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A Simple Conceptual Example in Discussing Thin Layer Reflections
Returning again with a new example, described in text as:
1w | 1/4WL | |/ laser-----air-----|---Si Crystal---|---Al contact--- |/ 1st medium | 2nd medium | 3rd medium |/ n = 1.0 n = 5.8275 n 6 whe the laser is in the UV/deep Blue (355nm to 360nm) the second medium is a single crystal of Silicon the third medium is a reflective aluminum contact. When you take the intensity times the area for both the reflected and refracted beams, the total energy flux must equal that in the incident beam. That equation appears as: (r² + (t² · n2² · cos(theta-t) / n1² · cos(theta-i))) = 1 It stands to reason that this can be quickly reduced without need to use transcendentals for an angle of incidence of 0° (which results in a refractive angle of 0°). All that needs to be known are the coefficients which for that same angle simplify to r = 0.7071 a value that is the limit of an asymptote; it is also invested with either a + or - sign depending upon the polarization (another issue that was discarded in the original discussion as more unknown than immaterial) t = 0.7071 a value that is the limit of an asymptote; here, too, there are polarization issues we will discard as before. All this discarding comes only by virtue of squaring: r² = 0.5000 t² = 0.5000 I presume that the remainder of the math can be agreed to exhibit: that part of the energy reflected amounts to 50% and that part of the energy transmitted amounts to 50%. In this example (a farrago, to say the least), it is overwhelmingly obvious that when the incident energy strikes the first interface that half of it is reflected and half of it transmitted (a common specification for this specie). Even more obvious is that the sum total of all re-reflections between the interfaces (and it has been absurdly guaranteed that no energy will ever transit the aluminum mirror) will combine in the proper phase relationship to "totally" cancel the first reflection. Now, what to make of this black mirror? The same conservation of energy has been maintained as has been exhibited in other threads of this ilk. That conservation expressed above as both a commentary and a formula is satisfied and "total" cancellation has been presented. To wit, and in former expressions: Observing the conservation of energy at the first interface: X = 0.5000X + 0.5000X Observing the conservation of energy at the second interface: 0.5000X = 0.5000X + 0.0000X 0.5000X == 0.5000X Of course, to put the lie to this example, no mirror is completely reflective. Some in these "debates" wanted to inject loss, or the lack of perfection. This should satisfy those who need this smudgy focus. To brush aside those anticipated rejections requires only expressing what fraction the "best" mirror could provide, and simple trim the wavelength of the source to match the numbers. Let me offer: We have a mirror that is only 98% reflective (it would exhibit a refractive index more than 1000 in this example). By slipping the wavelength 2nm shorter (actually there are other wavelengths that support these indices, but this is as illustrative as any); then we can allow for 49.5% reflection, a 50.5% transmission, a subsequent summation of all reflections with the 98% mirror to once again exhibit: Observing the conservation of energy at the first interface: X = 0.495X + 0.505X Observing the conservation of energy at the second interface: 0.505X = 0.495X + 0.010X 0.495X == 0.495X Choose another mirror efficiency and one need only perform like wavelength adjustments to obtain the necessary energy. As I've offered in other posts, the "total" cancellation is entirely driven by very simple optics which resolve to obvious ratios in the expression of conservation of energy. And, of course, "total" is not. ;-) Even with this pencil-whipping out 4 places, the reflection products that remain (in the 5th place) in this example are vastly brighter than the sun (for those who see this wavelength). Also note that the complete exercise reveals through the conservation of energy that there is a loss (due to the incomplete reflection of the in-efficient mirror) and that all energies add to the energy applied to the system. 73's Richard Clark, KB7QHC |
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