The strong and weak forces, also known as the strong nuclear force and the weak nuclear force, do not have a direct equivalent to the electromagnetic spectrum or the gravitational wave spectrum. Unlike electromagnetism and gravity, which are long-range forces, the strong and weak forces are short-range forces that act within the atomic nucleus.
The strong force is responsible for holding the atomic nucleus together, overcoming the electromagnetic repulsion between positively charged protons. It binds protons and neutrons together to form stable atomic nuclei. The strong force is much stronger than electromagnetism and acts over extremely short distances within the nucleus.
The weak force, on the other hand, is responsible for certain types of nuclear decays, such as beta decay, where a neutron can transform into a proton, an electron, and a neutrino. The weak force is involved in processes that change the flavor or type of particles, like the decay of unstable particles called mesons. The weak force is much weaker than both the strong force and electromagnetism.
Unlike electromagnetism and gravity, which can be described by continuous spectra (e.g., electromagnetic spectrum and gravitational wave spectrum), the strong and weak forces are not described by continuous spectra. Instead, they are described by quantum field theories known as quantum chromodynamics (QCD) and electroweak theory, respectively.
In summary, while electromagnetism has the electromagnetic spectrum and gravity has the gravitational wave spectrum, the strong and weak forces do not have equivalent continuous spectra. They are short-range forces that act within atomic nuclei and are described by quantum field theories rather than continuous spectra.