by Ian Douglas
Rogers and Jorgenson slipped through the lock, followed by Beaudet and Tomacek. They were followed by the next fireteam . . . and the next. I wasn’t tapped in to the visual channels, but I could hear the radio calls of the Marines already inside.
“Watch it! Watch it! Tango at oh-one-five!”
“Moving! Firing!”
“Rogers! Morrisey! To your right!”
“Got him! Tango down!”
“Sobiesky! You and Marshall secure the hatch! The rest of you, with me!”
More and more of the platoon’s Marines vanished through the doughnut, until it was my turn. I grabbed the handholds and pulled myself forward. I could feel the nanoseal closing around me, clinging to me, sliding down my torso as I moved . . . and then I was through.
The interior was a large compartment some ten meters across, dark except for emergency lights spaced around the bulkheads. Directly ahead, my helmet light illuminated a massive tangle of pipes and conduits—the business end of the nano-D mining equipment eating its way into the heart of Atun 3840. A dead tango floated in the air nearby, wearing what looked like a Chinese space suit without the helmet. A MAW drifted nearby.
Magnetic accelerator weapons aren’t a real good choice for close combat inside a pressurized environment. I wondered how well trained these idiots were.
A Marine fireteam on the far end of the hab module used an applicator gun to smear a two-meter circle of nano-D against the bulkhead, and then one of them gave the smoking ring a hard kick. Gunfire cracked and clanged as magnetic rounds snapped through the opening and punched through bulkheads, a cacophony of noise after the silence of our passage through vacuum. Corporal Tom Morrisey screamed, and I saw a flash of incoming data on my med channel.
“Corpsman!” Thomason yelled. “Marine down!”
I was also getting environmental warnings, and a station Klaxon began sounding an alert. Some of the rounds that had missed Morrisey had punched through the facility’s outer hull. The station’s external nanomatrix would seal the holes, but that would take a few moments, and the air pressure was dropping precipitously in the meantime.
That wouldn’t hurt us, of course, but it put the station’s crew in danger.
I kicked off the bulkhead and glided across the compartment to Morrisey. His right arm was missing below the elbow, the armor there was a tangled mess, and blood was spurting from the wreckage in a bright orange-red arterial stream that was breaking off into darker gobbets as it spiraled with his rotation. I collided with him and stabilized his spin, then jacked into his armor for a direct readout.
The magnetically accelerated slug had sliced through his elbow with kinetic energy enough to shred armor and amputate the lower arm. Normally, Marine armor will guillotine shut above a serious leg or arm wound, stopping the bleeding and, more important, stopping the suit from venting its air into vacuum. That last might be a problem in another few minutes, but right now the cabin pressure was high enough that the armor’s slice-and-seal function hadn’t triggered. Morrisey’s brachial artery was pumping out blood fast; he would be dead in a few minutes if I didn’t stop the bleeding.
I did a quick scan to make certain he didn’t have any head trauma—it looked like it was just his arm that had been hit, but you never know—then thoughtclicked a key directing Morrisey’s suit to autoinject a jolt of anodynic recep blockers into his carotid artery. Heart rate 155 . . . BP 149 over 90, respiration 36 and gasping, rapidly elevating levels of both adrenalin and noradrenalin.
Morrisey stopped screaming as the nanoanadynes started shutting down the doloric receptors in his thalamus and the insular cortex, blocking the pain signals as they reached his brain. “Jesus, Doc!” he said. “I can still feel it! It feels . . . weird!”
“That’s because your pressure receptors are still firing. Don’t worry. You’re going to be fine.”
I hoped. His extremities were already starting to cool, which meant he was already shocky. I ordered his suit to clamp down on his upper arm to reduce the brachial artery flow, then raise its internal temp slightly and relax the external pressure on the arteries leading to his head to interrupt the shock response.
I had to make a quick decision, though. The armor clamp would slow the bleeding, but wouldn’t stop it by itself. I could cram a packet of skinseal into the injury, and let that seal off the wound . . . or I could order his suit to slice off what was left of his arm well above the bleeding stump. The guillotine at his elbow, obviously, was smashed; the next working blade was eight centimeters up, midway up his humerus. The nanonarcs would block the pain, or most of it, but he would still feel it, and that would increase the risk of shock.
Shock or not, I elected to cut. Skinseal is great stuff, but it’s better for minor bleeding. And if the mining station’s outer hull didn’t seal off the leaks, Morrisey would have other problems in a moment if he started losing air.
I again checked his nananodyne levels, then thoughtclicked through the link to trigger the suit’s chopper. Another chunk of his arm came off, a squat cylinder encased in black armor, but the bleeding stopped at once.
“God,” he said. “I’m gonna be sick. . . .”
“No,” I told him. “You’re not.”
Vomiting inside a space suit is very serious business, and can lead to drowning. Morrisey’s armor was already firing antiemetic ’bots into his carotid artery, but it wasn’t enough.
The vomiting reflex is triggered in the area postrema, a tiny nub on the floor of the brain’s fluid-filled fourth ventricle snugged up against the cerebellum. There are a number of different chemical pathways leading to emeses triggers, but most involve a neuropeptide called substance P, or SP, which is found in both the brain and the spinal cord and which is associated with inflammation, pain, and shock.
I pulled my N-prog from my M-7 medical kit and thought a quick series of commands into it. The device, in turn, reprogrammed some of the nananodyne bots now circulating through Morrisey’s brain, ordering them to block out the SP . . . and also to shut down the cholinergic receptor input from his inner ears, since his vestibular system—reacting to zero-G—was also screaming at him. The reprogrammed ’bots would add to the suit’s antiemetic response, helping to stifle Morrisey’s nausea before he vomited inside his helmet.
“Yeah,” Morrisey said. “Yeah . . . that’s . . . that’s better, Doc. Thanks.”
I gave his readouts a final check. His BP was stabilizing at 125 over 70, and his respiration was a bit slower now. “You’ll be fine,” I told him. “Some time in sick bay, and we’ll grow you a new arm, better than the old.”
He nodded inside his helmet. “I know.”
I sent him back to the doughnut to await a medevac. Now that we had our foothold on board Zeta, more Marines were on the way in, along with support vessels and transports to haul away the wounded. I made my way toward the second breach in the bulkhead, slipping through and into the compartment on the other side. The fighting appeared to be over—here, at least. There was a seething mob of people in brown utilities, more spacesuited bodies, Marines, and a lot more drifting globules of blood, a tangle too confused for me to count. Marines were moving among the rescued hostages, cuffing their hands with zipstrips. Until we were absolutely sure of who was a tango and who was a hostage, we handled them all as potential terrorists. There was a bank of link-in controls along one bulkhead. I saw one deeply padded seat with a dead tango strapped into it, his hands still on the palmpads on the chair’s arms. He’d probably been the terrorist commander, running the station’s defenses by jacking in at this secondary control center, but the ugly crater in his spacesuit’s chest showed that a Marine had taken him out with a laser rifle.
“Corpsman, front!”
I homed on this new call, pushing my way through the milling civilians and Marines. Gunny Hancock was waving to me from an open hatch in the bulkhead beyond. “In here, Doc! On the double!”
Drifting through the opening, I entered a small and bare compartment—probab
ly a storage locker. There were two M’nangat drifting inside, and one of them looked like it was hurt. Another dead tango floated near the overhead, a MAW pistol still clutched his hand.
I drifted over to the alien. “What happened?” I asked.
“That guy shot him,” Hancock said, “just as we came through the door. Is it bad?”
“It’s not good.”
The M’nangat are surprisingly like us biologically—carbon-based oxygen breathers, with metal-chelated tetrapyroles pumped through an enclosed circulatory system by a pair of two-chambered hearts working in synch. They even use DNA for genetic coding rather than one of several other xenobiological possibilities, but that’s where the similarities stop. The being was a couple of meters long, resembling a pale, blue-green pillar of thick, tightly twisted tentacles like a tree’s trunk, which then spread out from the creature’s base like the roots of a tree. At the top end was what looked like a half-meter cluster of grapes—though each grape was the size of an orange—translucent, and shot through with flecks of red and gold. The wounded one had a savage puncture in one side of its leathery trunk, and blue-green liquid was jetting in spurts from the wound with enough force to paint one bulkhead and drive the being into the other like a small rocket. Slits beneath the grape cluster representing mouths and breathing apertures gaped and pulsed, and the being uttered a startlingly human-sounding groan.
“You’ll be okay, fella,” I said. The reassurance was automatic; I didn’t expect the creature to answer. But a link switched on within my in-head, and the words “Thank you” wrote themselves out on an inner window.
I’d not realized that the M’nangat shared something else with us besides our body chemistries, that they had CNS prostheses that, among other things, could connect with an AI residing within their internal hardware and communicate with other software in the area . . . such as a translator program.
And as soon as I thought about that, something clicked into place . . . something I’d just seen and not thought about, but which represented a terrible danger to the station and to us.
“Gunny!” I yelled, turning. “That dead tango in the seat out there . . .”
“What about him, Doc?”
“If he has an AI—”
I saw Hancock’s eyes widen behind his helmet visor. It had clicked for him too. He turned to duck out of the small compartment, but in that same instant I felt a solid jolt, and the sensation of weight tugged at me with a terrifying insistence. It wasn’t much—maybe a tenth of a gravity, but it was terrifying in its implications.
The massive meta-fueled thrusters mounted to the surface of Atun 3840 had just fired. The one-kilometer asteroid and its attached mining station were decelerating . . . which meant we were now beginning to fall out of orbit and toward the Earth’s surface.
And if we hit we were going to leave one hell of a big crater.
Chapter Two
We were falling out of the sky.
I knew immediately what had happened . . . and kicked myself for not picking up on it as soon as I’d seen that dead tango in the control seat. The guy might have been a neo-Ludd . . . but if he was running the control software for Capricorn Zeta—that’s the only reason he would have been strapped into that chair with his hands on the palm interfaces—then he must have had a resident AI inside his in-head hardware, his cerebral implant. I have one; all Marines do as well, and most civilians have them too. It’s how we can interface with all of the thousands of computers and control systems around us every day, from operating devices like my N-prog to pulling down in-head data feeds and scans and communication to telling the deck to grow a chair.
And a person doesn’t have to be alive for the AI to keep working.
Whoever had helped the neo-Ludds take over Capricorn Zeta had had some high-powered technology behind them, and that would include AIs carefully programmed to help carry out their mission. That meant there would have been some sort of backup electronic deadman’s switch; the man controlling the station dies, and his software tells the station to destroy itself . . . taking out a big part of the planet as it does so.
I heard Thomason’s shouts outside. “Get his hands off of there! Get him out of that fucking seat!” But moment followed moment and the deceleration continued. The neo-Ludd software must have had run-if-interrupted code sequences. Someone would have to regain control of the system to stop those rockets.
That wasn’t my immediate problem, however. The Marines had people who could regain control of the falling asteroid. I had a patient to worry about. If we re-entered Earth’s atmosphere he would die—as would I—but he would die anyway even if we regained a stable orbit and I didn’t patch him up.
There are certain priorities in treating a wounded patient no matter what his, her, or its species might be. The M’nangat was losing blood fast, and that was my immediate priority. M’nangat blood is cupriglobin, copper-based, rather than iron-based as with human hemoglobin. That’s why the blue-green color of the blood. But the different blood chemistry wouldn’t affect skinseal. These guys had a similar body temperature, and their skin, though thicker than in humans, was made up of the same sorts of carbon-based keratinocytes, keratin proteins, and lipids.
I pulled a packet of skinseal from my M-7 kit, thumbed it open, and pressed the whole pack, powder-side-down, over the wound. Skinseal includes both absorbents and binding nanoagents that would work on a variety of more or less similar body building blocks.
As it worked, I pulled down the species EG data from the Orbital Net.
Encyclopedia Galactica/Xenospecies Profile
Entry: Sentient Galactic Species 14566
“M’nangat”
M’nangat, “M’naggies,” “Broccolis,” “Brocs,” “Stalks”
Civilization type: 1.042 G
TL 19: FTL, Genetic Prostheses, Cerebral Prostheses
Societal code: AQCB
Dominant: loose associative/scavenger/defensive/sexual
Cultural library: 4.11 x 1016 bits
Data Storage/Transmission DS/T: 3.07 x 1011s
Biological code: 156.872.119
Genome: 3.8 x 109 bits; Coding/non-coding: 0.028.
Biology: C, N, O, S, H2O, PO4
DNA
Cupric metal-chelated tetrapyroles in aqueous circulatory fluid.
Mobile heterotrophs, omnivores, O2 respiration.
Upright tentacular locomotion.
Mildly gregarious, Polyspecific [1 genera, 12 species]; trisexual.
Communication: modulated sound at 150 to 300 Hz.
Neural connection equivalence NCE = 1.1 x 1014
T = ~260o to 300o K; M = 0.9 x 105 g; L: ~2.5 x 109s
Vision: ~200 nanometers to 720 nanometers; Hearing: 12 Hz to 18,000 Hz
Member: Galactic Polylogue
Receipt galactic nested code: 3.86 x 1010 s ago
Locally initiated contact 0.11 x 109 s ago
Star G1V; Planet: Fourth; “M’gat”
a = 1.669 x 1011m; M = 8.5 x 1027g; R = 7.2 x 106m; p = 3.6 x 107s
Pd = 2.3 x 105s, G = 10.9 m/s2 Atm: O2 20.1, N2 79.6, CO2 0.3;
Patm 0.97 x 105 Pa
Librarian’s note: First direct human contact occurred in 2119 C.E., the very first extraterrestrial space-faring civilization encountered by Humankind. Threat level—8.
I let the numbers cascade through my brain, watching for anything that was so far out of the ordinary that it would put up a red flag. Ordinary when discussing alien biochemistry takes in a huge chunk of territory, of course, but there were some basic rules to play by if the patient was a carbon-based oxygen breather. Hell, compared to some of the critters we’ve encountered out there, methane-breathers and gas giant floaters and fluoro-silicate crystal autotrophs, these guys were practically next of kin.
We’d known the Brocs for over a century, now . . . since just after the discovery of the local Encylopedia Galactica Node at Sirius. They were our first ET encounter, face-to . . . whatever it is they have in place
of a face. Once we established contact with them, they helped us figure out how to extract the oceans upon oceans of data in the EG, which helped us begin to make some small bit of sense out of the bewildering forest of intelligent life we were encountering as we moved out into the Galaxy. In fact, we were reading parts of the EG only twelve or thirteen years after we logged in; that we were doing so in only thirteen years was due almost entirely to Broc help. They’ve taught us five, so far, of the major Galactic linguae francae, as well as giving us the inside scoop on the slow-motion collapse of the R’agch’lgh Collective in toward the Core. In many ways, they’ve been Humankind’s friendly native guides in our first tentative explorations into the Galaxy jungle at large.
A few have been allowed to come to the Sol System as consultants—so long as they didn’t have astrogation devices that might give away Earth’s most closely guarded secret . . . exactly where Sol was among the four hundred billion stars of our Galaxy. It pays to be damned cautious in a star wilderness filled with roving predarians and the wreckage of a collapsing galactic empire. These two, according to our pre-mission briefing, had been at Capricorn Zeta to advise us on in-orbit mining techniques.
Unfortunately, they’d been at the wrong place at the wrong time when a Chinese tug declared an emergency and docked alongside. Twenty armed tangos had been hiding on board. As soon as the tug docked, they’d come swarming out of the tug’s cargo compartment and into the mining station.
PLEASE HELP HERM. The words printed themselves out in my in-head as the second, uninjured, M’nangat leaned closer.
Herm. The M’nangat had three sexes, I saw—male, female, and a third that received the fertilized embryo from the female and carried it to term. The wounded one, apparently, was one of those.
They were called life carriers.
I hesitated. I’d already done everything I could for the wounded Broccoli . . . everything I could, that is, without firing nano into its circulatory system to give me a look from the inside. Putting anything foreign into an alien body was risky, especially if you didn’t know about possible antibody or immune-system responses. The nanobots I carried in my M-7 kit were designed to neatly bypass the human immune response . . . but how would that play out inside an alien circulatory system?