Optical Tweezers

Read my full senior thesis, which won the Barbara McClintock Award for the best senior thesis in the sciences in 2023, on Scholarship at Claremont.

Photons carry momentum. When a tightly-focused beam of photons hit a particle, they transfer some of their momentum to the particle, exerting a force. Optical tweezers take advantage of this phenomenon to trap (or “tweeze”) a spherical bead just after the focus of a diverging laser beam, creating a potential well that pulls in beads.

In my senior thesis project at Scripps College:

• I built an optical tweezers setup
• Predicted the force exerted on trapped beads, which had not previously been quantitatively calculated
• Measured the actual force using the optical tweezers setup that I built

To predict the force, I follow the path of all possible rays from a diverging beam incident on a spherical bead in an optical trap. I then sum up all force contributions from input reflection, input refraction, first output reflection, and first output refraction for each ray, and integrate over all input angles.

I used the Fresnel equation to determine the relative magnitudes of the forces.

This ray analysis in combination with the measured power level of the optical tweezers predicts a net force on the scale of 10^(-13) N exerted on the bead.

I calculated the actual force using the Equipartition Theorem, which relates the “stiffness” or spring constant of the trap to its temperature and the standard deviation of trapped beads’ position, which was determined by video analysis done in Python. The actual force exerted was also on the scale of 10^(-13) N, in good agreement with the predicted force.