X rays on quantum mechanics: Pauli Exclusion Principle and collapse models at test

By performing X-ray measurements in the “cosmic silence” of the underground laboratory of Gran Sasso, LNGS-INFN, we test a basic principle of quantum mechanics: the Pauli Exclusion Principle (PEP) for electrons. We present the achieved results of the VIP experiment and the ongoing VIP2 measurement aiming to gain two orders of magnitude improvement in testing PEP. X-ray emission can also be used to put strong constraints on the parameters of the Continuous Spontaneous Localization Model, which was introduced as a possible solution to the measurement problem in Quantum Mechanics. A Bayesian analysis of the data collected by IGEX will be presented, which allows to exclude a broad region of the parameter space which characterizes this model.

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EXPERIMENTAL TESTS OF QUANTUM MECHANICS PAULI EXCLUSION PRINCIPLE VIOLATION (THE VIP EXPERIMENT) AND FUTURE PERSPECTIVES

International Journal of Quantum Information ◽

10.1142/s0219749911007162 ◽

2011 ◽

Vol 09 (supp01) ◽

pp. 145-154 ◽

Cited By ~ 9

Author(s):

C. CURCEANU (PETRASCU) ◽

S. BARTALUCCI ◽

M. BRAGADIREANU ◽

C. GUARALDO ◽

M. ILIESCU ◽

...

Keyword(s):

Experimental Technique ◽

Experimental Tests ◽

Pauli Exclusion Principle ◽

Exclusion Principle ◽

Mathematical Framework ◽

X Rays ◽

A Value ◽

Collapse Models ◽

Modern Physics ◽

Lively Debate

The Pauli exclusion principle (PEP) is one of the basic principles of modern physics. Being at the very basis of our understanding of matter, as many other fundamental principles it spurs, presently, a lively debate on its possible limits, deeply rooted in the very foundations of Quantum Field Theory. Therefore, it is extremely important to test the limits of its validity. Quon theory provides a suitable mathematical framework of possible violation of PEP, where the violation parameter q translates into a probability of violating PEP. Experimentally, setting a bound on PEP violation means confining the violation parameter to a value very close to either 1 (for bosons) or -1 (for fermions). The VIP (VIolation of the Pauli exclusion principle) experiment established a limit on the probability that PEP is violated by electrons, using the method of searching for PEP forbidden atomic transitions in copper. We describe the experimental method, the obtained results, both in terms of the q-parameter from quon theory and as probability of PEP violation, we briefly discuss them and present future plans to go beyond the actual limit by upgrading the experimental technique using vetoed new spectroscopical fast Silicon Drift Detectors. We also shortly mention the possibility of using a similar experimental technique to search for eventual X-rays, generated in the spontaneous collapse models.

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A glimpse into the Pandora box of the quantum mechanics: The Pauli exclusion principle violation and spontaneous collapse models put at test

10.1063/1.4773125 ◽

2012 ◽

Cited By ~ 2

Author(s):

C. Curceanu (Petrascu) ◽

S. Bartalucci ◽

A. Bassi ◽

S. Bertolucci ◽

M. Bragadireanu ◽

...

Keyword(s):

Quantum Mechanics ◽

Pauli Exclusion Principle ◽

Exclusion Principle ◽

Collapse Models

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The X-ray machine for the examination of quantum mechanics

International Journal of Quantum Information ◽

10.1142/s0219749916400177 ◽

2016 ◽

Vol 14 (04) ◽

pp. 1640017 ◽

Cited By ~ 2

Author(s):

Catalina Curceanu ◽

Sergio Bartalucci ◽

Angelo Bassi ◽

Massimiliano Bazzi ◽

Sergio Bertolucci ◽

...

Keyword(s):

Wave Function ◽

Quantum Mechanics ◽

Pauli Exclusion Principle ◽

Exclusion Principle ◽

X Rays ◽

X Ray ◽

The Future ◽

Spontaneous Localization ◽

Continuous Spontaneous Localization ◽

Future Plans

By performing X-rays measurements in the underground laboratory of Gran Sasso, LNGS-INFN, we test a basic principle of quantum mechanics: the Pauli exclusion principle (PEP). In the future, we aim to use a similar experimental technique to search for X-rays as a signature of the spontaneous collapse of the wave function predicted by continuous spontaneous localization theories. We present the achieved results of the VIP experiment and the future plans to gain two orders of magnitude in testing PEP with the recently VIP2 setup installed at Gran Sasso.

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VIP: AN EXPERIMENT TO SEARCH FOR A VIOLATION OF THE PAULI EXCLUSION PRINCIPLE

International Journal of Modern Physics A ◽

10.1142/s0217751x07035392 ◽

2007 ◽

Vol 22 (02n03) ◽

pp. 242-248 ◽

Cited By ~ 5

Author(s):

E. Milotti ◽

S. Bartalucci ◽

S. Bertolucci ◽

M. Bragadireanu ◽

M. Cargnelli ◽

...

Keyword(s):

Quantum Mechanics ◽

Basic Principle ◽

Pauli Exclusion Principle ◽

Experimental Results ◽

Underground Laboratory ◽

Exclusion Principle

The Pauli Exclusion Principle is a basic principle of Quantum Mechanics, and its validity has never been seriously challenged. However, given its fundamental standing, it is very important to check it as thoroughly as possible. Here we describe the VIP (VIolation of the Pauli exclusion principle) experiment, an improved version of the Ramberg and Snow experiment (E. Ramberg and G. Snow, Phys. Lett. B238, 438 (1990)); VIP has just completed the installation at the Gran Sasso underground laboratory, and aims to test the Pauli Exclusion Principle for electrons with unprecedented accuracy, down to β2/2 ≈ 10-30 - 10-31. We report preliminary experimental results and briefly discuss some of the implications of a possible violation.

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Quantum Mechanics and the Periodic Table

The Periodic Table ◽

10.1093/oso/9780190914363.003.0014 ◽

2019 ◽

Author(s):

Eric Scerri

Keyword(s):

Quantum Mechanics ◽

Quantum Theory ◽

Periodic Table ◽

Chemical Properties ◽

Pauli Exclusion Principle ◽

Niels Bohr ◽

Exclusion Principle ◽

Old Quantum Theory ◽

Set Up ◽

Three Body

In chapter 7, the influence of the old quantum theory on the periodic system was considered. Although the development of this theory provided a way of reexpressing the periodic table in terms of the number of outer-shell electrons, it did not yield anything essentially new to the understanding of chemistry. Indeed, in several cases, chemists such as Irving Langmuir, J.D. Main Smith, and Charles Bury were able to go further than physicists in assigning electronic configurations, as described in chapter 8, because they were more familiar with the chemical properties of individual elements. Moreover, despite the rhetoric in favor of quantum mechanics that was propagated by Niels Bohr and others, the discovery that hafnium was a transition metal and not a rare earth was not made deductively from the quantum theory. It was essentially a chemical fact that was accommodated in terms of the quantum mechanical understanding of the periodic table. The old quantum theory was quantitatively impotent in the context of the periodic table since it was not possible to even set up the necessary equations to begin to obtain solutions for the atoms with more than one electron. An explanation could be given for the periodic table in terms of numbers of electrons in the outer shells of atoms, but generally only after the fact. But when it came to trying to predict quantitative aspects of atoms, such as the ground-state energy of the helium atom, the old quantum theory was quite hopeless. As one physicist stated, “We should not be surprised . . . even the astronomers have not yet satisfactorily solved the three-body problem in spite of efforts over the centuries.” A succession of the best minds in physics, including Hendrik Kramers, Werner Heisenberg, and Arnold Sommerfeld, made strenuous attempts to calculate the spectrum of helium but to no avail. It was only following the introduction of the Pauli exclusion principle and the development of the new quantum mechanics that Heisenberg succeeded where everyone else had failed.

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