As is the case with many large American cities, Chicago has spawned it's share of run down, dirty and dangerous areas. I have visited the city many times, as I am only an hour or two away, and have come to know, that there are certain areas where you just don't go. Still, there is a mix, and it is surprising what you can find. As in New York, in some places, only a few blocks separates the good from the very bad. One of these areas is the location of the University of Chicago. Much of the surrounding neighborhood has turned bad, poor, run down, and dangerous; but the campus itself is quite a contrast to it's surroundings, and a pleasant place for the privileged few who attend the university.
    Within this extensive campus stands a large sculpture, on the east side of Ellis Avenue between 56th and 57th, wedged in between the Max Pelevsky Dormitory, and the tennis courts. Henry Moore, sculptor, named this work simply Nuclear Energy. The twelve foot high modern, metal sculpture stands within a concrete plaza, and may strike the visitor as nothing special, just another scrap of oddly shaped modern art; but it marks one of the milestones in a project which was to change history, and remake the world. This place was a part of the Manhattan Project, and of the development of the atom bomb, and of nuclear energy.
    Generally, when people think of the development of nuclear energy, and of the atom bomb, visions of the Trinity site come to mind, or of Oak Ridge, Los Alamos, or possibly Hanford; but these places came latter, and were primarily chosen for their isolation. Chicago played a much larger role than most people realize, in the development of nuclear technology, as it still does. Even today, two of the largest nuclear physics facilities, Fermilab, and Argonne, are located on the outskirts of Chicago.
    The sculpture marks the site of the first controlled nuclear reaction. This reaction took place in what was called a nuclear pile; but which we today would call a nuclear reactor. It was the work of Enrico Fermi, and others, and was the culmination of the old experimental, philosophical physics, and the beginning of the new more hard edged practical physics. The gentleman physicists of the previous several generations were about to be replaced by a new breed, just as a century before, they had themselves replaced the old physicist/philosophers. Also due for replacement was the old Stagg Field, built at the turn of the century. Stagg field was torn down in 1957, including the stands under which the first pile was constructed. There is a new Stagg Field now, several blocks from this original site. One could have wished that they would have preserved at least the grandstands under which the pile was built; but this was not to be.
    The whole story is pretty fascinating, and yet it is only a single chapter in the development of nuclear technology. The site was chosen in part, due to a strike, which interfered in the construction of the pile. This first reactor was an example of primitive engineering, allied with advanced science. Men stood above the structure, armed with buckets of bromated water, prepared to douse the reactor, should things get out of hand. The structure itself was built from bricks, rods, and pellets. An assortment of scientists, military people, and various others stood on a stand above the floor where the pile stood, awaiting the results. The whole thing was top secret, and there are thus no photographs of this very historical event; but sketches, and artists depictions were latter drawn. Future events were more carefully recorded by what would then be a much more secure and confidant nation. Trinity was exceptionally well recorded, as was the loading and dropping of the first nuclear weapons, and the countless nuclear tests to come.

     A cadmium plated rod was slowly withdrawn, by scientist George Weil, while every ear was cocked in rapt attention, straining to hear the faint clicks from a radiation counter. Though accounts vary, giving the moment of criticality as having occurred anywhere from 3:20, to 3:48, according to the official record, it was at 3:36 P.M., on December second, 1942, that the reactor went critical. It produced a power level of around 200 watts, and was soon shut down. One account says that it ran for only four and a half minutes, while another states that it was twenty eight minutes. The official painting, shown to the left, probably only bears an incidental resemblance to the actual scene at the time. I suspect that, rather than standing at dignified attention, the observers were pressed together, leaning over the railing, tired, disheveled, and exited. Their reward consisted of a barrage of clicks, as the pile went critical. The reaction could have sustained itself indefinitely; but was soon quelled, by pushing the rod back into the pile. This was a demonstration only, a proving of a theory, so that those working on the Manhattan Project could confirm that they were on the right track. Missing was the spectacular, of the Trinity explosion, and the utility of future reactors, like that of Arco. Yet, the world was changed. The demonstration here, made Trinity, nuclear arms, atomic subs, and nuclear power generation inevitable. In a fashion similar to that of the shot that killed Archduke Ferdinand, and set off the First World War, these were the clicks heard around the world, even though they were initially muffled by the top secret nature of the project.

     CP1 was a relatively large and heavy structure, and quite primitive, by today's standards. It nearly filled the 30 x 60 foot squash courts in which it was assembled. The framework was built of wooden timbers, which supported the actual reactor components. These components consisted of about 400 tons of graphite bricks, along with fissionables. The energy came from over six tons of uranium, along with another 34 tons of uranium oxide. The unit was designed to be roughly spherical, or at least as spherical as a structure made of bricks, and laid down by scientists could be. The wooden timbers supported the narrower bottom portions of the squared off sphere, keeping the structure from collapsing. The upper layers needed no support. A large, square balloon, hung over the structure. This is the simplest, and most easily constructed, of all of the reactor types, and is also the most dangerous.

      The fissionable materials were placed, as pellets, within the cavities of the graphite bricks. The graphite acted as a moderating material, slowing down the neutrons so that they could react with the uranium. This is the same material as is used in pencil leads, and is very slippery. The graphite bricks were constructed in a special workshop, and were machined with a pair of holes in each, so that each could contain two pellets of uranium oxide, or in some cases two pellets of actual uranium metal. The pellets were about the size and shape of hockey pucks.  Fabricators, who worked on the project, commented that walking across the floor of the shop in which these bricks were made, was like walking across a skating rink, because of the graphite dust everywhere. A photo of one of the original bricks, on display at Argonne National Laboratory, is shown at right.

     Today, such a structure would not be allowed in the center of a major city; but this was wartime. By today's standards, this was an incredibly dangerous, insecure, and dirty device. America has not built a graphite reactor since the forties, though this is the design most often found in the former Soviet Union. There was nothing like radiation shielding, no facility for cooling, and no barrier other than the surrounding balloon, to keep any escaping nuclear particles inside. Though there was no danger of anything like a nuclear explosion (which requires quite a different kind of containment), there is always the possibility of meltdown, or release of nuclear materials, as well as the radiation danger. A graphite moderated reactor also adds the danger of fire, since graphite will catch fire if sufficiently heated. What the team did have in place was a sort of a Rube Goldberg series of safety precautions. There was a set of electronically controlled rods which would be automatically pushed into the pile, at certain levels of radiation. There was also a rod weighted to be pulled into the reactor, and held off by a rope. In the event of emergency, Dr. Norman Hillberry was standing by with an axe, to cut the rope. Finally, above the reactor stood three other scientists, with buckets of a cadmium salt solution, with which they would douse the structure, at any indications of danger.

In search of the First (and second) Nuclear Reactor
	Above: The Pallos Woods compound, as it appeared sometime in the forties. Left: The sign for the Red Gate Woods, as it appears on Archer Avenue, near the site. This is the best way to access Site A, and Plot M. I had thought that these sites would be difficult to find; but they are really quite accessible.
	These rolling forested hills, would hardly seem like the a historical nuclear site; but the nearby compound was one of the centers of development for nuclear weapons.
	A little lot, off of the right had side of the parking lot, displays a map of the area, and is the starting point of the part trail that takes the visitor to both Site A, and Plot M.
	Left: The trail leading to the old military road, which accessed the old Argonne site. Below: Stepping out onto the old road, now called Preserve Road
	Above; A little stone bridge crosses a gulley, on the way to Site A, which was the former location of Argonne National Laboratory, and of several nuclear reactors. Left: The road disappears, and the visitor is left with a gravel path. This photo is taken in what had formerly been the compound, shown in the photo at top. Below: The Marker, placed at the location of CP2, which was the rebuilt CP1. The remains of the reactor are buried below this rock.
	A view of the former site, showing no sign that any significant structures ever stood here. The item to the lower left of the photo is a borehole. The NRC drilled a number of these holes in the area. To the visitor, they look like pipes sticking out of the ground, with padlocked metal caps on top. The NRC periodically unlocks these, and brings up samples, to check on possible contamination of the area, by all of the buried nuclear materials.
	A look down Preserve Road.
	Left: In a clearing, at the top of a ridge, stands a granite marker, indicating that this is Plot M, a burial site for much of the contaminated nuclear material produced at this place. Below: A close up of the granite marker. Interesting stuff lies right below. There is little danger of any unauthorized recovery, however. Underneath this sign, the nuclear waist is incased in concrete, and is checked on every years. It would take dynamite or a pile driver to get it out.
	This marker stone, shows the edge of the burial area. There are six of them, spaced 100 feet from the large granite marker shown above.
	One last look at one of the trails leading out of the woods, and back to the parking lot.