The inside of a black hole is hidden behind broken equations and a gravitational field so strong that even light cannot escape. Although general relativity predicts that black holes exist, the theory breaks down at the event horizon. It is widely believed that understanding the inside of a black hole will require a new theory of physics: a theory of quantum gravity.
General relativity uses spacetime geometry to explain gravity. Knot Physics extends this geometric description by assuming that spacetime is a branched manifold. In Knot Physics, both quantum mechanics and gravity result from the behavior of the branches of spacetime. This theory of quantum gravity makes predictions about the interior of black holes, extending our knowledge of physics beyond the event horizon.
Continue reading Physics Beyond the Event Horizon
One of the most common questions that people ask about Knot Physics is why we are not affiliated with an institution. There are many advantages to working in academia, especially when it comes to communicating new ideas. The credentials that come along with an academic position are very helpful for reaching an audience. That said, there are also many constraints, including numerous demands on the time and attention of the researcher.
When this project began, it was just an idea. Developing the idea required long periods of talking to no one and staring at walls—uninterrupted blocks of time that an academic career would not afford. As the idea progressed, it became clear that it had substance. Eventually, it was a fully formed theory that had developed as independent research.
From idea to theory
The theory began as a question: Can all of physics be described using only the spacetime manifold? General relativity succeeded in describing gravity as curvature of spacetime. Could that description be extended to particles? If spacetime can bend, perhaps it can bend so much that it forms a knot. What if those knots are the elementary particles?
Continue reading Origins