Barrett, The Honors College Thesis/Creative Project Collection

This research endeavor explores the 1964 reasoning of Irish physicist John Bell and how it pertains to the provoking Einstein-Podolsky-Rosen Paradox. It is necessary to establish the machinations of formalisms ranging from conservation laws to quantum mechanical principles. The notion that locality is unable to be reconciled with the quantum paradigm is upheld through analysis and the subsequent Aspect experiments in the years 1980-1982. No matter the complexity, any local hidden variable theory is incompatible with the formulation of standard quantum mechanics. A number of strikingly ambiguous and abstract concepts are addressed in this pursuit to deduce quantum's validity, including separability and reality. `Elements of reality' characteristic of unique spaces are defined using basis terminology and logic from EPR. The discussion draws directly from Bell's succinct 1964 Physics 1 paper as well as numerous other useful sources. The fundamental principle and insight gleaned is that quantum physics is indeed nonlocal; the door into its metaphysical and philosophical implications has long since been opened. Yet the nexus of information pertaining to Bell's inequality and EPR logic does nothing but assert the impeccable success of quantum physics' ability to describe nature.

Our work explores a fascinating experiment in physics and science, the Double-Slit Experiment. We cover the mystery of this experiment, representing the wave and particle nature of photons, electrons, and quantum elements. We recount the history of quantum physics, an unknown field for most people due to its detachment from the world we see. Finally, we explore the capability of the human eye to detect light in its quantum state, closing the gap between us and quantum physics.

Our work explores a fascinating experiment in physics and science, the Double-Slit Experiment. We cover the mystery of this experiment, representing the wave and particle nature of photons, electrons, and quantum elements. We recount the history of quantum physics, an unknown field for most people due to its detachment from the world we see. Finally, we explore the capability of the human eye to detect light in its quantum state, closing the gap between us and quantum physics.

The 1970’s was an exciting time for those interested in avian navigation and magnetoreception. In the mid 1970’s, it had been scientifically proven that birds utilized the Earth’s magnetic fields as a means for orientation. However, while scientists now knew that birds could detect geomagnetic fields, a major question still remained: how? Several years later, physicist Klaus Schulten would bring the world much closer to an answer with the introduction of the radical pair model. With an extremely firm grasp of quantum mechanics, Schulten was able to make an amazing connection between the magnetically sensitive “radical pairs” and magnetic sensing in organisms (such as birds). The goal of this thesis is to explore this intersection of quantum mechanics and biology first illuminated by Schulten, through providing an in-depth explanation of the radical pair model itself, the quantum mechanical concepts that allow it to exist, the possible biological structures involved, and a small exploration of where the theory stands today, all to better understand the fascinating phenomenon of avian magnetoreception.