I'd like you to clarify the relationship which relates penetration power by EM radiation with its wavelength (or inverse of frequency).
Suppose we conduct an experiment, irradiating a body with different wavelengths but keeping the amount of power per surface unit constant (so I reckon we have to reduce the power by the emitter as we shorten the wavelength, correct me if I'm wrong). Please appreciate that the body is always the same, so we can leave out the material's characteristics.
We should observe that as we move to higher frequencies, the radiation penetrates less and less into the body (again, tell me if I'm wrong).
First question: why EM radiation is less penetrating at higher frequencies?
However, one knows that the most penetrating form of EM are the gamma rays (that is, the radiation with the shortest wavelength), which seems to be in contrast with the above observation.
So I gather that gamma rays are highly penetrative just because of the high energy they carry by the vitue of their high frequency. If we could manage to keep constant the net amount of electromagnetic power per surface unit, gamma rays would be LESS penetrating than, say, visible light.
Am I correct?
Best Answer
Being a comment too short for this topic, I write an answer, with the necessary premise that it is only about this observation (so it could not be a full answer to your post):
A neat distinction must be made between
Photons are about how the Electro-Magnetic energy is delivered: it is delivered by separated "particles" (fragments) called photons, each of them carrying a quantity $h \nu$ of energy. When you absorb energy from the Electro-Magnetic field, you can absorb only an integer multiple of $h \nu$ Joules per time, because you can gather only a discrete number of photons.
When instead you evaluate the field amplitude $| \mathbf{E} |$, you are referring to the whole set of the photons you are receiving, with its global properties. You are not interested in the granularity of this energy (the minimum "quantum" of energy you can absorb), but in the behaviour of the whole wave represented by the field. This wave is capable to fill a volume $V$ with a global amount of energy $u \cdot V$ Joules (you may know that this quantity $u \cdot V$ is being carried there by fragments of $h \nu$ Joules, but you are not interested in this, now).
The global energy $u = \frac{1}{2} \epsilon | \mathbf{E} |^2$ is about the number of photons being delivered, $E = h \nu$ is about the energy amount carried by a single photon. If you want an amount of $A$ Joules of energy, you can obtain it with a large number of low-energy (so, low frequency) photons, or with a small number of high-energy (high frequency) photons. But the final amount of energy will always be $A$ Joules.
So, yes, an Electro-Magnetic field with a big $| \mathbf{E} |$ is like a "string" which is having a big vibration: it can deliver a big amount of energy. When you evaluate the global energy of the wave, you do not wonder how big are its fragments: you only care about their final sum.
A high frequency vibration is more energetic only in the sense that its energy fragments, the photons, are bigger.
Suppose that you can generate two fields:
You want to fill with them the volume $V$ with a global energy
$$u_{\mathrm{desired}} \cdot V$$
This is achieved only if both fields, regardless of the frequency and so regardless of how energetic are their photons, have a squared amplitude
$$| \mathbf{E} |^2 = \frac{2 u_{\mathrm{desired}}}{\epsilon}$$
Sorry if it was long, I hope anyway it was a little useful.
Edit 1: Your questions are all very good and absolutely licit, but I think this discussion would make more sense with a basic knowledge of Electromagnetism. You can begin with Coulomb's law. While these concepts will not cancel your doubts, they will make you more able to deal with them, also as regards the linked document.
No, because the global energy inside the volume $V$ is $u_{\mathrm{desired}} \cdot V$. The number of photons inside the volume $V$ is such that the sum of their single energies is $u_{\mathrm{desired}} \cdot V$: this is regardless of their frequency and can happen both for the field at frequency $\nu_1$ and the field at frequency $\nu_2$. What does change is instead the number of photons. The field at frequency $\nu_1$ will need to send inside the volume $V$ more photons than the field at frequency $\nu_2$ to reach the same amount of energy $u_{\mathrm{desired}} \cdot V$, because each single photons at frequency $\nu_1$ carry less energy than the photons at frequency $\nu_2$. But the global energy in both cases is $u_{\mathrm{desired}} \cdot V$. And this is an expected result, not weird in this case.
Edit 2 and disclaimer: these concepts are extremely more complex than this trivial, naive, elementary description. The language here used is only inteded to ease the comprehension: it is neither rigorous nor exhaustive and does not claim to be a Quantum Mechanics representation of this problem. This answer only aims at using a suitable and qualitative language for the OP.
Edit 3: This answer and the original question have been downvoted. This is when
Together with the OP, we are doing our best to deal with a legitimate and meaningful question. If some hint about what we can further improve were given, it could be useful.