Green Mars

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Green Mars Page 24

by Kim Stanley Robinson


  For those fond of this world, it was a very pleasant sight. Sax poked his head into several of the rooms, but none of the talks intrigued him enough to draw him in, and soon he found himself in a hall full of poster displays, so he kept on browsing.

  “Solubilization of Polycyclic Aromatic Hydrocarbons in Monomerie and Micellar Surfactant Solutions.” “Post-Pumping Subsidence in Southern Vastitas Borealis.” “Epithelial Resistance to Third-Stage Gerontological Treatment.” “Incidence of Radial Fracture Aquifers in Impact Basin Rims.” “Low-voltage Electroporation of Long Vector Plasmids.” “Katabatic Winds in Echus Chasma.” “Base Genome for a New Cactus Genera.” “Resurfacing of the Martian Highlands in the Amenthes and Tyrrhena Region.” “Deposition of the Nilosyrtis Sodium Nitrate Strata.” “A Method for Assessing Occupational Exposure to Chlorophenates Through Analysis of Contaminated Work Clothing.”

  As always, the posters were a deliciously mixed bag. They were posters rather than talks for a variety of reasons—often the work of graduate students at the university in Sabishii, or concerned with topics peripheral to the conference—but anything might be there, and it was always very interesting to browse. And at this conference there had been no strong attempt to organize the posters into hallways by subject matter, so that “Distribution of Rhizocarpon geo-graphicum in the East Charitum Montes,” detailing the high-altitude fortunes of a crustose lichen that could live up to four thousand years, was facing “Origins of Graupel Snow in Saline Particulates Found in Cirrus, Altostratus and Altocumulus Clouds in Cyclonic Vortexes in North Tharsis,” a meteorological study of some importance.

  Sax was interested in everything, but the posters that held him the longest were those that described aspects of the terraforming that he had initiated, or once had a hand in. One of these, “Estimate of the Cumulative Heat Released by the Underhill Windmills,” stopped him in his tracks. He read it through wee, feeling a slight dampening of spirits as he did.

  The mean temperature of the Martian surface before their arrival had been around 220°K, and one of the universally agreed-upon goals of terraforming Was to raise that mean temperature to something above the freezing point of water, which was 273°K. Raising the average surface temperature of an entire planet by more than 53°K was a very intimidating challenge, requiring, Sax had figured, the application over time of no less than 3.5 × 106 joules to every square centimeter of the Martian surface. Sax in his own modeling had always aimed to reach a mean of about 274°K, figuring that with this as the average, the planet would be warm enough for much of the year to create an active hydrosphere, and thus a biosphere. Many people advocated even more warming than that, but Sax did not see the need.

  In any case, all methods for adding heat to the system were judged by how much they had raised the global mean temperature; and this poster examining the effect of Sax’s little windmill heaters estimated that over seven decades they had added no more than 0.05°K. And he could find nothing wrong with the various assumptions and calculations in the model outlined in the poster. Of course heating was not the only reason he had distributed the windmills; he had also wanted to provide warmth and shelter for an early engineered cryptoendolith he had wanted to test on the surface. But all those organisms had in fact died immediately upon exposure, or shortly thereafter. So on the whole the project could not be said to be one of his better efforts.

  He moved on. “Application of Process-Level Chemical Data in Hydrochemical Modeling: Dao Vallis Watershed, Hellas.” “Increasing CO2 Tolerance in Bees.” “Epilimnetic Scavenging of Compton Fallout Radionuclides in the Marineris Glacial Lakes.” “Clearing Fines from Piste Reaction Rails.” “Global Warming As a Result of Released Halocarbons.”

  This last one stopped him again. The poster was the work of the atmospheric chemists. Simmon and some of his students, and reading it made Sax feel considerably better. When Sax had been made head of the terraforming project in 2042, he had immediately initiated the construction of factories to produce and release into the atmosphere a special greenhouse gas mix, composed mostly of carbon tetrafluoride, hexafluoroethane, and sulphur hexafluoride, along with some methane and nitrous oxide. The poster referred to this mix as the “Russell Cocktail,” which was what his Echus Overlook team had called it in the old days. The halocarbons in the cocktail were powerful greenhouse gases, and the best thing about them was that they absorbed outgoing planetary radiation at the 8-to 12-micron wavelength, the so-called “window” where neither water vapor nor CO2 had much absorptive ability. This window, when open, had allowed fantastic amounts of heat to escape back into space, and Sax had decided early on to attempt to close it, by releasing enough of the cocktail so that it would form ten or twenty parts per million of the atmosphere, following the classic early modeling on the subject by McKay et al. So from 2042 on, a major effort had been put into building automated factories, scattered all over the planet, to process the gases from local sources of carbon and sulphur and fluorite, and then release them into the atmosphere. Every year the amounts pumped out had increased, even after the twenty parts per million level had been reached, because they wanted to retain that proportion in an ever-thickening atmosphere, and also because they had to compensate for the continual high-altitude destruction of the halocarbons by UV radiation.

  And as the tables in the Simmon poster made clear, the factories had continued to operate through 2061 and the decades since, keeping the levels at about twenty-six parts per million; and the poster’s conclusion was that these gases had warmed the surface by around 12°K.

  Sax moved on, a little smile fixed on his face. Twelve degrees! Now that was something!—over twenty percent of all the warming they needed, and all by the early and continuous deployment of a nicely designed gas cocktail. It was elegant, it truly was. There was something so comforting about simple physics. . . .

  By now it was ten A.M., and a keynote talk was beginning by H. X. Borazjani, one of the best atmospheric chemists on Mars, concerning just this matter of global warming. Borazjani was apparently going to give his calculations of the contributions of all the attempts at warming that had been made up until 2100, the year before the soletta had come into operation. After estimating individual contributions, he was going to try to judge whether there were any synergistic effects taking place. This talk was therefore one of the crucial talks of the conference, as so many other people’s work was going to be mentioned and evaluated in it.

  It took place in me of the biggest meeting rooms, and the chamber was packed for the occasion, a couple of thousand people in there at least. Sax slipped in right at starting time, and stood at the back behind the last row of chairs.

  Borazjani was a small dark-skinned white-haired man, speaking with a pointer before a large screen, which was now showing video images of the various heating methods that had been tried: black dust and lichen on the poles, the orbiting mirrors that had sailed out from Luna, the moholes, the greenhouse gas factories, the ice asteroids burning up in the atmosphere, the denitrifying bacteria, and then all the rest of the biota.

  Sax had initiated every single one of these processes in the 2040s and ’50s, and he watched the video even more intently than the rest of the audience. The only obvious warming strategy that he had avoided in the early years was the massive release of CO2 into the atmosphere. Those supporting this strategy had wanted to start a runaway greenhouse effect and create a CO2 atmosphere of up to 2 bar, arguing that this would warm the planet tremendously, and stop UV radiation, and encourage rampant plant growth. All true, no doubt; but for humans and other animals it would be poisonous, and though advocates of the plan spoke of a second phase that would scrub the CO2 from the atmosphere and replace it with a breathable one, their methods were vague, as were their time scales, which varied from 100 to 20,000 years. And the sky milk white however long it lasted.

  Sax didn’t find this an elegant solution to the problem. He much preferred his single-phase model, striking directly toward the eventual goal. I
t meant they had always been a bit short on heat, but Sax judged that disadvantage worth it. And he had done his best to find replacements for the heat that CO2 would have added, as for instance the moholes. Unfortunately Borazjani’s estimate of the heat released by the moholes was fairly low; altogether they had added perhaps 5°K to the mean temperature. Weil, there was no getting around it, Sax thought as he tapped notes into his lectern—the only good source of heat was the sun. Thus his aggressive introduction of the orbiting mirrors, which had been growing yearly as sunsailers came out from Luna, where a very efficient production process made them from lunar aluminum. These fleets, Borazjani said, had grown large enough to have added some 5°K to the mean temperature.

  The reduced albedo, an effort which had never been very vigorously pursued, had added some 2 degrees. The two hundred or so nuclear reactors scattered around the planet had added another 1.5 degrees.

  Then Borazjani came to the cocktail of greenhouse gases; but instead of using the 12°K figure from Simmon’s poster, he estimated it was 14°K, and cited a twenty-year-old paper by J. Watkins to support his assertion. Sax had spotted Berkina sitting in the back row near him, and now he sidled over and leaned down until his mouth was by Berkina’s ear, and whispered, “Why isn’t he using Simmon’s work?”

  Berkina grinned and whispered back, “A few years ago Simmon published a paper in which he had taken a very complex figure of the UV-halocarbon interaction from Borazjani. He modified it slightly, and that first time he attributed it to Borazjani, but after that when he used it he only cited his own earlier paper. It’s made Borazjani furious, and he thinks Simmon’s papers on this subject are derivative of Watkins anyway, so whenever he talks about warming he goes back to the Watkins work, and pretends Simmon’s stuff doesn’t exist.”

  “Ah,” Sax said. He straightened up, smiling despite himself at Borazjani’s subtle but telling little payback. And in fact Simmon was there across the room, frowning heavily.

  By now Borazjani had moved on to the warming effects of the water vapor and CO2 that had been released into the atmosphere, which he estimated together as adding another 10°K. “Some of this might be called a synergistic effect,” he said, “as the desorption of CO2 is mainly a result of other warming. But other than that I don’t think we can say that synergy has been much of a factor. The sum of the warming created by all the individual methods matches pretty closely the temperatures reported by weather reports from around the planet.”

  The video screen displayed his final table, and Sax made a simplified copy of it into his lectern:

  From Borazjani 2 February 14, 2102:

  Halocarbons: 14

  H20 and CO2: 10

  Moholes: 5

  Pre-Soletta Mirrors: 5

  Reduced Albedo: 2

  Nuclear Reactors: 1.5

  Borazjani had not even included the windmill heaters, so on his lectern Sax did. Altogether it came to 37.55°K, a very respectable step, Sax thought, toward their goal of 53°+. They had only been going at it for sixty years, and already most summer days were reaching temperatures above freezing, allowing arctic and alpine plant life to flourish, as he had seen in the Arena Glacier area. And all this before the introduction of the soletta, which was raising insolation by twenty percent.

  The question period had begun, and someone brought up the soletta, asking Borazjani if he thought it was necessary, given the progress being made with the other methods.

  Borazjani shrugged in just the way Sax would have. “What does necessary mean?” he replied. “It depends how warm you want it. According to the standard model as initiated by Russell at Echus Overlook, it is important to keep CO2 levels as low as possible. If we do this, then other warming methods are going to have to be applied to compensate for the loss of the heat that CO2 would have contributed. The soletta might be thought of as compensating for the eventual reduction of CO2 to breathable levels.”

  Sax was nodding despite himself.

  Someone else rose and said, “Don’t you think the standard model is inadequate, given the amount of nitrogen we now know we have?”

  “Not if all the nitrogen is put into the atmosphere.”

  But this was an unlikely achievement, as the questioner was quick to point out. A fair percentage of the total would remain in the ground, and in fact was needed there for plants. So they were short on nitrogen, as Sax had always known. And if they kept the amount of CO2 in the air to the lowest levels possible, that left the percentage of oxygen in the air at a dangerously high level, because of its flammability. Another person rose to state that it was possible that the lack of nitrogen could be compensated for by the release of other inert gases, chiefly argon. Sax pursed his lips; he had been introducing argon into the atmosphere since 2042, as he had seen this problem coming, and there were significant amounts of argon in the regolith. But they were not easy to free, as his engineers had found, and as other people were now pointing out. No, the balance of gases in the atmosphere was turning out to be a real problem.

  A woman rose to note that a consortium of transnats coordinated by Armscor was building a continuous shuttle system to harvest nitrogen from the almost pure nitrogen atmosphere of Titan, liquefying it and flying it back to Mars and dumping it in the upper atmosphere. Sax squinted at this, and did some quick calculations on his lectern. His eyebrows shot up when he saw the result. It would take a very great number of shuttle trips to accomplish anything that way, that or else extremely large shuttles. It was remarkable that anyone had thought it worth the investment.

  Now they were discussing the soletta again. It certainly had the capability of compensating for the 5 or 8°K that would be lost if they scrubbed the current amount of CO2 from the air, and probably it would add even more heat than that; theoretically, Sax calculated on his lectern, it could add as much as 22°K. The scrubbing itself would not be easy, someone pointed out. A man standing near Sax, from a Subarashii lab, rose to announce that a demonstration talk on the soletta and the aerial lens would occur later in the conference, when some of these issues would be greatly clarified. He added before sitting down that serious flaws in the single-phase model made the creation of a two-phase model nearly mandatory.

  People rolled their eyes at this, and Borazjani declared that the next meeting in the room needed to begin. No one had commented on his skillful modeling, which had sorted out so plausibly all the contributions of the various warming methods. But in a way this was a sign of respect—no one had challenged the model either, Borazjani’s preeminence in this area being taken for granted. Now people stood, and some went up to talk with him; a thousand, conversations broke out as the rest filed out of the room and into the halls.

  Sax went to lunch with Berkina, in a café just outside the foot of Branch Mesa. Around them scientists from all over Mars ate and talked about the events of the morning. “We think it’s parts per billion.” “No, sulfates behave conservatively.” It sounded like the people at the table next to theirs were assuming there was going to be a shift to a two-phase model. One woman said something about raising the mean temperature to 295°K, seven degrees higher than Terra’s average.

  Sax squinted at all these expressions of haste, of greed for heat. He saw no need to be dissatisfied with the progress that had been made so far. The ultimate goal of the project was not purely heat, after all, but a viable surface. The results so far certainly seemed to give no reason for complaint. The present atmosphere was averaging 160 millibars at the datum, and it was composed about equally of CO2, oxygen, and nitrogen, with trace amounts of argon and other gases. This was riot the mixture Sax wanted to see in the end, but it was the best they had been able to do given the inventory of volátiles they had to begin with. It represented a substantial step on the way to the final mix Sax had in mind. His recipe for this mix, following the early Fogg formulation, was as follows:

  300 millibars nitrogen

  160 millibars oxygen

  30 millibars argon, helium, etc.

&n
bsp; 10 millibars CO2 =

  Total pressure at datum, 500 millibars

  All these amounts had been fixed by physical requirements and limits of various kinds. The total pressure had to be high enough to drive oxygen into the blood, and 500 millibars was what was obtained on Earth at about the 4,000-meter elevation, near the upper limit of what people could live at permanently. Given that it was near the upper limit, it would be best if such a thin atmosphere had more than the Terran percentage of oxygen in it, but it could not be too much more or else fires might be hard to extinguish. Meanwhile CO2 had to be kept below 10 millibars, or else it would be poisonous. As for nitrogen, the more the better, in fact 780 millibars would be ideal, but the total nitrogen inventory on Mars was now estimated at less than 400 millibars, so 300 millibars was as much as one could reasonably ask to put into the air, and perhaps more. Lack of nitrogen was in fact one of the biggest problems the terraforming effort faced; they needed more than they had, both in the air and in their soil.

 

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