Modes of Coupling: Exploring the Neon Atom's Interactions in a Cavity

How many modes can a Neon atom couple to in a cavity with a frequency range of 0 to 473 THz?

Given data: Frequency range: 0 to 473 THz, Emission frequency of Neon atom: 473 THz, Linewidth: 16 MHz

The Neon atom can couple to approximately 29.56 million modes in the given cavity.

When exploring the interactions of a Neon atom in a cavity with a frequency range of 0 to 473 THz, it is crucial to consider the concept of modes of coupling. In this scenario, the Neon atom has an emission frequency of 473 THz and a linewidth of 16 MHz.

To determine the number of modes the Neon atom can couple to in the cavity, we need to calculate the discrete frequencies within the frequency range. By dividing the frequency range by the linewidth, we can establish the number of modes.

Firstly, let's convert the frequency range to Hz. 473 THz can be converted to 473 x 10^12 Hz. Multiplying the linewidth by 16 MHz (16 x 10^6 Hz) gives us the number of modes the atom can couple to.

Number of modes = (473 x 10^12 Hz) / (16 x 10^6 Hz) = 2.956 x 10^7 modes.

Therefore, the Neon atom can couple to approximately 29.56 million modes in the given cavity. This highlights the intricate nature of interactions within the cavity and the multitude of modes available for the Neon atom to couple to.

← Airy s equation power series expansion and solution behavior Understanding the slope of a linear function →