13 polidrupa No. You probably know that a LC circuit has a resonance of $\omega = 1/\sqrt{LC}$, so *in principle* you can find L, C values to make it resonate at any frequency, even at terahertz or exahertz, where the gamma rays lay. However, **this is only a model**, and is a valid approximation only for relatively low frequencies. For frequencies at the microwave range, other physical problems arise, and for frequencies even higher, the decay of your voltage is so large that for all practical purposes the circuit is a piece of wood without any conductivity. That's the reason electromagnetic waves in the visible spectrum are transmitted via fibers instead of metallic circuits, and this is even more true for gamma rays.
3 mfb- You would need a cable with a length of the wavelength of gamma rays - short than an atom. That doesn't work with anything you would call a cable.
12 0 polidrupa No. You probably know that a LC circuit has a resonance of $\omega = 1/\sqrt{LC}$, so *in principle* you can find L, C values to make it resonate at any frequency, even at terahertz or exahertz, where the gamma rays lay. However, **this is only a model**, and is a valid approximation only for relatively low frequencies. For frequencies at the microwave range, other physical problems arise, and for frequencies even higher, the decay of your voltage is so large that for all practical purposes the circuit is a piece of wood without any conductivity. That's the reason electromagnetic waves in the visible spectrum are transmitted via fibers instead of metallic circuits, and this is even more true for gamma rays.
4 0 mfb- You would need a cable with a length of the wavelength of gamma rays - short than an atom. That doesn't work with anything you would call a cable.