A century after Albert Einstein said we would never be able to observe the instantaneous velocity of tiny particles as they randomly shake and shimmy, so called Brownian motion, physicist Mark Raizen and his group have done so.
“This is the first observation of the instantaneous velocity of a Brownian particle,” says Raizen, the Sid W. Richardson Foundation Regents Chair and professor of physics at The University of Texas at Austin. “It’s a prediction of Einstein’s that has been standing untested for 100 years. He proposed a test to observe the velocity in 1907, but said that the experiment could not be done.”
In 1907, Einstein likely did not foresee a time when dust-sized particles of glass could be trapped and suspended in air by dual laser beam “optical tweezers.” Nor would he have known that ultrasonic vibrations from a plate-like transducer would shake those glass beads into the air to be tweezed and measured as they moved in suspension.
Raizen’s research, published in Science, is the first direct test of the equipartition theorem for Brownian particles, one of the basic tenets of statistical mechanics. It is also a step toward cooling glass beads to a state in which they could be used as oscillators or sensors.
The equipartition theorem states that a particles’ kinetic energy — the energy it possesses due to motion — is determined only by its temperature, not its size or mass.
Raizen’s study now proves that the equipartition theorem is true for Brownian particles; in this case, glass beads that were three micrometers across.
Raizen says he and his colleagues can now push the limits, moving the particles closer to a quantum state for observation.
“We’ve now observed the instantaneous velocity of a Brownian particle,” says Raizen. “In some sense, we’re closing a door on this problem in physics. But we are actually opening a much larger door for future tests of the equipartition theorem at the quantum level.”
There, he expects that equipartition theory will break down, leading to new problems and solutions surrounding the quantum mechanics of small particles composed of many atoms.