Fundamental limit of the microresonator field uniformity and slow light enabled angstrom-precise straight-line translation

Abstract

We determine the fundamental limit of the microresonator field uniformity. It can be achieved in a specially designed microresonator, called a bat microresonator, fabricated at the optical fiber surface. We show that the relative nonuniformity of an eigenmode amplitude along the axial length L of an ideal bat microresonator cannot be smaller than 13π 2n4rλ -4Q-2L4, where nr,\ λ and Q are its refractive index, the eigenmode wavelength and Q-factor. In the absence of losses (Q=∞ ), this eigenmode has the amplitude independent of axial coordinate and zero axial speed (i.e., is stopped) within the length L. For a silica microresonator with Q=108 this eigenmode has the axial speed 10-4c, where c is the speed of light in vacuum, and its nonuniformity along the length 100 micron at wavelength λ =1.5 micron is 10-7. For a realistic fiber with diameter 100 micron and surface roughness 0.2 nm, the smallest eigenmode nonuniformity is 0.0003. As an application, we consider a bat microresonator evanescently coupled to high Q-factor silica microspheres which serves as a reference supporting the angstrom-precise straight-line translation over the distance L exceeding a hundred microns.