diameter of the telescope primary in the Rayleigh formula shows that we could see a hair up an ant's ass on planets around stars out to a few tens of light years away. We could image planets much much further out than that. Talk about the ultimate telescope. I had what is known in amateur telescope making circles as 'Big Aperture Fever' or BAF. Even worse, my case was acute, chronic, and was a special strain called BMFAF. You can guess what the MF stands for.
According to General Relativity, the solar focus should be somewhere between five hundred and eight hundred AUs depending on the wavelength you wish to view. The lensing effect works for all electromagnetic radiation not just visible light. Anyway, imagine a telescope that large. All that would be needed to use old Sol as the primary optic would be to place a detector at the focus. I planned to add other optics to do some image correction and cleaning up but the complete system is simple commercial adaptive optics and software. The hard part is getting to the solar focus. The other hard part is lining the star you wish to view up with the Sun and with the detector. The three objects must form a straight line: the star, then the Sun, then the detector. Assuming the solar focus is six hundred AUs from the Moon Base, then that means a trip time of about three hours to view one star. Of course there would be multiple stars in the field of view of the telescope depending on which eyepiece you use, but we were most immediately interested in stars close to Earth. Now we're talking about maybe fifty stars sparsely spaced whose light paths were rays passing through the surface of a sphere six hundred AUs in radius. It would take some time hopping around the solar focus to get images of all of these star systems. Three hours one way, there then a day or so of observation, then three hours back. Let's assume two days per star system. That means that it would take about a hundred days to look at each of our local stellar neighbors. I decided to start with the closest and move outward. That is once we got the telescope system working properly.
So, we zipped out to the solar focus in line with Alpha Centauri, which is the closest star to Earth. Tabitha popped open the hatch that enclosed our telescope secondary system. It took Jim and me another five or six hours before we had the system functioning the way we wanted it to perform.
There were several planets in the Alpha Centauri system but there was no hint of any planets that could support life as we know it. Using a visible spectrometer, we could analyze exactly what elements were in the atmospheres of these planets. None supported our kind of life. No water, chlorophyll, or oxygen.
Slightly disappointed, we warped back to the Moon. This time we decided to tax the ECC's to ninety-nine percent. Using most of the energy we had available enabled us to deepen the Alcubierre warp. We only shaved off about half of the trip time. In other words, it took about thirty-three times more power to increase our warp speed by a factor of two. Obviously there was some nonlinear function involved here that I hadn't counted on. My solutions to the Einstein equations were only accurate at low warp speeds. Between twenty and fifty times the speed of light, something else was going on. I'm still thinking about that. Jim suggested that spacetime might be quantized like the excitation levels of an atom and that there is some Moor's potential well that we have to overcome. Interesting idea. Like I have said before, Jim deserves a Nobel Prize.
We had proven that there was no life around Alpha Centauri. The next step was to look at Barnard's Star, which is only slightly further out. Barnard's Star is about six light years from Earth and is a faint red giant or M class star on the Hertzsprung--Russel diagram.
Using the solar focus telescope system, Jim brought the star system into view at low magnification and stopped out the bright spot caused by Sol, and by Barnard's Star. An array of planets came into view. Two were fairly large gas giants, one of which was twice the size of Jupiter, and three were planets in the realm of Earth-like in size. The spectrometer computer dinged at us and said that oxygen and chlorophyll had been detected. The light from Barnard's Star had illuminated the planet's atmosphere and the wavelength bands that get absorbed by oxygen and chlorophyll had been absorbed and not reflected off one of the planets—the spectrometer instrument enabled us to measure which bands of light were received by the telescope and which ones weren't. But which planet?
We zoomed in on the inner three planets one at a time. The first planet was a barren rock much like Mercury. The second planet closest to Banard's Star was blue and green and looked like a Mars-sized Earth. We spent hours zooming in on the planet. There were oceans, mountains, trees, and even grass. We saw no artificial structures of any sort. There was life there, but most likely not intelligent life.
The third planet was mostly like Venus.
We bounced back to Moon Base 1 and began discussing who was going to visit Barnard's Star. We decided that we were all going. We were too valuable to America to risk getting lost in space, but we didn't care. Was that selfish? We knew we could get back.
We had one problem. At fifty times the speed of light, the trip would take at least fifty days there and fifty days back. That's a little more than three months. Tabitha and 'Becca were pushing two months pregnant. The
The crew split up into three groups. Tabitha and Sara and I made up one group, Annie, Al, and Margie made up the second, and Jim and 'Becca made the third group. We took turns. One week you got to bounce out to the solar focus and continue planet hunting. One week you got to work the starship construction project. The third week you watched over the military research and development aspects of our Moon Base 1 operations. Each team alternated through the three jobs. There were over a hundred and fifty personnel on the Moon Base now but we were the original brain trust. We felt an obligation to making sure it functioned and continued all of its missions, not just the really fun ones.
Tabitha, Sara, and I took the first watch designing the starship. We took blueprints from the International Space Station habitat modules and began redesigning them. Our idea was to build three habitat size modules, just a little larger, and connect them side by side, then lay two on top of those three, and then one on top of the two. So we would have a pyramid of six cylinder-shaped modules. We would then attach the
Tabitha and Sara went about setting up the contracts Earthside to get construction of the modules under way. It would take about a year to complete the modules. We contracted the same aerospace firm that built
A few days later, Annie had the idea to put a retrofit faring on both ends of the cylinders so that we could dock one of the other warpships to the other side. This way, we could land and then split up into two teams to cover more ground more quickly. She had the contracts modified to allow the new designs.
Occasionally, Jim and I would compare notes on the warp field and energy anomalies. We still hadn't quite put our finger on a solution to the nonlinear energy requirements for fast warp speeds. But we were new to warp theory. We had only been doing it for a year or so. We also compared notes on pregnancy. Tabitha hadn't had a lot of trouble with morning sickness. 'Becca on the other hand was miserable. I told Jim that Tabitha had been an
