Publications

Year of Publication: 2021

1 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).
2 Gaona-Reyes, L., M. Carlesso, and A. Bassi. "Gravitational interaction through a feedback mechanism." Physical Review D. 1032.5 (2021).
3 Carlesso, Matteo, Hamid Reza Naeij, and Angelo Bassi. "Perturbative algorithm for rotational decoherence." Physical Review A. 103.3 (2021).
4 Gundhi, Anirudh, Sergei V. Ketov, and Christian F. Steinwachs. "Primordial black hole dark matter in dilaton-extended two-field Starobinsky inflation." Physical Review D. 103674314.8 (2021).
5 Rijavec, Simone, et al. "Decoherence effects in non-classicality tests of gravity." New Journal of Physics. 23.4 (2021): 043040.

Year of Publication: 2020

6 Zheng, Di, et al. "Room temperature test of the continuous spontaneous localization model using a levitated micro-oscillator." Physical Review Research. 2.1 (2020).
7 Gundhi, Anirudh, and Christian F. Steinwachs. "Scalaron-Higgs inflation." Nuclear Physics B. 954 (2020): 114989.
8 Vinante, A., et al. "Narrowing the Parameter Space of Collapse Models with Ultracold Layered Force Sensors." Physical Review Letters. 125.10 (2020).
9 Donadi, Sandro, et al. "Underground test of gravity-related wave function collapse." Nature Physics (2020).

Year of Publication: 2019

10 Adler, Stephen L., et al. "Testing continuous spontaneous localization with Fermi liquids." Physical Review D. 99.10 (2019).
11 Carlesso, Matteo, et al. "Testing the gravitational field generated by a quantum superposition." New Journal of Physics (2019).
12 Carlesso, Matteo, and Sandro Donadi Collapse Models: Main Properties and the State of Art of the Experimental Tests. Vol. 23762. Springer Proceedings in Physics, 23762. Cham: Springer International Publishing, 2019.

Year of Publication: 2018

13 Carlesso, Matteo, A. Vinante, and Angelo Bassi. "Multilayer test masses to enhance the collapse noise." Physical Review A. 98B15.2 (2018).
14 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.
15 Carlesso, Matteo, L. Ferialdi, and Angelo Bassi. "Colored collapse models from the non-interferometric perspective." The European Physical Journal D. 72.9 (2018).
16 Nobakht, J., et al. "Unitary unraveling for the dissipative continuous spontaneous localization model: Application to optomechanical experiments." Phys. Rev. A. 98 (2018): 042109.

Year of Publication: 2017

17 McMillen, S., et al. "Quantum-limited estimation of continuous spontaneous localization." Physical Review A. 95.1 (2017).
18 Carlesso, Matteo, and Angelo Bassi. "Adjoint master equation for quantum Brownian motion." Physical Review A. 95.5 (2017).
19 Gasbarri, Giulio, Marko Toroš, and Angelo Bassi. "General Galilei Covariant Gaussian Maps." Physical Review Letters. 119.10 (2017).
20 Vinante, A., et al. "Improved Noninterferometric Test of Collapse Models Using Ultracold Cantilevers." Physical Review Letters. 119.11 (2017).
21 Bassi, Angelo, André Großardt, and H. Ulbricht. "Gravitational decoherence." Classical and Quantum Gravity. 34.19 (2017): 193002.
22 Piscicchia, Kristian, et al. "CSL Collapse Model Mapped with the Spontaneous Radiation." Entropy. 19Volume 526.7 (2017): 319.
23 Bilardello, Marco, A. Trombettoni, and Angelo Bassi. "Collapse in ultracold Bose Josephson junctions." Physical Review A. 95.3 (2017).
24 Caiaffa, Matteo, A. Smirne, and Angelo Bassi. "Stochastic unraveling of positive quantum dynamics." Physical Review A. 95206362.6 (2017).
25 Toroš, Marko, Giulio Gasbarri, and Angelo Bassi. "Colored and dissipative continuous spontaneous localization model and bounds from matter-wave interferometry." Physics Letters A (2017).
26 Gasbarri, Giulio, et al. "Gravity induced wave function collapse." Physical Review D. 96506291.10 (2017).

Year of Publication: 2016

27 Carlesso, Matteo, and Angelo Bassi. "Decoherence due to gravitational time dilation: Analysis of competing decoherence effects." Physics Letters A. 380.31-32 (2016): 2354-2358.
28 Vinante, A., et al. "Upper Bounds on Spontaneous Wave-Function Collapse Models Using Millikelvin-Cooled Nanocantilevers." Physical Review Letters. 116.9 (2016).
29 Großardt, André, et al. "Optomechanical test of the Schrödinger-Newton equation." Physical Review D. 93.9 (2016).
30 Großardt, André. "Approximations for the free evolution of self-gravitating quantum particles." Phys. Rev. A. 94 (2016): 022101.
31 Adler, Stephen L., and Angelo Bassi. "Gravitational decoherence for mesoscopic systems." Physics Letters A. 380.3 (2016): 390-393.
32 Bilardello, Marco, et al. "Bounds on collapse models from cold-atom experiments." Physica A: Statistical Mechanics and its Applications. 462 (2016): 764-782.
33 Toroš, Marko, S. Di Matteo, and Angelo Bassi. "Bohmian mechanics, collapse models and the emergence of classicality." Journal of Physics A: Mathematical and Theoretical. 49.35 (2016): 355302.
34 Belli, Sebastiano, et al. "Entangling macroscopic diamonds at room temperature: Bounds on the continuous-spontaneous-localization parameters." Physical Review A. 94.1 (2016).
35 Kaltenbaek, Rainer, et al. "Macroscopic Quantum Resonators (MAQRO): 2015 update." EPJ Quantum Technology. 3.1 (2016).
36 Großardt, André, et al. "Effects of Newtonian gravitational self-interaction in harmonically trapped quantum systems." Scientific Reports. 6 (2016): 30840.
37 Bassi, Angelo. "Models of spontaneous wave function collapse: what they are, and how they can be tested." Journal of Physics: Conference Series. 701 (2016): 012012.
38 Curceanu, C., et al. "Spontaneously Emitted X-rays: An Experimental Signature of the Dynamical Reduction Models." Foundations of Physics. 46.3 (2016): 263-268.
39 Curceanu, C., et al. "The X-ray machine for the examination of quantum mechanics." International Journal of Quantum Information. 14.04 (2016): 1640017.
40 Carlesso, Matteo, et al. "Experimental bounds on collapse models from gravitational wave detectors." Physical Review D. 94.12 (2016).

Year of Publication: 2015

41 Curceanu, C., et al. "Experimental search for the “impossible atoms” Pauli Exclusion Principle violation and spontaneous collapse of the wave function at test." Journal of Physics: Conference Series. 626 (2015): 012027.
42 Bahrami, M., and Angelo Bassi. "Proposing new experiments to test the quantum-to-classical transition." Journal of Physics: Conference Series. 626 (2015): 012006.
43 Großardt, André, and Beatrix Hiesmayr. "Newtonian self-gravitation in the neutral meson system." Phys. Rev. D. 91 (2015): 064056.
44 Bassi, Angelo, and Kasra Hejazi. "No-faster-than-light-signaling implies linear evolution. A re-derivation." European Journal of Physics. 36.5 (2015): 055027.
45 Curceanu, C., et al. "X rays on quantum mechanics: Pauli Exclusion Principle and collapse models at test." Journal of Physics: Conference Series. 631 (2015): 012068.
46 Bassi, Angelo, Saikat Ghosh, and Tejinder Singh The Frontiers Collection It From Bit or Bit From It? Information and the Foundations of Quantum Theory. Eds. Anthony Aguirre, Brendan Foster, and Zeeya Merali. Cham: Springer International Publishing, 2015.
47 Bahrami, M., et al. "Is Gravity Quantum?" (2015).
48 Bassi, Angelo. "Gravity: Wanna be quantum." Nature Physics. 11.8 (2015): 626-627.
49 Gasbarri, Giulio, S. Di Matteo, and Angelo Bassi. "Coherent scattering in non relativistic quantum mechanics." European Journal of Physics. 36.5 (2015): 055038.
50 Curceanu, C., et al. "Quantum explorations: from the waltz of the Pauli exclusion principle to the rock of the spontaneous collapse." Physica Scripta. 90.2 (2015): 028003.

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