In 1961, R. Landauer proposed the principle that logical irreversibility is associated with physical irreversibility and further theorized that the erasure of information is fundamentally a dissipative process. Landauer posited that a fundamental ene
rgy cost is incurred by the erasure of information contained in the memory of a computation device. His theory states that to erase one binary bit of information from a physical memory element in contact with a heat bath at a given temperature, at least kT ln(2) of heat must be dissipated from the memory into the environment, where k is the Boltzmann constant and T is the temperature. Although this connection between information theory and thermodynamics has proven to be very useful for establishing boundary limits for physical processes, Landauer principle has been a subject of some debate. Despite the theoretical controversy and fundamental importance of Landauer erasure in information technology, this phenomenon has not been experimentally explored using any practical physical implementation for digital information. Here, we report an investigation of the thermodynamic limits of the memory erasure process using nanoscale magnetic memory bits, by far the most ubiquitous digital storage technology today. Through sensitive, temperature dependent magnetometry measurements, we observed that the amount of dissipated energy is consistent with the Landauer limit during an adiabatic erasure process in nanoscale, single domain magnetic thin film islands. This result confirms the connection between information thermodynamics and physical systems and also provides a foundation for the development of practical information processing technologies that approach the fundamental limit of energy dissipation.
