Giacomo Mauro D'Ariano

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Giacomo Mauro D'Ariano
Giacomo Mauro D'Ariano.jpg
Born
Giacomo Mauro D'Ariano

(1955-05-11)May 11, 1955
Alessandria, Italy
Scientific career
Fields Theoretical physics
Institutions University of Pavia
Northwestern University
Academic advisorsFerdinando Borsa

Giacomo Mauro D'Ariano (born 11 May 1955) is an Italian quantum physicist. He is a professor of theoretical physics at the University of Pavia, where he is the leader of the QUIT (Quantum Information Theory) group. [1] [2] He is a member of the Center of Photonic Communication and Computing at Northwestern University; [3] a member of the Istituto Lombardo Accademia di Scienze e Lettere; and a member of the Foundational Questions Institute (FQXi). [4]

Contents

His primary areas of research are Quantum information theory, the mathematical structure of quantum theory, and foundational problems of contemporary physics. [5] As one of the pioneers of Quantum Information Theory, he has made major contributions to the informational-theoretical derivation of Quantum Theory. [6]

Early life and career

D'Ariano was born on 11 May 1955. He got Laurea cum laude in Physics in 1978 from Pavia University. In 1978, he started a research fellowship in Polymer Science at Politecnico di Milano and in 1979, a research fellowship at Pavia University. In 1984, he was appointed as research assistant at the University of Pavia and as a result of national competitions he became associate professor in 1992 and full professor in 2000. [7]

At the time of his appointment, there were no PhD schools in Italy [8] and D'Ariano became one of the first PhD supervisors in the country. He founded the Quantum Information Theory Group (QUIT) in 2000 and took on the role of the group leader. In the same year, he was also selected as a member of the Photonic Communication and Computing at Northwestern University. [3]

Work

Quantum foundations

D'Ariano has played a major role in making quantum information theory a new paradigm for the foundations of quantum theory and fundamental physics in general. In 2010, he proposed a set of information-theoretical postulates for a rigorous derivation of (finite-dimensional) Quantum Theory, [9] a derivation subsequently achieved in his collaboration with Giulio Chiribella and Paolo Perinotti. [10] This project also led to a new way of understanding, working with, and developing quantum theory, presented in a comprehensive textbook entitled Quantum Theory from First Principles. [11]

In the mid 2010s, D'Ariano extended this program to a derivation of Quantum Field Theory from informational-theoretical postulates, which enabled him and his team to derive the complete free Quantum field theory. [12] A historical perspective, from Dirac's discovery of quantum electrodynamics to the present time, on this work was given by Arkady Plotnitsky in The Principles of Quantum Theory, From Planck's Quanta to the Higgs Boson. [13] In an article in New Scientist, Lucien Hardy wrote that "their work and their approach is extraordinary", and Časlav Brukner wrote that he was "impressed" by their work writing that "there's something deep about quantum mechanics in this work". [14]

A book by Oliver Darrigol offers an extensive commentary on D'Ariano and co-workers' derivation of Quantum Mechanics, especially emphasizing how it overcomes certain ad hoc assumptions of previous derivations. [15]

On the formulation of quantum theory based on information principles, physicist Federico Faggin based his theory on the nature of consciousness. [16]

Quantum information

D'Ariano and his collaborators introduced the first exact algorithm for quantum homodyne tomography of states, [17] and they subsequently generalized the technique used to do to a universal method of quantum measurement. [18] D'Ariano then developed the first experimental scheme—now called "ancilla-assisted tomography"—that made the characterization of quantum channels, operations, and measuring apparatuses feasible to be actually done in the laboratory, by exploiting a single entangled input state. [19]

D'Ariano proposed quantum entanglement as a tool for improving the precision of quantum measurement, [20] an idea that, parallel to works of other authors, suggested the new field of Quantum metrology. He has also introduced several new types of measurement. With his team, he solved a number of long-standing problems of quantum information theory, such as the optimal broadcasting of mixed states; [21] the optimal phase-estimation for mixed states, [22] and the optimal protocols for phase cloning. [23]

D'Ariano and collaborators introduced the concept of "quantum comb", [24] which generalizes that of "quantum operation", and has a wide range of applications in optimization of quantum measurements, communication, algorithms, and protocols. He and his group subsequently used quantum combs to find the optimal apparatuses for Quantum tomography. [25] The quantum-comb framework also enabled a new understanding of causality in quantum mechanics and quantum field theory. This understanding had a wide and diverse impact in several areas of research, beginning with the study of quantum causal interference and causal-discovery algorithms, used in recent attempts, along quantum informational lines, at reconciling quantum theory and general relativity, one of the great outstanding problems of fundamental physics. [26]

Honors and awards

Giacomo Mauro D’Ariano is a Fellow of the Optical Society of America and of the American Physical Society. He won the third prize for the FQXi essay world competitions of 2011, [27] 2012 [28] and 2013. [29] His paper on the informational derivation of quantum theory [10] has been selected for an APS Viewpoint. [30]

Books

Related Research Articles

<span class="mw-page-title-main">Quantum entanglement</span> Correlation between measurements of quantum subsystems, even when spatially separated

Quantum entanglement is the phenomenon that occurs when a group of particles are generated, interact, or share spatial proximity in a way such that the quantum state of each particle of the group cannot be described independently of the state of the others, including when the particles are separated by a large distance. The topic of quantum entanglement is at the heart of the disparity between classical and quantum physics: entanglement is a primary feature of quantum mechanics not present in classical mechanics.

Quantum Darwinism is a theory meant to explain the emergence of the classical world from the quantum world as due to a process of Darwinian natural selection induced by the environment interacting with the quantum system; where the many possible quantum states are selected against in favor of a stable pointer state. It was proposed in 2003 by Wojciech Zurek and a group of collaborators including Ollivier, Poulin, Paz and Blume-Kohout. The development of the theory is due to the integration of a number of Zurek's research topics pursued over the course of 25 years, including pointer states, einselection and decoherence.

<span class="mw-page-title-main">Quantum tomography</span> Reconstruction of quantum states based on measurements

Quantum tomography or quantum state tomography is the process by which a quantum state is reconstructed using measurements on an ensemble of identical quantum states. The source of these states may be any device or system which prepares quantum states either consistently into quantum pure states or otherwise into general mixed states. To be able to uniquely identify the state, the measurements must be tomographically complete. That is, the measured operators must form an operator basis on the Hilbert space of the system, providing all the information about the state. Such a set of observations is sometimes called a quorum. The term tomography was first used in the quantum physics literature in a 1993 paper introducing experimental optical homodyne tomography.

<span class="mw-page-title-main">Topological order</span> Type of order at absolute zero

In physics, topological order is a kind of order in the zero-temperature phase of matter. Macroscopically, topological order is defined and described by robust ground state degeneracy and quantized non-Abelian geometric phases of degenerate ground states. Microscopically, topological orders correspond to patterns of long-range quantum entanglement. States with different topological orders cannot change into each other without a phase transition.

In physics, the no-broadcasting theorem is a result of quantum information theory. In the case of pure quantum states, it is a corollary of the no-cloning theorem. The no-cloning theorem for pure states says that it is impossible to create two copies of an unknown state given a single copy of the state. Since quantum states cannot be copied in general, they cannot be broadcast. Here, the word "broadcast" is used in the sense of conveying the state to two or more recipients. For multiple recipients to each receive the state, there must be, in some sense, a way of duplicating the state. The no-broadcast theorem generalizes the no-cloning theorem for mixed states.

Quantum cloning is a process that takes an arbitrary, unknown quantum state and makes an exact copy without altering the original state in any way. Quantum cloning is forbidden by the laws of quantum mechanics as shown by the no cloning theorem, which states that there is no operation for cloning any arbitrary state perfectly. In Dirac notation, the process of quantum cloning is described by:

Objective-collapse theories, also known as models of spontaneous wave function collapse or dynamical reduction models, are proposed solutions to the measurement problem in quantum mechanics. As with other theories called interpretations of quantum mechanics, they are possible explanations of why and how quantum measurements always give definite outcomes, not a superposition of them as predicted by the Schrödinger equation, and more generally how the classical world emerges from quantum theory. The fundamental idea is that the unitary evolution of the wave function describing the state of a quantum system is approximate. It works well for microscopic systems, but progressively loses its validity when the mass / complexity of the system increases.

<span class="mw-page-title-main">Jens Eisert</span> German physicist

Jens Eisert is a German physicist, ERC fellow, and professor at the Free University of Berlin. He is also affiliated with the Helmholtz Association and the Fraunhofer Society.

In quantum information theory, quantum discord is a measure of nonclassical correlations between two subsystems of a quantum system. It includes correlations that are due to quantum physical effects but do not necessarily involve quantum entanglement.

<span class="mw-page-title-main">Sandu Popescu</span> British physicist

Sandu Popescu is a Romanian-British physicist working in the foundations of quantum mechanics and quantum information.

Continuous-variable (CV) quantum information is the area of quantum information science that makes use of physical observables, like the strength of an electromagnetic field, whose numerical values belong to continuous intervals. One primary application is quantum computing. In a sense, continuous-variable quantum computation is "analog", while quantum computation using qubits is "digital." In more technical terms, the former makes use of Hilbert spaces that are infinite-dimensional, while the Hilbert spaces for systems comprising collections of qubits are finite-dimensional. One motivation for studying continuous-variable quantum computation is to understand what resources are necessary to make quantum computers more powerful than classical ones.

Spin squeezing is a quantum process that decreases the variance of one of the angular momentum components in an ensemble of particles with a spin. The quantum states obtained are called spin squeezed states. Such states can be used for quantum metrology, as they can provide a better precision for estimating a rotation angle than classical interferometers.

Quantum foundations is a discipline of science that seeks to understand the most counter-intuitive aspects of quantum theory, reformulate it and even propose new generalizations thereof. Contrary to other physical theories, such as general relativity, the defining axioms of quantum theory are quite ad hoc, with no obvious physical intuition. While they lead to the right experimental predictions, they do not come with a mental picture of the world where they fit.

<span class="mw-page-title-main">Crispin Gardiner</span> New Zealand physicist

Crispin William Gardiner is a New Zealand physicist, who has worked in the fields of quantum optics, ultracold atoms and stochastic processes. He has written about 120 journal articles and several books in the fields of quantum optics, stochastic processes and ultracold atoms

Randomized benchmarking is an experimental method for measuring the average error rates of quantum computing hardware platforms. The protocol estimates the average error rates by implementing long sequences of randomly sampled quantum gate operations. Randomized benchmarking is the industry-standard protocol used by quantum hardware developers such as IBM and Google to test the performance of the quantum operations.

Applying classical methods of machine learning to the study of quantum systems is the focus of an emergent area of physics research. A basic example of this is quantum state tomography, where a quantum state is learned from measurement. Other examples include learning Hamiltonians, learning quantum phase transitions, and automatically generating new quantum experiments. Classical machine learning is effective at processing large amounts of experimental or calculated data in order to characterize an unknown quantum system, making its application useful in contexts including quantum information theory, quantum technologies development, and computational materials design. In this context, it can be used for example as a tool to interpolate pre-calculated interatomic potentials or directly solving the Schrödinger equation with a variational method.

Adrian Kent is a British theoretical physicist, Professor of Quantum Physics at the University of Cambridge, member of the Centre for Quantum Information and Foundations, and Distinguished Visiting Research Chair at the Perimeter Institute for Theoretical Physics. His research areas are the foundations of quantum theory, quantum information science and quantum cryptography. He is known as the inventor of relativistic quantum cryptography. In 1999 he published the first unconditionally secure protocols for bit commitment and coin tossing, which were also the first relativistic cryptographic protocols. He is a co-inventor of quantum tagging, or quantum position authentication, providing the first schemes for position-based quantum cryptography. In 2005 he published with Lucien Hardy and Jonathan Barrett the first security proof of quantum key distribution based on the no-signalling principle.

A generalized probabilistic theory (GPT) is a general framework to describe the operational features of arbitrary physical theories. A GPT must specify what kind of physical systems one can find in the lab, as well as rules to compute the outcome statistics of any experiment involving labeled preparations, transformations and measurements. The framework of GPTs has been used to define hypothetical non-quantum physical theories which nonetheless possess quantum theory's most remarkable features, such as entanglement or teleportation. Notably, a small set of physically motivated axioms is enough to single out the GPT representation of quantum theory.

The Eastin–Knill theorem is a no-go theorem that states: "No quantum error correcting code can have a continuous symmetry which acts transversely on physical qubits". In other words, no quantum error correcting code can transversely implement a universal gate set. Since quantum computers are inherently noisy, quantum error correcting codes are used to correct errors that affect information due to decoherence. Decoding error corrected data in order to perform gates on the qubits makes it prone to errors. Fault tolerant quantum computation avoids this by performing gates on encoded data. Transversal gates, which perform a gate between two "logical" qubits each of which is encoded in N "physical qubits" by pairing up the physical qubits of each encoded qubit, and performing independent gates on each pair, can be used to perform fault tolerant but not universal quantum computation because they guarantee that errors don't spread uncontrollably through the computation. This is because transversal gates ensure that each qubit in a code block is acted on by at most a single physical gate and each code block is corrected independently when an error occurs. Due to the Eastin–Knill theorem, a universal set like {H, S, CNOT, T} gates can't be implemented transversally. For example, the T gate can't be implemented transversely in the Steane code. This calls for ways of circumventing Eastin–Knill in order to perform fault tolerant quantum computation. In addition to investigating fault tolerant quantum computation, the Eastin–Knill theorem is also useful for studying quantum gravity via the AdS/CFT correspondence and in condensed matter physics via quantum reference frame or many-body theory.

Bound entanglement is a weak form of quantum entanglement, from which no singlets can be distilled with local operations and classical communication (LOCC).

References

  1. "QUIT".
  2. "Il teletrasporto passa dalla fisica quantistica". 28 April 2017.
  3. 1 2 "Center for Photonic Communication and Computing".
  4. "Curriculum vitae of GM D'Ariano".
  5. "Physicists Want To Rebuild Quantum Theory From Scratch". Wired. 2 September 2017.
  6. d'Ariano, Giacomo Mauro (2017). "Physics Without Physics: The Power of Information-theoretical Principles". International Journal of Theoretical Physics. 56 (1): 97–128. arXiv: 1701.06309 . Bibcode:2017IJTP...56...97D. doi:10.1007/s10773-016-3172-y. S2CID   119338397.
  7. "Biographical Sketch: Giacomo Mauro D'Ariano".
  8. "PhD Programs in Italy".
  9. "Philosophy of Quantum Information and Entanglement".
  10. 1 2 Chiribella, Giulio; d'Ariano, Giacomo Mauro; Perinotti, Paolo (2011). "Informational derivation of quantum theory". Physical Review A. 84 (1): 012311. arXiv: 1011.6451 . Bibcode:2011PhRvA..84a2311C. doi:10.1103/PhysRevA.84.012311. S2CID   15364117.
  11. "Review: Quantum Theory from First Principles". 12 July 2017. Archived from the original on 19 June 2018. Retrieved 18 December 2018.
  12. d'Ariano, Giacomo Mauro; Perinotti, Paolo (2014). "Derivation of the Dirac equation from principles of information processing". Physical Review A. 90 (6): 062106. arXiv: 1306.1934 . Bibcode:2014PhRvA..90f2106D. doi:10.1103/PhysRevA.90.062106. S2CID   118385875.
  13. The Principles of Quantum Theory, From Planck's Quanta to the Higgs Boson. Springer. 2016. ISBN   9783319320663.
  14. "Quantum purity".
  15. Physics and Necessity. Oxford University Press. 22 May 2014. ISBN   9780198712886.
  16. "Federico Faggin. Irriducibile - Filosofia". Rai Cultura (in Italian). Retrieved 27 April 2023.
  17. d'Ariano, G. M.; MacChiavello, C.; Paris, M. G. A. (1994). "Detection of the density matrix through optical homodyne tomography without filtered back projection". Physical Review A. 50 (5): 4298–4302. Bibcode:1994PhRvA..50.4298D. doi:10.1103/PhysRevA.50.4298. PMID   9911405.
  18. Hayashi, Masahito (2005). Asymptotic Theory of Quantum Statistical Inference. doi:10.1142/5630. ISBN   978-981-256-015-5.
  19. d'Ariano, G. M.; Lo Presti, P. (2001). "Quantum tomography for measuring experimentally the matrix elements of an arbitrary quantum operation". Physical Review Letters. 86 (19): 4195–8. arXiv: quant-ph/0012071 . Bibcode:2001PhRvL..86.4195D. doi:10.1103/PhysRevLett.86.4195. PMID   11328133. S2CID   119075753.
  20. d'Ariano, G. Mauro; Lo Presti, Paoloplacido; Paris, Matteo G. A. (2001). "Using Entanglement Improves the Precision of Quantum Measurements". Physical Review Letters. 87 (27): 270404. arXiv: quant-ph/0109040 . doi:10.1103/PhysRevLett.87.270404. PMID   11800863. S2CID   11199855.
  21. d'Ariano, Giacomo Mauro; MacChiavello, Chiara; Perinotti, Paolo (2005). "Superbroadcasting of Mixed States". Physical Review Letters. 95 (6): 060503. arXiv: quant-ph/0506251 . Bibcode:2005PhRvL..95f0503D. doi:10.1103/PhysRevLett.95.060503. PMID   16090933. S2CID   2978617.
  22. d'Ariano, Giacomo Mauro; MacChiavello, Chiara; Perinotti, Paolo (2005). "Optimal phase estimation for qubits in mixed states". Physical Review A. 72 (4): 042327. arXiv: quant-ph/0411133 . Bibcode:2005PhRvA..72d2327D. doi:10.1103/PhysRevA.72.042327. S2CID   117753018.
  23. d'Ariano, Giacomo Mauro; MacChiavello, Chiara (2003). "Optimal phase-covariant cloning for qubits and qutrits". Physical Review A. 67 (4): 042306. arXiv: quant-ph/0301175 . Bibcode:2003PhRvA..67d2306D. doi:10.1103/PhysRevA.67.042306. S2CID   119490312.
  24. Chiribella, G.; d'Ariano, G. M.; Perinotti, P. (2008). "Quantum Circuit Architecture". Physical Review Letters. 101 (6): 060401. arXiv: 0712.1325 . Bibcode:2008PhRvL.101f0401C. doi:10.1103/PhysRevLett.101.060401. PMID   18764438. S2CID   16160309.
  25. Bisio, A.; Chiribella, G.; d'Ariano, G. M.; Facchini, S.; Perinotti, P. (2009). "Optimal Quantum Tomography of States, Measurements, and Transformations". Physical Review Letters. 102 (1): 010404. arXiv: 0806.1172 . Bibcode:2009PhRvL.102a0404B. doi:10.1103/PhysRevLett.102.010404. PMID   19257173. S2CID   31954030.
  26. Brukner, Časlav (2014). "Quantum causality". Nature Physics. 10 (4): 259–263. Bibcode:2014NatPh..10..259B. doi:10.1038/nphys2930. S2CID   236500884.
  27. "A Quantum-Digital Universe".
  28. "Quantum-informational Principles for Physics".
  29. "It From Qubit".
  30. Brukner, Časlav (11 July 2011). "Viewpoint: Questioning the rules of the game". Physics. 4: 55. doi: 10.1103/Physics.4.55 .