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The Best American Science and Nature Writing 2018 Page 3


  But there’s no denying that the marches were unprecedented, and if this anthology really aims to capture the state of science during the past year, it couldn’t ignore them. Laying aside actual research, this was arguably the biggest science story of the year.

  So how to capture the marches? Obviously, we could have included a story or two about them—but meh. How could they hope to capture the energy of actually being there? In my own mind, I kept circling back to the people that day, the scientists and teachers and technicians chanting and carrying signs. And I realized that some of the best “science writing” of the year appeared right there, on those signs. We all knew scientists were smart, but who knew they could be so pithy and witty and cutting as well?

  It seemed appropriate, then, to highlight that wit and wisdom here. Unlike most previous editions of BASNW, the stories here aren’t listed alphabetically by author but grouped into sections by theme. And the title of each section comes directly from a sign at one of the marches. Space stories, for instance, fall under “It’s Not Rocket Science . . . (Actually, Some of It Is).” Profiles of different scientists are gathered under “So Bad, Even the Introverts Are Here.” There is “At the Start of Every Disaster Movie Is a Scientist Being Ignored” for stories on environmental science, and “What Do We Want? Evidence-Based Science. When Do We Want It? After Peer Review.” for stories on rethinking some current paradigms. And so on. I’ve never had more fun putting together a table of contents.

  As I said before, science is a human activity above all, reflecting and refracting all of our passions and obsessions. Former Supreme Court justice Earl Warren once said, “I always turn to the sports pages first, which records people’s accomplishments. The front page has nothing but man’s failures.” I think we’ve all been disillusioned about athletes at this point, but that still holds true in the main for science—it’s largely a record of our accomplishments, however imperfect so far. And when times get bleak, science can help us find direction, too. In “Greetings, E.T. (Please Don’t Murder Us.),” Steven Johnson discusses the promise and peril of making contact with an alien society, and he writes at one point, “Thinking hard about what kinds of civilization we might be able to talk to ends up making us think even harder about what kind of civilization we want to be ourselves.” We could all stand to think about that right now, and I hope these stories can help us along that path—both in making us uncomfortable with the limitations of now and in pointing to where we can get to in the future.

  Sam Kean

  PART I

  “We Are Not Just Resistors, We Are Transformers”

  Transformative Science

  ROSS ANDERSEN

  Pleistocene Park

  from The Atlantic

  Nikita Zimov’s nickname for the vehicle seemed odd at first. It didn’t look like a baby mammoth. It looked like a small tank, with armored wheels and a pit bull’s center of gravity. Only after he smashed us into the first tree did the connection become clear.

  We were driving through a remote forest in Eastern Siberia, just north of the Arctic Circle, when it happened. The summer thaw was in full swing. The undergrowth glowed green, and the air hung heavy with mosquitoes. We had just splashed through a series of deep ponds when, without a word of warning, Nikita veered off the trail and into the trees, ramming us into the trunk of a young 20-foot larch. The wheels spun for a moment, and then surged us forward. A dry crack rang out from under the fender as the larch snapped cleanly at its base and toppled over, falling in the quiet, dignified way that trees do.

  I had never seen Nikita happier. Even seated behind the wheel, he loomed tall and broad-shouldered, his brown hair cut short like a soldier’s. He fixed his large ice-blue eyes on the fallen tree and grinned. I remember thinking that in another age, Nikita might have led a hunter-gatherer band in some wildland of the far north. He squeezed the accelerator, slamming us into another larch, until it too snapped and toppled over, felled by our elephantine force. We rampaged 20 yards with this same violent rhythm—churning wheels, cracking timber, silent fall—before stopping to survey the flattened strip of larches in our wake.

  “In general, I like trees,” Nikita said. “But here, they are against our theory.”

  Behind us, through the fresh gap in the forest, our destination shone in the July sun. Beyond the broken trunks and a few dark tree-lined hills stood Pleistocene Park, a 50-square-mile nature reserve of grassy plains roamed by bison, musk oxen, wild horses, and maybe, in the not-too-distant future, lab-grown woolly mammoths. Though its name winks at Jurassic Park, Nikita, the reserve’s director, was keen to explain that it is not a tourist attraction, or even a species-resurrection project. It is, instead, a radical geoengineering scheme.

  “It will be cute to have mammoths running around here,” he told me. “But I’m not doing this for them, or for any other animals. I’m not one of these crazy scientists that just wants to make the world green. I am trying to solve the larger problem of climate change. I’m doing this for humans. I’ve got three daughters. I’m doing it for them.”

  Pleistocene Park is named for the geological epoch that ended only 12,000 years ago, having begun 2.6 million years earlier. Though colloquially known as the Ice Age, the Pleistocene could easily be called the Grass Age. Even during its deepest chills, when thick, blue-veined glaciers were bearing down on the Mediterranean, huge swaths of the planet were coated in grasslands. In Beringia, the Arctic belt that stretches across Siberia, all of Alaska, and much of Canada’s Yukon, these vast plains of green and gold gave rise to a new biome, a cold-weather version of the African savanna called the Mammoth Steppe. But when the Ice Age ended, many of the grasslands vanished under mysterious circumstances, along with most of the giant species with whom we once shared this Earth.

  Nikita is trying to resurface Beringia with grasslands. He wants to summon the Mammoth Steppe ecosystem, complete with its extinct creatures, back from the underworld of geological layers. The park was founded in 1996, and already it has broken out of its original fences, eating its way into the surrounding tundra scrublands and small forests. If Nikita has his way, Pleistocene Park will spread across Arctic Siberia and into North America, helping to slow the thawing of the Arctic permafrost. Were that frozen underground layer to warm too quickly, it would release some of the world’s most dangerous climate-change accelerants into the atmosphere, visiting catastrophe on human beings and millions of other species.

  In its scope and radicalism, the idea has few peers, save perhaps the scheme to cool the Earth by seeding the atmosphere with silvery mists of sun-reflecting aerosols. Only in Siberia’s empty expanse could an experiment of this scale succeed, and only if human beings learn to cooperate across centuries. This intergenerational work has already begun. It was Nikita’s father, Sergey, who first developed the idea for Pleistocene Park, before ceding control of it to Nikita.

  The Zimovs have a complicated relationship. The father says he had to woo the son back to the Arctic. When Nikita was young, Sergey was, by his own admission, obsessed with work. “I don’t think he even paid attention to me until I was twenty,” Nikita told me. Nikita went away for high school, to a prestigious science academy in Novosibirsk, Siberia’s largest city. He found life there to his liking, and decided to stay for university. Sergey made the journey to Novosibirsk during Nikita’s freshman year and asked him to come home. It would have been easy for Nikita to say no. He soon started dating the woman he would go on to marry. Saying yes to Sergey meant asking her to live, and raise children, in the ice fields at the top of the world. And then there was his pride. “It is difficult to dedicate your life to someone else’s idea,” he told me.

  But Sergey was persuasive. Like many Russians, he has a poetic way of speaking. In the Arctic research community, he is famous for his ability to think across several scientific disciplines. He will spend years nurturing a big idea before previewing it for the field’s luminaries. It will sound crazy at first, several of them told me. “B
ut then you go away and you think,” said Max Holmes, the deputy director of Woods Hole Research Center, in Massachusetts. “And the idea starts to makes sense, and then you can’t come up with a good reason why it’s wrong.”

  Of all the big ideas that have come spilling out of Sergey Zimov, none rouses his passions like Pleistocene Park. He once told me it would be “the largest project in human history.”

  As it happens, human history began in the Pleistocene. Many behaviors that distinguish us from other species emerged during that 2.6-million-year epoch, when glaciers pulsed down from the North Pole at regular intervals. In the flood myths of Noah and Gilgamesh, and in Plato’s story of Atlantis, we get a clue as to what it was like when the last glaciation ended and the ice melted and the seas welled up, swallowing coasts and islands. But human culture has preserved no memory of an oncoming glaciation. We can only imagine what it was like to watch millennia of snow pile up into ice slabs that pushed ever southward. In the epic poems that compress generations of experience, a glaciation would have seemed like a tsunami of ice rolling down from the great white north.

  One of these 10,000-year winters may have inspired our domestication of fire, that still unequaled technological leap that warmed us, warded away predators, and cooked the calorie-dense meals that nourished our growing brains. On our watch, fire evolved quickly, from a bonfire at the center of camp to industrial combustion that powers cities whose glow can be seen from space. But these fossil-fueled fires give off an exhaust, one that is pooling, invisibly, in the thin shell of air around our planet, warming its surface. And nowhere is warming faster, or with greater consequence, than the Arctic.

  Every Arctic winter is an Ice Age in miniature. In late September, the sky darkens and the ice sheet atop the North Pole expands, spreading a surface freeze across the seas of the Arctic Ocean, like a cataract dilating over a blue iris. In October, the freeze hits Siberia’s north coast and continues into the land, sandwiching the soil between surface snowpack and subterranean frost. When the spring sun comes, it melts the snow, but the frozen underground layer remains. Nearly a mile thick in some places, this Siberian permafrost extends through the northern tundra moonscape and well into the taiga forest that stretches, like an evergreen stripe, across Eurasia’s midsection. Similar frozen layers lie beneath the surface in Alaska and the Yukon, and all are now beginning to thaw.

  If this intercontinental ice block warms too quickly, its thawing will send as much greenhouse gas into the atmosphere each year as do all of America’s SUVs, airliners, container ships, factories, and coal-burning plants combined. It could throw the planet’s climate into a calamitous feedback loop, in which faster heating begets faster melting. The more apocalyptic climate-change scenarios will be in play. Coastal population centers could be swamped. Oceans could become more acidic. A mass extinction could rip its way up from the plankton base of the marine food chain. Megadroughts could expand deserts and send hundreds of millions of refugees across borders, triggering global war.

  “Pleistocene Park is meant to slow the thawing of the permafrost,” Nikita told me. The park sits in the transition zone between the Siberian tundra and the dense woods of the taiga. For decades, the Zimovs and their animals have stripped away the region’s dark trees and shrubs to make way for the return of grasslands. Research suggests that these grasslands will reflect more sunlight than the forests and scrub they replace, causing the Arctic to absorb less heat. In winter, the short grass and animal-trampled snow will offer scant insulation, enabling the season’s freeze to reach deeper into the Earth’s crust, cooling the frozen soil beneath and locking one of the world’s most dangerous carbon-dioxide lodes in a thermodynamic vault.

  To test these landscape-scale cooling effects, Nikita will need to import the large herbivores of the Pleistocene. He’s already begun bringing them in from far-off lands, two by two, as though filling an ark. But to grow his Ice Age lawn into a biome that stretches across continents, he needs millions more. He needs wild horses, musk oxen, reindeer, bison, and predators to corral the herbivores into herds. And, to keep the trees beaten back, he needs hundreds of thousands of resurrected woolly mammoths.

  As a species, the woolly mammoth is fresh in its grave. People in Siberia still stumble on frozen mammoth remains with flesh and fur intact. Some scientists have held out hope that one of these carcasses may contain an undamaged cell suitable for cloning. But Jurassic Park notwithstanding, the DNA of a deceased animal decays quickly. Even if a deep freeze spares a cell the ravenous microbial swarms that follow in death’s wake, a few thousand years of cosmic rays will reduce its genetic code to a jumble of unreadable fragments.

  You could wander the entire Earth and not find a mammoth cell with a perfectly preserved nucleus. But you may not need one. A mammoth is merely a cold-adapted member of the elephant family. Asian elephants in zoos have been caught on camera making snowballs with their trunks. Modify the genomes of elephants like those, as nature modified their ancestors’ across hundreds of thousands of years, and you can make your own mammoths.

  The geneticist George Church and a team of scientists at his Harvard lab are trying to do exactly that. In early 2014, using CRISPR, the genome-editing technology, they began flying along the rails of the Asian elephant’s double helix, switching in mammoth traits. They are trying to add cold-resistant hemoglobin and a full-body layer of insulating fat. They want to shrink the elephant’s flapping, expressive ears so they don’t freeze in the Arctic wind, and they want to coat the whole animal in luxurious fur. By October 2014, Church and his team had succeeded in editing 15 of the Asian elephant’s genes. Late last year he told me he was tweaking 30 more, and he said he might need to change only 50 to do the whole job.

  When I asked Beth Shapiro, the world’s foremost expert in extinct species’ DNA, about Church’s work, she gushed. “George Church is awesome,” she said. “He’s on the right path, and no one has made more progress than him. But it’s too early to say whether it will take only 50 genes, because it takes a lot of work to see what each of those changes is going to do to the whole animal.”

  Even if it takes hundreds of gene tweaks, Church won’t have to make a perfect mammoth. If he can resculpt the Asian elephant so it can survive Januarys in Siberia, he can leave natural selection to do the polishing. For instance, mammoth hair was as long as 12 inches, but shorter fur will be fine for Church’s purposes. Yakutian wild horses took less than 1,000 years to regrow long coats after they returned to the Arctic.

  “The gene editing is the easy part,” Church told me, before I left for Pleistocene Park. Assembling the edited cells into an embryo that survives to term is the real challenge, in part because surrogacy is out of the question. Asian elephants are an endangered species. Few scientists want to tinker with their reproductive processes, and no other animal’s womb will do. Instead, the embryos will have to be nurtured in an engineered environment, most likely a tiny sac of uterine cells at first, and then a closet-sized tank where the fetus can grow into a fully formed, 200-pound calf.

  No one has yet brought a mammal to term in an artificial environment. The mammalian mother-child bond, with its precisely timed hormone releases, is beyond the reach of current biotechnology. But scientists are getting closer with mice, whose embryos have now stayed healthy in vitro for almost half of their 20-day gestation period. Church told me he hopes he’ll be manufacturing mice in a lab within five years. And though the elephant’s 22-month gestation period is the longest of any mammal, Church said he hopes it will be a short hop from manufacturing mice to manufacturing mammoths.

  Church has been thinking about making mammoths for some time, but he accelerated his efforts in 2013, after meeting Sergey Zimov at a de-extinction conference in Washington, D.C. Between sessions, Sergey pitched him on his plan to keep Beringia’s permafrost frozen by giving it a top coat of Ice Age grassland. When he explained the mammoth’s crucial role in that ecosystem, Church felt compelled to help. He told me he hopes to deliv
er the first woolly mammoth to Pleistocene Park within a decade.

  Last summer, I traveled 72 hours, across 15 time zones, to reach Pleistocene Park. After Moscow, the towns, airports, and planes shrunk with every flight. The last leg flew out of Yakutsk, a gray city in Russia’s far east, whose name has, like Siberia’s, become shorthand for exile. The small dual-prop plane flew northeast for four hours, carrying about a dozen passengers seated on blue-felt seats with the structural integrity of folding chairs. Most were indigenous people from Northeast Siberia. Some brought goods from warmer climes, including crops that can’t grow atop the permafrost. One woman held a bucket of grapes between her knees.

  We landed in Cherskiy, a dying gold-mining town that sits on the Kolyma River, a 1,323-mile vein of meltwater, the largest of several that gush out of northeastern Russia and into the East Siberian Sea. Stalin built a string of gulags along the Kolyma and packed them with prisoners, who were made to work in the local mines. Solzhenitsyn called the Kolyma the gulag system’s “pole of cold and cruelty.” The region retains its geopolitical cachet today, on account of its proximity to the Arctic Ocean’s vast undersea oil reserves.

  Cherskiy’s airstrip is one of the world’s most remote. Before it became a Cold War stronghold, it was a jumping-off point for expeditions to the North Pole. You need special government permission to fly into Cherskiy. Our plane had just rolled to a halt on the runway’s patchy asphalt when Russian soldiers in fatigues boarded and bounded up to the first row of the cabin, where I was sitting with Grant Slater, an American filmmaker who had come with me to shoot footage of Pleistocene Park. I’d secured the required permission, but Slater was a late addition to the trip, and his paperwork had not come in on time.