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Accueil du site > Recrutement > Stages M2 / Thèses au LPT > Incompatibility of quantum measurements

Incompatibility of quantum measurements

par Ion Nechita - 7 décembre 2018

Toutes les versions de cet article : English , français

PhD advisor : Ion NECHITA

Email : nechita@irsamc.ups-tlse.fr

Web : http://ion.nechita.net/about/

One of the defining properties of quantum mechanics is the existence of incompatible observables, i.e. measurements that cannot be performed simultaneously, with the observables of position and momentum as a classic example. One of the central notions to capture this property of quantum mechanics is joint measurability or compatibility. Quantum measurements are compatible if they arise as marginals from a common measurement. Compatibility has practical implications for quantum information tasks [BCP+14], as only incompatible measurements can violate Bell inequalities. Therefore, incompatibility can be seen as a resource for quantum information tasks similar to entanglement [HMZ16]. It is well-known that incompatible measurements become compatible if enough noise is added to them. While many works study compatibility questions for concrete measurements, there has also been an interest in how much incompatibility there is in quantum mechanics and other generalized probabilistic theories [BHSS13].

The candidate will start with the study of the different examples of maximally incompatible sets of measurements in the literature. In the light of recent results in the field [BN18], many cases remain open, both in the binary situation (quantum effects) and in the general case. Using both numerical [BQG+17] and analytical methods, the candidate will investigate new cases of maximally incompatible quantum observables. The notions of mutually unbiased bases [WF89] and random quantum measurements [CN16] will certainly play an important role in this task.

The candidate should have a good grasp of quantum mechanics and linear algebra. Competences in quantum information theory, and scientific software (python or MATLAB) are useful (but not required, the missing ones will be acquired during the thesis).

References

  1. [BCP+14] Nicolas Brunner, Daniel Cavalcanti, Stefano Pironio, Valerio Scarani, and Stephanie Wehner. Bell nonlocality. Reviews of Modern Physics, 86(2):419, 2014.
  2. [BHSS13] Paul Busch, Teiko Heinosaari, Jussi Schultz, and Neil Stevens. Comparing the degrees of incompatibility inherent in probabilistic physical theories. EPL (Europhysics Letters), 103(1):10002, 2013.
  3. [BN18] Andreas Bluhm and Ion Nechita. Joint measurability of quantum effects and the matrix diamond. Journal of Mathe- matical Physics, 59(11):112202, 2018.
  4. [BQG+17] Jessica Bavaresco, Marco Tulio Quintino, Leonardo Guerini, Thiago O Maciel, Daniel Cavalcanti, and Marcelo Terra Cunha. Most incompatible measurements for robust steering tests. Physical Review A, 96(2):022110, 2017.
  5. [CN16] Benoit Collins and Ion Nechita. Random matrix techniques in quantum information theory. Journal of Mathematical Physics, 57(1), 2016.
  6. [HMZ16] Teiko Heinosaari, Takayuki Miyadera, and Mario Ziman. An invitation to quantum incompatibility. Journal of Physics A : Mathematical and Theoretical, 49(12):123001, 2016.
  7. [WF89] William K Wootters and Brian D Fields. Optimal state-determination by mutually unbiased measurements. Annals of Physics, 191(2):363-381, 1989.