After a quick review of 20th-century physics, Professor Kachru introduces the concept of unimaginably minute strings. These appear to solve longstanding problems in quantum mechanics and achieve Einstein’s dream of a quantum theory of gravity. Learn why string theory predicts extra dimensions of space—10 in total, according to some models. Then explore the startling implications.
Delve deeper into string theory by probing the geometries of the extra dimensions. In the simplest cases, these could be curled into tiny circles. Also explore branes, analogous to two-dimensional membranes. See how elementary particles are a reflection of underlying string states, and learn what “spherical cows” have to do with the unifying principle of supersymmetry.
The Standard Model of particle physics accounts for the fundamental particles and forces of the universe, apart from gravity. Use the framework developed so far in the course to construct a streamlined version of the Standard Model. Key concepts include D-branes (which connect open strings), scalar fields (generated by D-branes), and superpartners (a byproduct of supersymmetry).
In the Standard Model oscillating strings are still a dream since they create particles beyond the reach of current particle accelerators. But what would happen if scientists could dial up the energy to produce highly excited strings? Draw on the work of Indian mathematician Srinivasa Ramanujan to count the almost limitless string states for a given energy level. Then see something bizarre happen.
Investigate the physics of black holes, focusing on their entropy, a measure of disorder that is proportional to the black hole’s event horizon—or its “point of no return.” Find that string theory can explain this property, providing a tool to study one of the most puzzling objects in the universe. As in Lecture 2, utilize a spherical cow model and supersymmetry.
Dive into the mystery of a black hole’s event horizon through the medium of hyperbolic art. Utilize the concept of anti-de Sitter space in conjunction with the holographic principle to probe the peculiar properties of this region. Discover how Argentine theorist Juan Maldacena harnessed these concepts, along with string theory, to enhance our understanding of quantum gravity.
Shift from the study of black holes to the problem of the Big Bang. Both phenomena involve singularities, where matter is infinitely dense, and the known laws of physics break down. How did the universe get from a point-like singularity to a vast, geometrically “flat” realm, filled with the particles and fields of the Standard Model? See how a theory called cosmic inflation accounts for this fact.
Continue your investigation of the aftermath of the Big Bang. Analyze the evidence for a mysterious “dark” energy that is causing the expansion of the universe to accelerate. Then apply string theory to this phenomenon as well as to cosmic inflation. Although the answers are not yet definitive, string theory provides a powerful theoretical tool for understanding the earliest instant of the universe.
Step back to inspect the simplest features of string theory. Professor Kachru has already shown that string theories are well suited to 10 space-time dimensions. But why is this, and how many separate string theories are possible in 10 dimensions? To address these questions, appeal to the spherical cow approach introduced earlier. Also, see how supergravity theories fit into this framework.
Explore a key feature of modern theoretical physics: the equivalence between apparently dissimilar theories, a property known as duality. Probe a pair of examples in string theory: type IIA and heterotic theories. Markedly different, they can nonetheless be shown to be mathematically equivalent under certain conditions, suggesting that a more fundamental theory underlies them.
The energies needed to prove the existence of strings are far beyond today’s research tools. Is it even possible to test the theory? Learn how resourceful physicists have come up with several indirect methods of inferring the reality of strings. Hunt for the extra dimensions required by the theory, and search for the hypothesized cosmic strings left over from the era of cosmological inflation.
The energies needed to prove the existence of strings are far beyond today’s research tools. Is it even possible to test the theory? Learn how resourceful physicists have come up with several indirect methods of inferring the reality of strings. Hunt for the extra dimensions required by the theory, and search for the hypothesized cosmic strings left over from the era of cosmological inflation.