The Discovery of the Higgs Boson

The Discovery of the Higgs Boson

Instructor: Christos Leonidopoulos

Sponsored by Louisiana Workforce Commission

7 modules

Gain insight into a topic and learn the fundamentals.

4.7

(17 reviews)

Intermediate level

Recommended experience

17 hours to complete

3 weeks at 5 hours a week

Flexible schedule

Learn at your own pace

7 modules

Gain insight into a topic and learn the fundamentals.

4.7

(17 reviews)

Intermediate level

Recommended experience

17 hours to complete

3 weeks at 5 hours a week

Flexible schedule

Learn at your own pace

What you'll learn

Discuss fundamental building blocks of the Standard Model, explore Quantum Mechanics and Special Relativity, describe elementary Particle Physics.

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Assessments

31 assignments

Taught in English

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There are 7 modules in this course

The discovery of a new fundamental particle at the Large Hadron Collider (LHC), CERN is the latest step in a long quest seeking to answer one of physics’ most enduring questions: why do particles have mass? The experiments’ much anticipated success confirms predictions made decades earlier by Peter Higgs and others, and offers a glimpse into a universe of physics beyond the Standard Model.

As Professor Peter Higgs continues his inspiring role at Edinburgh University’s School of Physics & Astronomy, the experiments at the LHC continue. This free online course introduces the theoretical tools needed to appreciate the discovery, and presents the elementary particles that have been discovered at the tiniest scales ever explored. Beginning with basic concepts in classical mechanics, the story unfolds through relativity and quantum mechanics, describing forces, matter and the unification of theories with an understanding driven by the tools of mathematics. Narrating the journey through experimental results which led to the discovery in 2012, the course invites you to learn from a team of world-class physicists at Edinburgh University. Learners participate in discussion of the consequences of the Higgs boson, to physics and cosmology, and towards a stronger understanding and new description of the universe. Photo of Professor Higgs © Peter Tuffy, The University of Edinburgh.

The Higgs discovery is the latest step in a long journey of discovery of the elementary constituents of matter. Before we discuss the detailed structure of matter at the smallest scales ever explored, we want to introduce some basic concepts in the more familiar framework of classical mechanics.

What's included

9 videos7 readings4 assignments1 discussion prompt

9 videosTotal 71 minutes

Why is the Higgs Boson discovery important?1 minutePreview module
Collisions, Higgs decays and the discovery plot5 minutes
Introduction2 minutes
Newton's Law14 minutes
Harmonic oscillator11 minutes
Gravitational forces and potential10 minutes
Spatial translation symmetry10 minutes
Rotational symmetry and time translation symmetry15 minutes
Particles and fields in classical mechanics1 minute

7 readingsTotal 30 minutes

Introducing the educators2 minutes
Course Information2 minutes
Physical phenomena from mathematical equations5 minutes
Feedback after the quiz2 minutes
Feedback after the quiz1 minute
Summary of activities3 minutes
Glossary15 minutes

4 assignmentsTotal 45 minutes

Newtonian dynamics10 minutes
Newtonian dynamics15 minutes
Conservation laws10 minutes
Conservation laws10 minutes

1 discussion promptTotal 15 minutes

Discussion topics for classical mechanics15 minutes

In order to have a consistent description of the interactions of matter and light, we need a new framework. QED as an example of RQFT.

What's included

6 videos6 readings4 assignments1 discussion prompt

6 videosTotal 70 minutes

Maxwell's equations5 minutesPreview module
Special relativity: from experiment to theory19 minutes
Particles of light14 minutes
Particle-wave duality16 minutes
The hydrogen atom12 minutes
The photoelectric effect, quantum mechanics & special relativity2 minutes

6 readingsTotal 29 minutes

New phenomena at the atomic scale5 minutes
Introducing the educators2 minutes
Waves of light15 minutes
Feedback after the quiz1 minute
Feedback after the quiz1 minute
Elements of special relativity and quantum mechanics5 minutes

4 assignmentsTotal 25 minutes

Test on special relativity5 minutes
Quantum mechanics5 minutes
Quiz on special relativity10 minutes
Quantum mechanics5 minutes

1 discussion promptTotal 15 minutes

Discussion topics for special relativity and quantum mechanics15 minutes

In order to have a consistent description of the interactions of matter and light, we need a new framework. QED as an example of RQFT.

What's included

7 videos5 readings4 assignments1 discussion prompt

7 videosTotal 104 minutes

Relativistic wave equations15 minutesPreview module
Dirac's equation20 minutes
Interactions of matter and light19 minutes
Elementary processes in QED25 minutes
Higher-order processes and applications19 minutes
QED & symmetries2 minutes
Renormalisation1 minute

5 readingsTotal 14 minutes

The theory of matter and light3 minutes
Introducing the educators2 minutes
Feedback after the quiz2 minutes
Feedback after the quiz2 minutes
QED: matter and light5 minutes

4 assignmentsTotal 40 minutes

Field theory10 minutes
QED10 minutes
Field theory10 minutes
QED10 minutes

1 discussion promptTotal 15 minutes

Discussion topics for quantum field theory15 minutes

The framework introduced for QED can be generalised to describe all four fundamental forces in Nature. Characteristic features of the strong/weak force, what needs to be modified with respect to QED.

What's included

9 videos6 readings6 assignments1 discussion prompt

9 videosTotal 87 minutes

The theory of strong interactions13 minutesPreview module
The theory of weak interactions14 minutes
Massless particles11 minutes
Massive particles and bowl potentials8 minutes
Superconductors and spontaneous symmetry breaking6 minutes
Goldstone's theorem6 minutes
The Higgs mechanism and the Higgs boson12 minutes
Professor Boyle, in the Maxwell Building, with a copper pipe8 minutes
QCD & strong interactions3 minutes

6 readingsTotal 16 minutes

Fundamental forces as gauge theories2 minutes
Introducing the educators2 minutes
Feedback after the quiz1 minute
Feedback after the quiz1 minute
Feedback after the quiz5 minutes
Summary of activities5 minutes

6 assignmentsTotal 45 minutes

Test on strong interactions10 minutes
Weak interactions10 minutes
Spontaneous symmetry breaking10 minutes
Quiz on strong interactions5 minutes
Weak interactions5 minutes
Spontaneous symmetry breaking5 minutes

1 discussion promptTotal 15 minutes

Discussion topics for strong and weak interactions15 minutes

The Higgs mechanism, and the construction of the Standard Model, and Higgs phenomenology.

What's included

3 videos5 readings4 assignments1 discussion prompt

3 videosTotal 50 minutes

The Higgs boson and the Standard Model15 minutesPreview module
Higgs decay modes21 minutes
The 1964 paper13 minutes

5 readingsTotal 12 minutes

The Higgs and the Standard Model5 minutes
Introducing the educators1 minute
Feedback after the quiz2 minutes
Feedback after the quiz2 minutes
Summary of activities2 minutes

4 assignmentsTotal 30 minutes

Higgs and the Standard Model10 minutes
Higgs decay10 minutes
Higgs and the Standard Model5 minutes
Higgs decay5 minutes

1 discussion promptTotal 15 minutes

Discussion topics for the Higgs boson in the Standard Model15 minutes

This week should provide an overview of experimental techniques (colliders/detectors), and results.

What's included

8 videos5 readings3 assignments1 discussion prompt

8 videosTotal 64 minutes

Physics of Particle Colliders and early searches for the Higgs Boson17 minutesPreview module
Searches at the LHC and the discovery of the Higgs boson14 minutes
Higgs measurements and future colliders2 minutes
Peter's commentary on the searches for the Higgs Boson8 minutes
Bonus video: the experimental challenges3 minutes
The Edinburgh group at the ATLAS experiment8 minutes
The Edinburgh group at the LHCb experiment9 minutes
Why is the sun burning so slowly?0 minutes

5 readingsTotal 41 minutes

Introduction to week 65 minutes
Introducing the educators2 minutes
Feedback after the quiz2 minutes
Feedback after the quiz30 minutes
Summary of activities2 minutes

3 assignmentsTotal 35 minutes

Higgs boson searches at the LHC10 minutes
Early experimental searches for the Higgs Boson15 minutes
Higgs boson searches at the LHC10 minutes

1 discussion promptTotal 15 minutes

Discussion topics for experimental searches15 minutes

Basic understanding of concepts behind the hot big bang cosmology; relevance of particle processes to early Universe cosmology; summary of cosmological observations suggesting physics beyond the standard model.