fluctuations caused by beam wandering in continuous-variable quantum communication over free-space atmospheric channels." Optics Express. 26.24 (2018): 31106.

81 Shi, H., et al. "Search for the violation of Pauli Exclusion Principle at LNGS." EPJ Web of Conferences. 182 (2018): 02118.

82 Rashid, Muddassar, et al. "Precession Motion in Levitated Optomechanics." Physical Review Letters. 121.25 (2018).

83 Galambos, Máté, and László Bacsárdi. "Comparing Calculated and Measured Losses in a Satellite-Earth Quantum Channel." Infocommunications journal.3 (2018): 14-19.

84 Toroš, Marko, Muddassar Rashid, and Hendrik Ulbricht. "Detection of anisotropic particles in levitated optomechanics." Physical Review A. 98.5 (2018).

85 Brunelli, Matteo, et al. "Unconditional preparation of nonclassical states via linear-and-quadratic optomechanics." Physical Review A. 98.6 (2018).

86 Apellaniz, Iagoba, et al. "Precision bounds for gradient magnetometry with atomic ensembles." Physical Review A. 97.5 (2018).

87 Diósi, Lajos. "Normal Ordering the Squeeze Operator by Generalized Wick Theorem." Journal of Russian Laser Research. 39.4 (2018): 349-352.

88 Diósi, Lajos. "Wick theorem for all orderings of canonical operators." Journal of Physics A: Mathematical and Theoretical. 51.36 (2018): 365201.

89 Diósi, Lajos. "Fundamental Irreversibility: Planckian or Schrödinger–Newton?" Entropy. 20.7 (2018): 496.

90 Nobakht, J., et al. "Unitary unraveling for the dissipative continuous spontaneous localization model: Application to optomechanical experiments." Phys. Rev. A. 98 (2018): 042109.

91 Carlesso, Matteo, Luca Ferialdi, and Angelo Bassi. "Colored collapse models from the non-interferometric perspective." The European Physical Journal D. 72.9 (2018).

92 Carlesso, Matteo, et al. "Non-interferometric test of the continuous spontaneous localization model based on rotational optomechanics." New Journal of Physics. 20.8 (2018): 083022.

93 Carlesso, Matteo, Andrea Vinante, and Angelo Bassi. "Multilayer test masses to enhance the collapse noise." Physical Review A. 98.2 (2018).

94 Lange, Karsten, et al. "Entanglement between two spatially separated atomic modes." Science. 360 (2018): 416.

95 Vitagliano, Giuseppe, et al. "Entanglement and extreme planar spin squeezing." Phys. Rev. A. 97.2 (2018): 020301.

96 Tóth, Géza, and Tamas Vertesi. "Quantum States with a Positive Partial Transpose are Useful for Metrology." Physical Review Letters. 120.2 (2018): 020506.

Year of Publication: 2017

97 Curceanu, C, et al. "Underground tests of quantum mechanics. Whispers in the cosmic silence?" Journal of Physics: Conference Series. 880 (2017): 012045.

98 Marton, J., et al. "VIP-2 at LNGS: An experiment on the validity of the Pauli Exclusion Principle for electrons." Journal of Physics: Conference Series. 873 (2017): 012018.

99 Curceanu, Catalina, et al. "Test of the Pauli Exclusion Principle in the VIP-2 Underground Experiment." Entropy. 19.7 (2017): 300.

100 Piscicchia, Kristian, et al. "CSL Collapse Model Mapped with the Spontaneous Radiation." Entropy. 19.7 (2017): 319.

101 Bose, Sougato, et al. "Spin Entanglement Witness for Quantum Gravity." Physical Review Letters. 119.24 (2017).

102 Diósi, Lajos. "Centre of mass decoherence due to time dilation: paradoxical frame-dependence." Journal of Physics: Conference Series. 880 (2017): 012020.

103 Diósi, Lajos, and Antoine Tilloy. "On GKLS Dynamics for Local Operations and Classical Communication." Open Systems & Information Dynamics. 24.04 (2017): 1740020.

104 Tilloy, Antoine, and Lajos Diósi. "Principle of least decoherence for Newtonian semiclassical gravity." Physical Review D. 96.10 (2017).

105 Homa, Gábor, and Lajos Diósi. "On the earliest jump unravelling of the spatial decoherence master equation." Physics Letters A. 381.40 (2017): 3456-3459.

106 Diósi, Lajos. "New results on non-CP dynamics unearthed from urtexts of quantum state diffusion." Journal of Physics A: Mathematical and Theoretical. 50.16 (2017): 16LT01.

107 Apellaniz, Iagoba, et al. "Optimal witnessing of the quantum Fisher information with few measurements." Physical Review A. 95.3 (2017): 032330.

108 Vitagliano, Giuseppe, et al. "Entanglement and extreme spin squeezing of unpolarized states." New Journal of Physics. 19.1 (2017): 013027.

109 Li, Jie, et al. "Enhanced entanglement of two different mechanical resonators via coherent feedback." Physical Review A. 95.4 (2017): 043819.

110 Rossi, Massimiliano, et al. "Enhancing Sideband Cooling by Feedback-Controlled Light." Physical Review Letters. 119.12 (2017): 123603.

Year of Publication: 2016

111 Altenburg, Sanah, et al. "Optimized parameter estimation in the presence of collective phase noise." Physical Review A. 94.5 (2016).