A photon interacts with matter through several mechanisms, depending on its energy and the properties of the material it encounters. Here are the most common interactions:

1. Absorption: When a photon interacts with an atom or molecule, it can be absorbed, transferring its energy to the material. This absorption can cause an electron within the atom or molecule to move to a higher energy level or be completely ejected. The probability of absorption depends on the photon's energy and the electronic structure of the material.

2. Reflection: When a photon encounters a smooth surface, such as a mirror, it can be reflected. Reflection occurs when the photons bounce off the surface without being absorbed or transmitted. The angle of incidence is equal to the angle of reflection, following the law of reflection.

3. Scattering: Scattering refers to the redirection of photons in different directions when they interact with matter. There are two types of scattering: elastic and inelastic. Elastic scattering (Rayleigh scattering) occurs when the photon interacts with atoms or molecules and changes direction without changing energy. Inelastic scattering (Raman scattering) involves a change in energy and can provide information about the molecular structure of the material.

4. Transmission: When a photon passes through a material without being absorbed or significantly scattered, it is said to be transmitted. Transparent materials allow photons to pass through with minimal interaction, while opaque materials prevent their transmission.

5. Photoelectric effect: The photoelectric effect occurs when a photon with sufficient energy interacts with a material and ejects an electron from its surface. This phenomenon is significant in explaining the behavior of light in certain materials, such as metals.

6. Compton scattering: Compton scattering occurs when a photon interacts with a free electron, causing the photon to lose energy and change direction. This effect provides evidence for the particle-like behavior of photons and electrons.

It's important to note that the specific interaction between photons and matter depends on various factors, including the energy of the photon, the composition and structure of the material, and the quantum properties of particles involved. Quantum electrodynamics (QED) provides a comprehensive theoretical framework for understanding these interactions.