Survival would come first. Shelter, food, and water would come first. Assuming we survive through the first couple years and the construction of a small farming community with virtually no tools or supplies available, I would start working on making paper and ink so books can be written to preserve the knowledge we have for our future generations.
Math, medicine, and basic biology would be priorities. Unfortunately, I would do so with a heavy heart. The knowledge that a few of us would probably die before producing children, and that few of those children would live would be unpleasant.
The knowledge that ten people is insufficient to provide a healthy gene pool, resulting in humanity's final demise through genetic diseases as the result of inbreeding, and that everything I do would inevitably be for nothing would be nearly unbearable.
There are many important pieces of information to pass onto future generations, but if such a tragedy really occurs, I am sure I will go mad and will not be in a position to pass any information to my next generation.
I would teach the children survival before I taught them math formulas. Eventually you would be like the Rothchilds as everyone would be sleeping with their cousins so life wouldn't carry out to far.
Anything I can to survive. Establish my own government and then rule whats left of the world as we now know it. I teach my children and grand/great children not to make the same mistakes again.
Don't pollute or plunder or ever take for granted again what you have been unbelievably lucky to have. Survival.
Ringshine is when sunlight is reflected by a planet's ring system onto the planet or onto the moons of the planet. Also this happens on other planets. This has been observed in many of the photos from the Cassini–Huygens probe.
Scientists at NASA's Navigator Program, which specializes in the detection of terrestrial planets, have backed the launch of a Terrestrial Planet Finder (TPF) mission. 2 TPF would detect planetshine from planets orbiting stars to investigate whether they could harbor life. It would use advanced telescope technologies to look for life-marks in the light reflected from the planets, including water, oxygen and methane.
The European Space Agency has a similar mission, named Darwin, under consideration. This will also study the earthshine of planets to detect the signatures of life. Unlike many traditional astronomical challenges, the most serious challenge for these missions is not gathering enough photons from the faint planet, but rather detecting a faint planet that is extremely close to a very bright star.
For a terrestrial planet, the contrast ratio of planet to its host stars is approximately ~10? 6-10?7 in the thermal infrared or ~10? 9-10?10 in the optical/near infrared.
For this reason, Darwin and Terrestrial Planet Finder-I will work in the thermal infrared. However, searching for terrestrial planets in the optical/near infrared has the advantage that the diffraction limit corresponds to a smaller angle for a given size telescope. Therefore, NASA is also pursuing an Terrestrial Planet Finder-C mission that will search for and study terrestrial planets using the optical (and near infrared) wavelengths.
While Terrestrial Planet Finder-C aims to study the planetshine of extrasolar planets, Darwin and Terrestrial Planet Finder-I will search for thermal infrared light that is reradiated (rather than scattered) by the planet, and most astronomers would not consider that to be planetshine. In preparation for these missions, astronomers have performed detailed earthshine observations. Astronomers have paid particular attention to whether earthshine measurement can detect the red edge, a spectral feature that is due to the plants.
The detection of a similar spectral feature in light from an extrasolar planet would be particularly interesting, since it might be due to a light-harvesting organism. While the red edge is almost certainly the easiest way to directly detect life on earth via earthshine observations, it could be extremely difficult to interpret a similar feature due to life on another planet, since the wavelength of the spectral feature is not known in advance (unlike most atomic or molecular spectral features). , Turner, E.L. & Seager, S.
(2001) ``Characterization of extrasolar terrestrial planets from diurnal photometric variability Nature, Volume 412, Issue 6850, pp. , & Ford, E. (2005) ``Vegetation's Red Edge: A Possible Spectroscopic Biosignature of Extraterrestrial Plants Astrobiology, Volume 5, Issue 3, pp.
I cant really gove you an answer,but what I can give you is a way to a solution, that is you have to find the anglde that you relate to or peaks your interest. A good paper is one that people get drawn into because it reaches them ln some way.As for me WW11 to me, I think of the holocaust and the effect it had on the survivors, their families and those who stood by and did nothing until it was too late.