2019-01-18

ION HANCU

ION HANCU

2019-01-29

MARIA MAFFEI

MARIA MAFFEI

2019-02-13

BORIS BOURDONCLE

BORIS BOURDONCLE

2019-02-15

JORDI MORALES DALMAU

JORDI MORALES DALMAU

2019-02-22

FRANCESCO RICCI

FRANCESCO RICCI

2019-03-06

CLARA GREGORI

CLARA GREGORI

2019-03-26

ALEXIA SALAVRAKOS

ALEXIA SALAVRAKOS

2019-04-12

SENAIDA HERNANDEZ SANTANA

SENAIDA HERNANDEZ SANTANA

2019-04-15

DAVID RAVENTÓS RIBERA

DAVID RAVENTÓS RIBERA

2019-04-16

PETER SCHMIDT

PETER SCHMIDT

2019-04-29

CALLUM O’DONNELL

CALLUM O’DONNELL

2019-05-02

LUCIANA VIDAS

LUCIANA VIDAS

2019-05-03

HANYU YE

HANYU YE

2019-05-10

TANJA DRAGOJEVIC

TANJA DRAGOJEVIC

2019-05-17

FLAVIO BACCARI

FLAVIO BACCARI

2019-06-04

MARTINA GIOVANNELLA

MARTINA GIOVANNELLA

2019-07-02

OZLEM YAVAS

OZLEM YAVAS

2019-07-03

ALESSANDRO SERI

ALESSANDRO SERI

2019-07-11

RENWEN YU

RENWEN YU

2019-09-06

ALEXANDER BLOCK

ALEXANDER BLOCK

2019-10-04

MARCO PAGLIAZZI

MARCO PAGLIAZZI

### Bell Inequalities for Device-Independent Protocols

ALEXIA SALAVRAKOS

**March 26th, 2019**

**ALEXIA SALAVRAKOS**

**Quantum Information Theory**

ICFO-The Institute of Photonic Sciences

ICFO-The Institute of Photonic Sciences

The technological era that we live in is sometimes described as the Information Age. Colossal amounts of data are generated every day and considerable effort is put into creating technologies to process, store and transmit information in a secure way. Quantum Information Science relies on quantum systems to develop new information technologies by exploiting the non-classical properties of those systems, such as entanglement or superposition. Quantum computing has recently received substantial investment, and quantum random number generators and cryptography systems are already available commercially.

Entanglement is one of the counter-intuitive, mysterious phenomena that quantum theory is known to describe. Two entangled particles are such that, even when they are spatially separated, their quantum state can only be described for the system as a whole, and not as two independent quantum states.

This implies that when making measurements on entangled particles, particular correlations between the measurement outcomes may appear which cannot be obtained with pre-shared classical information. Such correlations, termed nonlocal, can be detected using mathematical objects called Bell inequalities, that correspond to hyperplanes in the set of correlations obtained in a so-called Bell scenario. Many Bell experiments were conducted in which violations of Bell inequalities were measured, thus confirming the existence of nonlocality in Nature.

The last decade has seen the development of a new paradigm in quantum information theory, called the device-independent paradigm. The security and success of a device-independent protocol relies on the observation of nonlocal correlations in a Bell experiment. Moreover, the nature of Bell scenarios is such that very few assumptions on the experimental apparatus are needed, hence the name device-independent. In this framework, Bell inequalities serve as certificates that guarantee properties and quantities such as the randomness of a series of numbers or the security of a secret key shared between users. It is even possible to certify which quantum state and measurements were used in the experiment based solely on the correlations they produce: this task is called self-testing.

The goal of this thesis is the study of Bell inequalities, both as fundamental objects and as tools for device-independent protocols. We consider in particular protocols for randomness certification, quantum key distribution and self-testing.

In Chapter 3, we develop robust self-testing procedures for the chained Bell inequalities, which also imply randomness certification. The chained Bell inequalities are a family of Bell inequalities that are relevant for a scenario with an arbitrary number of measurement choices. In Chapter 4, we introduce a family of Bell inequalities maximally violated by the maximally entangled states, valid for a scenario with any number of measurement choices as well as any number of measurement outcomes. We study the properties of these Bell inequalities in depth, and discuss through examples their applications to self-testing, randomness certification and quantum key distribution. We also present an extension of our results to any number of parties, as well as experimental results obtained in an international collaboration, where we measure violations of our Bell inequalities for local dimension up to 15. In Chapter 5, we consider the question of randomness certification from partially entangled states. We show, through self-testing results, that maximal randomness can be certified from any partially entangled state of two qubits, using the Clauser-Horne-Shimony-Holt inequality and its tilted version.

Tuesday, March 26, 11:00. ICFO Auditorium

Thesis Advisor: Prof Dr Antonio Acín

Tuesday, March 26, 11:00. ICFO Auditorium

Thesis Advisor: Prof Dr Antonio Acín