A 100% online professional master’s degree, with a syllabus available 24 hours a day, so that you can advance whenever you wish in the key concepts of Quantum Physics"

The research field of Quantum Physics offers a wide range of lines of development with great potential for engineering professionals who decide to delve into this field of exploration and discovery in energy production, ultracold atoms, trapped ions or photonics.

Recent advances in this field have opened multiple lines of study and actions in other disciplines such as astrophysics, cosmology, chemistry, biology, medicine or artificial intelligence: possibilities as vast as the universe. That is why TECH has designed this professional master’s degree in Quantum Physics, which will allow graduates to achieve, in only 12 months, the most advanced knowledge about the most common physical processes in planetary and solar physics, the studies of Paul Dirac or Richard Feynman and quantum field theory.

All this, through a program taught exclusively online, which will allow them to delve, whenever they wish, into Einstein's equations, Schwarzschild's solution, dark matter and energies or the thermodynamics of the early universe. The case studies will also help them to integrate the practice into their daily professional work.

This academic institution thus offers an excellent opportunity for engineering specialists who wish to progress in their professional career through a quality university education that is compatible with their work and/or personal responsibilities. They only need an electronic device with an Internet connection to view the content hosted on the virtual platform. With no classroom attendance or fixed class schedules, students have the freedom to distribute the course load according to their needs.

Thanks to the knowledge acquired in this professional master’s degree you will be able to contribute to solve the problems of dark matter" 

This professional master’s degree in Quantum Physics contains the most complete and up-to-date program on the market. The most important features include:

• Practical case studies are presented by experts in Physics
• The graphic, schematic, and practical contents with which they are created, provide scientific and practical information on the disciplines that are essential for professional practice
• Practical exercises where the self-assessment process can be carried out to improve learning
• Its special emphasis on innovative methodologies 
• Theoretical lessons, questions to the expert, debate forums on controversial topics, and individual reflection assignments
• Content that is accessible from any fixed or portable device with an Internet connection

The library of multimedia resources of this course will allow you to learn the main contributions to Quantum Physics from Richard Feynman, Paul Dirac, Peter Higgs or Schrödinger”

The program includes, in its teaching staff, professionals from the sector who bring to this program the experience of their work, in addition to recognized specialists from prestigious reference societies and universities. 

Its multimedia content, developed with the latest educational technology, will allow professionals to learn in a contextual and situated learning environment, i.e., a simulated environment that will provide them with immersive education programmed to learn them in real situations. 

The design of this program focuses on Problem-Based Learning, by means of which professionals must try to solve the different professional practice situations that arise during the academic course. For this purpose, students will be assisted by an innovative interactive video system developed by renowned experts. 

Click now and obtain a diploma that will allow you to progress in your Engineer professional career in Quantum Physics"

Enroll in a professional master’s degree that will lead you to be able to solve the main existing problems in quantum mechanics"

TECH has designed this university degree with the main objective of offering students the most advanced and comprehensive information on Quantum Physics. For this purpose, it provides multimedia teaching resources, which will allow students to master quantum systems, cosmology, the concept of relativity and the main authors in this field. Additionally, the teaching team that is part of this program will guide the professionals to easily achieve these goals.

TECH's goal is you. Progress in your Engineer professional career thanks to the latest knowledge on the functioning of supersymmetry, strings and extra dimensions”

General Objectives

• Acquire basic concepts of astrophysics
• Obtain basic notions about Feynman diagrams, how they are drawn and their utilities
• Learn and apply approximate methods to study quantum systems
• Master the Klein-Gordon, Dirac and electromagnetic fields

Specific Objectives

Module 1. Introduction to Modern Physics

• Identify and assess the presence of physical processes in daily life and in both specific (medical applications, fluid behavior, optics or radiation protection) and common scenarios (electromagnetism, thermodynamics or classical mechanics)
• Be able to use computer tools to solve and model physical problems
• Be familiar with new developments and advances in the field of physics, both theoretical and experimental
• Develop communication skills, to write reports and documents, or to make effective presentations of these

Module 2. Mathematical Methods

• Obtain basic notions of metric and Hilbert spaces
• Acquire knowledge about the characteristics of linear operators and the Surm-Liouville theory
• Know the theory of groups, group representation, tensor calculus and their applications to physics

Module 3. Quantum Physics

• Apply the fundamental concepts of Quantum Physics and their articulation in laws and theories
• Know the most common physical processes in Quantum Physics
• Be familiar with the postulates of Quantum Physics
• Know how to apply the mathematical tools characteristic to Quantum Physics to solve quantum mechanics problems

Module 4. Astrophysics

• Understand and use mathematical and numerical methods commonly used in Astrophysics
• Be familiar with new developments and advances in the field of Astrophysics, both theoretical and experimental
• Understand the most common physical processes in cosmology
• Know the most common physical processes in only Physics

Module 5. Quantum Physics

• Know the atomic models with the variational method 
• Master the intrinsic angular momentum
• Understand time-dependent perturbation theory
• Understand and know how to apply the WKB method

Module 6. Nuclear and Particle Physics

• Obtain basic knowledge of nuclear and particle physics
• Know how to distinguish the different nuclear decay processes
• Know the Feynman diagrams, their use and how to draw them
• Know how to calculate relativistic collisions

Module 7. Quantum Field Theory 

• Acquire basic notions of quantum field theory
• Know the main problems of quantization of some of the fields and how to solve them
• know how to calculate amplitudes of interactions between particles from Feynman diagrams
• Know the C, P, T symmetries, the most common symmetry violations and the C, P, T symmetry conservation theorem 

Module 8. General Relativity and Cosmology

• Acquire basic notions of general relativity
• Apply knowledge of calculus and algebra to the study of gravity using the theory of general relativity
• Know the Einstein's equations in tensor format
• Acquire basic knowledge of cosmology and the primitive universe

Module 9. High Energy Physics

• Apply knowledge of quantum field theory and the mathematics of group and representations theory to elementary particle physics
• Know spontaneous symmetry breaking mechanisms and the Higgs mechanism
• Have notions of neutrino physics, their masses and oscillations
• Know Feynman's rules for quantum electrodynamics, quantum chromodynamics and weak interaction
• Acquire basic notions of Yang-Millis theory

Module 10. Information and Quantum Computing

• Acquire basic notions of classical and quantum information
• Identify the most common algorithms for quantum encryption of information
• Obtain basic notions about semiquantum and quantum theories of light-matter interaction
• Know the most common quantum information implementations

You will get the most comprehensive knowledge about the most common symmetry breakings"