Enhancing Longitudinal Excitation Effectiveness with a Glass Confinement Layer

In order to enhance the longitudinal excitation effectiveness, we have introduced a glass confinement layer. This layer is designed to confine and guide the excitation energy along the longitudinal direction, thus improving the overall efficiency of the excitation process.

The glass confinement layer acts as a waveguide, allowing the excitation energy to propagate along its length with minimal losses. By confining the excitation energy within the glass layer, we can effectively direct and focus the energy towards the desired target area, leading to enhanced excitation effectiveness.

The choice of glass material for the confinement layer is crucial. It should have high transparency to the excitation energy wavelength and low absorption losses. Additionally, the refractive index of the glass should be well-matched to the surrounding medium to ensure efficient energy propagation.

Overall, the introduction of a glass confinement layer provides a means to enhance the longitudinal excitation effectiveness by confining and guiding the excitation energy, resulting in improved performance in various applications, such as optical sensing, laser systems, and photonic devices.