The echoes rang and dwindled. The lunar silence flowed back, underlined by the breathing of the people in the observatory and the sound of pumps laboring somewhere beneath.
And slowly, and without a sound, the cloudy planet on the screen turned white all over. The clouds and the dim oceans and continents blended into a blue-white glare which shone out from the screen like a searchlight. It seemed to penetrate their bloodless faces down to the bone.
Slowly, slowly, it all melted away: the chirruping forests, Chtexa's porcelain house, the barking lungfish, the stump of the Message Tree, the wild allosaurs, the single silver moon, the great beating heart of Blood Lake, the city of the potters, the flying squid, the Lithian crocodile and his winding track, the tall noble reasoning creatures and the mystery and the beauty around them. Suddenly the whole of Lithia began to swell, like a balloon—
The count tried to turn the screen off, but he was too late. Before he could touch the black box, the whole circuit went out with a puffing of fuses. The intolerable light vanished instantly; the screen went black, and the universe with it. They sat blinded and stunned.
"An error in Equation Sixteen," the count's voice said harshly in the swimming darkness.
No, Ruiz-Sanchez thought, no. An instance of fulfilled desire. He had wanted to use Lithia to defend the faith, and he had been given that. Cleaver had wanted to turn it into a fusion-bomb plant, and he had got that in full measure, all at once. Michelis had seen in it a prophecy of infallible human love, and had been stretched on that rack ever since. And Agronski—Agronski had wanted nothing to change, and now was unchangeably nothing.
In the darkness, there was a long, ragged sigh. For a moment, Ruiz-Sanchez could not place the voice; he thought it was Liu. But no. It was Mike.
"When we have our eyesight back," the count's voice said, "I propose that we suit up and go outside. We have a nova to watch for."
That was only a maneuver, an act of misdirection on the count's part—an act of kindness. He knew well enough that that nova would not be visible to the naked eye until the next Holy Year, fifty years to come; and he knew that they knew.
Nevertheless, when Father Ramon Ruiz-Sanchez, sometime Clerk Regular in the Society of Jesus, could see again, they had left him alone with his God and his grief.
APPENDIX
The Planet Lithia (from Michelis, D., and Ruiz-Sanchez, R.: Lithia—a preliminary report. J. I. R. 4:225, 2050; abstract.)
Lithia is the second planet of the solar type star Alpha Arietis, which is located in the constellation Aries and is approximately 50 light-years from Sol.1
It revolves around its primary at a mean distance of 108,600, 000 miles, with a year of approximately 380 terrestrial days. The orbit is definitely elliptical, with an eccentricity of 0.51, so that the long axis of the ellipse is approximately 15 per cent longer than the short axis.
The axis of the planet is essentially perpendicular to the orbit, and the planet rotates on its axis with a day of about 20 terrestrial hours. Hence, the Lithian year consists of 456 Lithian days. The eccentricity of the orbit produces mild seasons, with long, relatively cold winters, and short, hot summers.
The planet has one moon with a diameter of 1,256 miles, which revolves about its primary at a distance of 326,000 miles, twelve times in the Lithian year.
The outer planets of the system have not yet been explored. Lithia is 8,267 miles in diameter, and has a surface gravity of 0.82 that of Earth. The light gravity of the planet is accounted for by the relatively low density, which in turn is the result of its composition. When the planet was formed there was a much lower percentage of the heavy elements with atomic numbers above 20 included in its make-up than was the case with the Earth. Furthermore, the odd-numbered elements are even rarer than they are on Earth; the only odd-numbered elements that appear in any quantity are hydrogen, nitrogen, sodium and chlorine. Potassium is quite rare, and the heavy oddnumbered elements (gold, silver, copper) appear only in microscopic quantities and never in the elemental form. In fact, the only uncombined metal that has ever appeared on the planet has been the nickel-iron of an occasional meteorite.
The metallic core of the planet is considerably smaller than that of the Earth, and the basaltic inner coating correspondingly thicker. The continents are built, as on Earth, basically of granite, overlaid with sedimentary deposits.
The scarcity of potassium has led to an extremely static geology. The natural radioactivity of K40 is the major source of the internal heat of the Earth, and Lithia has less than a tenth of the K40 content of the Earth. As a result, the interior of the planet is much cooler, vulcanism is extremely rare, and geological revolutions even rarer. The planet seems to have settled down early in life, and nothing very startling has happened since. The major part of its uneventful geological history is at best conjectural, because the scarcity of radioactive elements has led to great difficulties in dating the strata.
The atmosphere is somewhat similar to that of the Earth.2 The atmospheric pressure is 815.3 mm at sea level, and the composition of dry air is as follows:
Nitrogen 66.26 per cent by volume
Oxygen 31.27
Argon, &c. 2.16
CO2 0.31
The relatively high CO2 concentration (partial pressure about 11 times that of the gas in the Earth’s atmosphere) leads to a hothouse type of climate, with relatively slight temperature differences from pole to equator. The average summer temperature at the pole is about 30° C., at the equator near 38° C., while the winter temperatures are about 15° colder. The humidity is generally high and there is a lot of haze; gentle, drizzling rain is chronic.
There has been little change in the climate of the planet for about 700 million years. Since there is little vulcanism, the CO2 content of the air does not rise appreciably from that cause, and the amount consumed in photosynthesis by the lush vegetation is compensated for by the rapid oxidation of dead vegetable matter induced by the high temperature, high humidity, and high oxygen content of the air. In fact, the climate of the planet has been in equilibrium for more than half a billion years.
As has the geography of the planet. There are three continents, of which the largest is the southern continent, extending roughly from latitude 15° south to 60° south, and two-thirds of the way around the planet. The two northern continents are squarish in shape, and of sizes similar to each other. They extend from about 10° south to about 70° north, and each one about 80° east and west. One is located north of the eastern end of the southern continent, the other north of the western end. On the other side of the world there is an archipelago of large islands, the size of England and Ireland, running from 20° north to 10° south of the equator. There are thus five seas or oceans: the two polar seas; the equatorial sea separating the southern from the northern continents; the central sea between the two latter, and connecting the equatorial sea with the north polar sea; and the great sea, stretching from pole to pole, broken only by the archipelago, extending a third of the way around the planet.
The southern continent has one low mountain range (highest peak 2263 meters) paralleling its southern shore, and moderating the never very momentous effect of the south winds. The northwestern continent has two ranges, one paralleling the eastern and one the western sea, so that the polar winds have a free run, and give this continent a more variable climate than that of the southern one. The northeastern continent has a slight range along its southern shore. The islands of the archipelago have few hills, and possess an oceanic type of climate. The trade winds are much like those of Earth, but of lesser velocity, due to the lesser temperature differentials between the different parts of the planet. The equatorial sea is nearly windless.
Except for the few mountain ranges, the terrain of the continents is rather flat, particularly near the coasts, and the lower reaches of all the rivers are of the meandering type, bordered with marshes, and with low plains that are flooded, miles wide, every spring.
There are tides, milder than on
Earth, producing an appreciable tidal current in the equatorial sea. As the coastal terrain is generally quite flat, except where the mountain ranges come to the sea, wide tidal flats separate the shore from the open sea.
The water is similar to that of Earth, but considerably less salty.3 Life began in the sea, and evolved much as it did on Earth. There is a rich assortment of microscopic sea life, types resembling such forms as seaweed and sponges, and many crustacea and mollusklike forms. The latter are very highly developed and diversified, particularly the mobile types. Quite familiar fishlike forms have emerged and dominate the seas as they do on Earth.
Present-day Lithian land plant life would be unfamiliar, but not surprising, to a terrestrial observer. There are no plants exactly like those of Earth, but most of them have a noticeable similarity to those with which the visitor would be familiar. The most surprising aspect is that the forests are of a remarkably mixed type. Flowering and non-flowering trees, palms and pines, tree ferns, shrubs and grasses all grow together in remarkable amity. Since Lithia never had a glacial period, these mixed forests, rather than the uniform type prevailing on Earth, are the rule.
In general the vegetation is lush and the forests can be considered as typical rain-forests. There are several varieties of poisonous plants, including most of the edible-looking tubers. Their roots resemble potatoes and they produce extremely toxic alkaloids, whose structure has not yet been worked out, in large quantities. There are several types of bushes which grow thorns impregnated with glucosides which are extremely irritating to the skins of most vertebrates.
The grasses are more prevalent on the plains, shading into rushes and similar swamp-adapted plants in the marshes. There are few desert areas—even the mountains are rounded and smooth, and covered with grasses and shrubs. Seen from space, the land areas of the planet are almost entirely green. Bare rock is found only in the river valleys, where the streams have cut their way down to the lime and sandstone, and in ligneous outcroppings, where flint, quartz and quartzite are frequently found. Obsidian is rare, of course, because of the lack of volcanic activity. There is clay to be found in some of the river valleys, with an appreciable alumina content, and rutile (titanium dioxide) is not uncommon. There are no concentrated deposits of iron ore, and hematite is almost unknown. The land-living animal forms include orders similar to those found on Earth. There is a large variety of arthropods, including eight-legged insectlike forms of all sizes, up to a pseudo dragonfly with two pairs of wings and a wingspread which has been recorded at 86.5 cm. maximum. This variety lives exclusively on other insects, but there are several types dangerous to higher forms of animals. Several have dangerous bites (the poison is generally an alkaloid) and one insect can eject a stream of poisonous gas (reputed to be largely HCN) in quantity sufficient to immobilize a small animal. These insects are social in nature, like ants, living in colonies which are usually left severely alone by otherwise insectivorous organisms.
There are also many amphibians, small lizardlike forms with three fingers on each limb instead of the five that are common to terrestrial land vertebrates. They form an extremely important class, and there are some species that are as large as a St. Bernard dog at maturity. Except for some small and unimportant forms, however, the amphibians are confined to the marshy lowlands near the sea, and the rest of the land is dominated by a class resembling Earthly reptiles. Among these is the dominant species, a large, highly intelligent animal with a bipedal gait which balances itself with a rather stiff, heavy tail. Two groups of the reptiles went back to the sea and engaged in successful competition with the fish. One adopted a completely streamlined form and is, outwardly, just another 30-foot fish. But its tail fin is in the horizontal plane and its internal structure shows its ancestry. It is the fastest thing in the waters of Lithia, doing nearly 80 knots when pressed (as it usually is by its insatiable appetite). The other group of returned reptiles resembles crocodiles, and is competent either in the open sea or on the mud flats, although it is not very fast in either situation.
Several genera of the reptiles have taken to the air, as did the terrestrial pteranodons. The largest of these has a wingspread of nearly three meters, but is very lightly built. It roosts mainly on the sea cliffs of the southern coast of the northeastern continent, and lives mainly on fish, and such of the gliding cephalopods as it can manage to catch above water. This flying reptile has a large assortment of sharp, backward-curving teeth in its long beak. One other species of flying reptile is of special interest, because it has developed something resembling feathers, in a many-colored crest down its long neck. They appear only on the mature reptile; the young are completely naked. Some 100,000,000 years ago the land-living reptiles were almost completely wiped out by one of the smallest of their own family, which adopted the easiest method of making a living: eating the eggs of its larger relatives. The larger forms almost completely disappeared, and those that survived (such as the Lithian allosaur) are now almost as rare as the terrestrial elephant (as compared for instance, with the many elephant species of the Pleistocene). The smaller forms survived better, but are not nearly so abundant now as they once were. The dominant species is an exception. The female of this species has an abdominal pouch in which the eggs are carried until they hatch. This animal is about twelve feet tall at the crown, with a head shaped for bifocal vision. One of the three fingers on the free forelimb is an opposable thumb.
1 An earlier figure of 40 light-years, often quoted in the literature, arose from application of the so-called Cosmological Constant. Einstein’s reluctance to allow this “constant” into his scholium has now been fully justified. v. Haertel, J. I. R. 1:21, 2047.
2Clark, J.: The climate of Lithia. J. I. R., in press.
Ley, W.: The ecologies of Lithia. J. I. R., in press.
WHO?
Algis Budrys
Chapter One
1.
It was near the middle of the night. The wind came up from the river, moaning under the filigreed iron bridges, and the weathercocks on the dark old buildings pointed their heads north.
The Military Police sergeant in charge had lined up his receiving squad on either side of the cobbled street. Blocking the street was a weathered concrete gateway with a black-and-white-striped wooden rail. The headlights of the M.P. superjeeps and of the waiting Allied Nations Government sedan glinted from the raised shatterproof riot visors on the squad’s varnished helmets. Over their heads was a sign, fluorescing in the lights:
you are leaving the allied sphere you are entering the soviet socialist sphere
In the parked sedan, Shawn Rogers sat waiting with a man from the A.N.G. Foreign Ministry beside him. Rogers was Security Chief for this sector of the A.N.G.-administered Central European Frontier District. He waited patiently, his light green eyes brooding in the dark.
The Foreign Ministry representative looked at his thin gold wristwatch. “They’ll be here with him in a minute.” He drummed his fingertips on his briefcase. “If they keep to their schedule.”
“They’ll be on time,” Rogers said. “That’s the way they are. They held him four months, but now they’ll be on time to prove their good faith all along.” He looked out through the windscreen, past the silent driver’s shoulders, at the gateway. The Soviet border guards on the other side—Slavs and stumpy Asiatics in shapeless quilted jackets—were ignoring the Allied squad. They were clustered around a fire in an oil drum in front of their checkpoint shack, holding their hands out to the warmth. Their shroud-barreled submachine guns were slung over their shoulders, hanging clumsily and unhandily. They were talking and joking, and none of them were bothering to watch the frontier.
“Look at them,” the Foreign Ministry man said peevishly. “They don’t care what we do. They’re not concerned if we drive up with an armed squad.”
The Foreign Ministry man was from Geneva, five hundred kilometers away. Rogers had been here, in this sector, for seven years. He shrugged. “We’re all old acquaintances by n
ow. This frontier’s been here forty years. They know we’re not going to start shooting, any more than they are. This isn’t where the war is.”
He looked at the clustered Soviets again, remembering a song he’d heard years ago: “Give the Comrade With the Machine Gun the Right to Speak.” He wondered if they knew of that song, over on their side of the line. There were many things on the other side of the line that he wanted to know. But there was little hope for it.
The war was in all the world’s filing cabinets. The weapon was information: things you knew, things you’d found out about them, things they knew about you. You sent people over the line, or you had them planted from years ago, and you probed. Not many of your people got through. Some of them might. So you put together the little scraps of what you’d found out, hoping it wasn’t too garbled, and in the end, if you were clever, you knew what the Soviets were going to do next.
And they probed back. Not many of their people got through—at least, you could be reasonably sure they didn’t— but, in the end, they found out what you were going to do next. So neither side did anything. You probed, back and forth, and the deeper you tried to go, the harder it was. For a little distance on either side of the line, there was some light. Further on, there was only a dark fog. And some day, you had to hope, the balance would break in your favor.
The Foreign Ministry man was taking out his impatience in talk. “Why the devil did we give Martino a laboratory so near the border in the first place?”
Rogers shook his head. “I don’t know. I don’t handle strategy.”
“Well, why couldn’t we get a rescue team of our own in there after the explosion?”
“We did. Theirs just got in first. They moved fast and took him away.” And he wondered if that had been a simple piece of luck.
American Science Fiction Five Classic Novels 1956-58 Page 61