The frequency of acoustic resonances/standing waves are more of a function of distances between reflective surfaces rather than their size.
It probably makes more sense to talk about particle size with EMF since wavelengths of visible light are in the nanometer range while wavelengths of audible sound will be measured in cm at high frequencies and m at low frequencies.
The amount of sound that is converted to heat has a lot to do with material properties like hardness and surface texture. Something that is an effective insulator of heat will also typically be an effective insulator or sound, hence why you see double-paned glass with an air gap used for both applications.
The frequency of acoustic resonances/standing waves are more of a function of distances between reflective surfaces rather than their size.
It probably makes more sense to talk about particle size with EMF since wavelengths of visible light are in the nanometer range while wavelengths of audible sound will be measured in cm at high frequencies and m at low frequencies.
The amount of sound that is converted to heat has a lot to do with material properties like hardness and surface texture. Something that is an effective insulator of heat will also typically be an effective insulator or sound, hence why you see double-paned glass with an air gap used for both applications.