Long Now

Held at the historic Castro Theater, almost 1,400 enthusiastic San Francisco history buffs packed in to partake of guerrilla archivist Rick Prelinger’s annual ritual. The audience learned from, laughed at, quizzed and heckled the lovingly curated footage of their city’s past. New material this year (presented for the first time in HD) included San Francisco's lost cemeteries in color, unique drive-through footage of the Produce Market (now Embarcadero Center and Golden Gateway), rides along the now destroyed Embarcadero Freeway, back streets in working-class North Beach, the sand-swept Sunset before its dunes were covered, wild automobile rides through downtown in the 1920s, newly-rediscovered Kodachrome Cinemascope footage of Playland and the Sky Tram, and much more.

Brewster Kahle, founder of the Internet Archive and digital librarian, advocates for universal access to all knowledge. He shares insights on digitizing over 3 million books and how innovative scanning technology is preserving literature for everyone. Kahle discusses the archive's vast music collection, featuring thousands of concerts and collaborations with artists. He emphasizes the urgency of archiving the 20th century and the importance of making educational content freely available, ensuring that both future generations and AIs can benefit from this treasure trove of information.

### Eco-continuity in California California ecology used to be much more driven by floods and fires, Cunningham said, showing with her paintings how the Great Valley would become a vast inland sea, like a huge vernal pool progressing each year from navigable water to intense flower displays to elk-grazed grassland. Lake Merritt in Oakland was a salt water inlet. On the Albany mudflats grizzly bears would tunnel into a beached humpback whale for food, joined by California condors. Every fall at the Carquinez Strait a million four-foot-long Chinook salmon headed inland to spawn. Only 300 years ago the whole Bay Area was grasslands, routinely burned by the local Indians. There were oaks in the valleys, redwoods in the Berkeley Hills, and extensive oak savannahs inland. The hills were greener more of the year than now, with fire-freshened grass attracting elk, and native perennial grasses drawing moisture with their deep roots. Cunningham researched the ancient landscapes using old maps, photos, paintings, scientific reports, sundry local experts, and 30 years of fieldwork. She witnessed the last wild condors feeding on a calf carcass, chasing off a golden eagle. (The condors are now back in the wild, spotted as far north as Mt. Hamilton.) To learn about the behavior and ecological effects of wolves and grizzly bears, she studied them in Yellowstone Park. (The California golden bear was enormous, up to 2,200 pounds.) Along the Pacific shore there used to be 10-ton Steller's sea cows (extinct in 1768), a giant petrel with an 8-foot wingspan, and a flightless diving goose that ate mussels. Further back, in the Ice Ages before 12,000 years ago, the ocean was lower, and San Francisco Bay was a savannah occupied by huge bison (6 feet at the shoulder), a native full-sized horse similar to the African quagga (Cunningham shows it with quagga-like stripes), Columbian mammoths, and the giant short-faced bear (10 feet tall standing up). For current Californians Cunningham encourages local restoration of old ecosystems, perhaps learning to live with more flood and fire. With her multi-millennial perspective, she's pretty relaxed about climate change. As much as long-term ecology is about continuity, it is about change.

### Learning to learn fast To acquire "the meta-skill of acquiring skills," Ferriss recommends approaching any subject with some contrarian analysis: "What if I try the opposite of best practices?" Some conventional wisdom---"children learn languages faster than adults" (no they don't)---can be discarded. Some conventional techniques can be accelerated radically. For instance, don't study Italian in class for a year before your big Italy trip; just book your flight a week early and spend that week cramming the language where it's spoken. You can be fluent in any language with mastery of just 1,200 words. That's what Ferriss calls the "minimum effective dose" for learning a language. The equivalent with any skill or goal is worth identifying. A regular 5 minutes of kettlebell swinging can tone the body rapidly; 30 grams of protein within 30 minutes of waking makes your slow-carb diet effective; just 20,000 "early evangelists" for your book in its first 2 weeks guarantees it becomes a best seller. With any skill, "solve for extremes and anomalies." Look at who's best and how they do it, but especially look for those who are surprisingly good---the wispy girl who can deadlift 405 pounds---because they're doing it with technique rather than genes, and technique is learnable. How do you manage the self-discipline to bear down on learning a skill? Ferriss suggests you begin by treating your new regime as a trial (vowing permanence can be discouraging)--- give it 2 weeks or 5 serious sessions. By that point early rewards from the discipline will keep you going. You have to measure to detect the rewards ("What gets measured gets managed"--Peter Drucker), and score-keeping lets you make your progress a competitive game with others---which becomes its own motivation. Make public bets about your specific goals, where you'll pay painfully if you fail. "Loss aversion" is a surprisingly powerful incentive. You can get profound effects in an amazingly short time, Ferriss concluded. "Doing the unthinkable is easier than you think." PS: [ A collection of all of these summaries of the SALT talks](http://www.amazon.com/Summaries-Condensed-Long-term-Thinking-ebook/dp/B005I57M4O/ref=sr_1_1?s=digital-text&ie=UTF8&qid=1316213727&sr=1-1) is available on the Kindle for $3. Foreword by Brian Eno.

### Superlinear Cities "It's hard to kill a city," West began, "but easy to kill a company." The mean life of companies is 10 years. Cities routinely survive even nuclear bombs. And "cities are the crucible of civilization." They are the major source of innovation and wealth creation. Currently they are growing exponentially. "Every week from now until 2050, one million new people are being added to our cities." "We need," West said, "a grand unified theory of sustainability--- a coarse-grained quantitative, predictive theory of cities." Such a theory already exists in biology, and you can build on that. Working with macroecologist James Brown and others, West explored the fact that living systems such as individual organisms show a shocking consistency of scalability. (The theory they elucidated has long been known in biology as Kleiber's Law.) Animals, for example, range in size over ten orders of magnitude from a shrew to a blue whale. If you plot their metabolic rate against their mass on a log-log graph, you get an absolutely straight line. From mouse to human to elephant, each increase in size requires a proportional increase in energy to maintain it. But the proportion is not linear. Quadrupling in size does not require a quadrupling in energy use. Only a tripling in energy use is needed. It's sublinear; the ratio is 3/4 instead of 4/4. Humans enjoy an economy of scale over mice, as elephants do over us. With each increase in animal size there is a slowing of the pace of life. A shrew's heart beats 1,000 times a minute, a human's 70 times, and an elephant heart beats only 28 times a minute. The lifespans are proportional; shrew life is intense but brief, elephant life long and contemplative. Each animal, independent of size, gets about a billion heartbeats per life. (West added that human bodies run on 100 watts---2,000 calories of food a day. But our civilizational energy use adds up 11,000 watts per person. We're like blue whales walking around.) Does such scalability apply to cities? If you plot, say, the number of gas stations against the size of population of metropolitan areas on a log-log scale, it turns out you get another straight line. Ditto with the length of electrical lines, carbon footprint, etc. Per capita, big city dwellers use less energy than small town dwellers. As with animals, there is greater efficiency with size, this time at a 9/10 ratio. Energy use is sublinear. But unlike animals, cities do not slow down as they get bigger. They speed up with size! The bigger the city, the faster people walk and the faster they innovate. All the productivity-related numbers increase with size---wages, patents, colleges, crimes, AIDS cases---and their ratio is superlinear. It's 1.15/1. With each increase in size, cities get a value-added of 15 percent. Agglomerating people, evidently, increases their efficiency and productivity. Does that go on forever? Cities create problems as they grow, but they create solutions to those problems even faster, so their growth and potential lifespan is in theory unbounded. (West pointed out that there is a bit of variability between cities worth noticing. On the plot of crimes/population, Tokyo has slightly fewer crimes for its size, and Osaka has slightly more. In the U.S., the most patents per capita come from Corvalis, Oregon, and the least from Abiline, Texas. Such variations tend to remain constant over decades, despite everyone's efforts to adjust them. "Exciting cities stay exciting, and boring cities stay boring.") Are corporations more like animals or more like cities? They want to be like cities, with ever increasing productivity as they grow and potentially unbounded lifespans. Unfortunately, West et al.'s research on 22,000 companies shows that as they increase in size from 100 to 1,000,000 employees, their net income and assets (and 23 other metrics) per person increase only at a 4/5 ratio. Like animals and cities they do grow more efficient with size, but unlike cities, their innovation cannot keep pace as their systems gradually decay, requiring ever more costly repair until a fluctuation sinks them. Like animals, companies are sublinear and doomed to die. What is the actual mechanism of difference? Research on that continues. "Cities tolerate crazy people," West observed, "Companies don't."

### Environmentalism for THIS Century Kareiva began by recalling the environmental "golden decade" of 1965-75, set in motion by the scientist Rachel Carson. In quick succession Congress created the Clean Air Act, the Clean Water Act, and the Endangered Species Act---which passed the Senate unanimously. Green influence has been dwindling ever since. A series of polls in the US asked how many agreed with the statement, "Most environmentalists are extremists, not reasonable people." In 1996, 32% agreed. In 2004, 43% agreed. Now it's over 50% who think environmentalists are unreasonable. Kareiva noted that as the world is urbanizing, ever fewer people grow up in contact with nature---current college freshman have less than a tenth of the childhood experience of nature as previous generations. And there's a demographic shift toward multiethnicity, with whites already a minority in California and soon to be a minority in the whole country. Asked to describe a typical environmentalist, current grade school students say it's a girl, white, with money, preachy about recycling, nice but uptight, not sought as a friend. In general, environmentalist have earned the reputation of being "misanthropic, anti-technology, anti-growth, dogmatic, purist, zealous, exclusive pastoralists." Kareiva gave several examples of how that reputation was earned. In Green rhetoric, everything in nature is described as "fragile!"---rivers, forests, the whole planet. It's manifestly untrue. America's eastern forest lost two of its most dominant species---the American chestnut and the passenger pigeon---and never faltered. Bikini Atoll was vaporized in an H-bomb test that boiled the ocean. When National Geographic sent a research team there recently, they found 25% more coral than was ever there before. The Deepwater Horizon oil disaster last year caused dramatically less harm to salt marshes and fisheries than expected, apparently because ocean bacteria ate most of the 5 million barrels of oil. The problem with the fragility illusion is that it encourages a misplaced purism, leaving no room for compromise or negotiation, and it leads to "fortress conservation"---the idea that the only way to protect "fragile" ecosystems is to exclude all people. In Uganda, when a national park was established to protect biodiversity, 5,000 families were forced out of the area. After a change in government, those families returned in anger. To make sure they were never forced out again, they slaughtered all the local wildlife. In the 1980s, Kareiva was a witness in Seattle for protecting old growth forest (and spotted owls). At the courtroom loggers carried signs reading: "You care about owls more than my children." That jarred him. When genetically engineered crops (GMOs) came along, environmentalists responded with "knee-jerk anti-technology religiosity," Kareiva said. How to feed the world was not a consideration. Lessening the overwhelming impact of agriculture on natural systems was not a consideration. Instead, the usual apocalyptic fears were deployed in the usual terms: EVERYTHING'S GOING TO BE DEAD TOMORROW! When Kareiva was working on protecting salmon, he saw the same kind of language employed in a 1999 New York Times full-page ad about dams in the Snake River: TIMELINE TO EXTINCTION! He knew it wasn't true. Salmon are a weedy species, and the re-engineered dams were letting the fish through. The Nature Conservancy---where Kareiva is chief scientist working with the organization's 600 scientists, 4,000 staff, and one million members in 37 countries---promotes a realistic approach to conservation. Instead of demonizing corporations, they collaborate actively with them. They've decided to do the same with farmers, starting an agriculture initiative within the Conservancy. For the growing cities they emphasize the economic value of conservation in terms of valuable clean water and air. They started a program taking inner-city kids out to their field conservation projects not to play but to work on research and restoration. An astonishing 30% of those kids go on to major in science. Kareiva sees conservation in this century as a profoundly social, cooperative undertaking that has to include everyone. New social networking tools can be in the thick of it. For instance, people could use their smartphones to photograph (and geotag, timestamp, and broadcast) the northernmost occurrence of bird species, and the aggregate data could be graphed in real time, showing the increasing effects of global warming on the natural world. When everyone makes science like that, everyone owns it. They've invested.

### What's time to a virus? "Everything about viruses is extreme," Zimmer began. The number of viruses on Earth is estimated to be 1 followed by 31 zeroes. Small as they are, if you stacked them all up, the stack would reach 100 million light years. They are the planet's most abundant organism by far. They're fast. We take decades to reproduce. A flu virus can generate billions of itself in us within hours. And they evolve 10,000 times faster than us, because they're creatively sloppy about making copies of their genomes, and they readily combine genes among varieties when jointly infecting a cell. Each of us has four trillion viruses on board, in 1,500 all-too-fungible varieties. Yet they can also be "time stealthy." You may have a bout of childhood chickenpox that is over in days, but the viruses may hide in your nervous system and emerge decades later as shingles. HIV spreads inexorably because of the lag of months or years between infection and visible symptoms. The earliest record of a virus in human history is the smallpox marks you can see on the mummified face of Ramses V, who died in 1145 BCE. Viruses leave no fossils, but in a sense they ARE fossils, with the ancient gene sequences of retroviruses buried in the genomes of every creature they've infected over the ages. About 8 percent of our genome---some 100,000 elements---comes from viruses, and some of those genes now work for us (enabling the mammalian placenta, for instance). One French scientist revived from our genome a functioning 2-million-year-extinct virus just by deducing the original code from the current variety in that stretch of DNA. For billions of years the planet's life consisted solely of bacteria and their viruses, the bacteriophages. They became a planet force, and remain so today, determining the makeup of the atmosphere, among other things. Every day half of all the bacteria in the oceans are killed by phages. Some of the carbon from the bodies sinks to the bottom, some is freed up to fertilize other life. Ocean viruses cart around and transmit genes for photosynthesis to previously incapable microbes---10 percent of oceanic photosynthesis happens that way. If some day we have to geoengineer the atmosphere to manage climate change, we may want to employ the viruses that are already doing it. Virology will be revolutionizing science for decades to come. One body of investigation suggests that the so-called giant viruses may be a whole fourth domain of life (added to bacteria, archaea, and eukaryotes). As the ultimate parasite, viruses were assumed to come along after life evolved, but they might an instrument of that evolution. One hypothesis is that viruses took primordial RNA and generated DNA to better protect the genes. They might have created life as we know it, a long time ago.

### Wallace beats Darwin The great insight of natural selection was published simultaneously by Charles Darwin and Alfred Russell Wallace in 1858, Flannery pointed out, but their interpretations of the insight then diverged. Darwin's harsh view of "survival of the fittest" led too easily to social Darwinism, eugenics societies, neo-classical economics, and an overly reductionist focus on the "selfish gene." Wallace, by contrast, focussed on the tendency of evolution to generate a world of complex co-dependence, and he became an activist for social justice. At the age of 80 in 1904 Wallace published a book titled _Man's Place in the Universe_ , which proposed that Earth was the only living planet in the Solar System. Flannery regards it as "the foundation text of astrobiology" and, with its view that the atmosphere is an instrument of life, a direct precursor of James Lovelock's Gaia Hypothesis and Earth System Science. The study of Earth systems, in turn, revealed that the atmosphere is 99 percent an artifact of life (minus only the noble gases), that the makeup of the oceans is life-driven (toxic heavy metals were concentrated into ore bodies), and that the whole, in Flannery's terms, constitutes a "commonwealth of virtue," using "geo-pheromones" such ozone, methane, atmospheric dust, and dimethyl sulfide from algae to regulate the stability of a livable planet. It acts like a loosely connected superorganism. The first tightly connected superorganism came 100 million years ago when cockroaches invented agriculture and the division of labor and became termites, building complex skyscrapers with air-conditioning, highways, and garbage dumps. Only 10,000 years ago, humans did the same, inventing agriculture and the division of labor in cities, becoming the most potent superorganism yet. One cause of that, Flannery opined, may be our astonishing genetic uniformity, caused by a near-extinction 70,000 years ago, when only 1,000 to 10,000 breeding pairs of humans survived. The 7 billion of us now alive have less genetic diversity than any random sample of 50 chimpanzees in West Africa. Flannery finds cause for hope in the increasing pace of global agreements to manage the global commons. There was the Comprehensive Test Ban Treaty in 1996, the Stockholm Convention on Persistent Organic Pollutants in 2001, and worthy of an annual holiday on September 16, the 1987 signing of the Montreal Protocol on Substances that Deplete the Ozone Layer. Flannery, who now works full time on climate issues, even takes hope from the last-minute Copenhagen Accord that emerged from the UN climate meeting in 2009, because it brought developing nations into the global project to reduce greenhouse gases. In Flannery's view, Gaia is an infant still. Even if it is the only Gaian planet in the galaxy, with growing skills and rudimentary space travel, it could invest the whole galaxy with life in just 5 to 50 million years---an instant in light of Earth's 4.5 billion years and the universe's 14 billion years. Tim Flannery is the author of _[Here on Earth: A Natural History of the Planet](http://www.amazon.com/Here-Earth-Natural-History-Planet/dp/080211976X/ref=sr_1_1?ie=UTF8&s=books&qid=1304535603&sr=8-1)_.

### Geographical determinism Historians and others who try to explain the world dominance by the West since the 18th century usually put it down to long-term lock-in or short-term accidents, said Morris. The lock-in theories are belied by the dominance of the East from 550 to 1750 CE. The accidents approach is undermined by clear patterns that emerge when you look for them in a rigorous way. Morris has devised a quantitative "social development index" based on evaluating a civilization's energy capture, organization (size of largest cities), information management, and war-making capability. (The details of his method are online here.) When you graph human progress since the last ice age 15,000 years ago, the results show that the West led for all the millennia up till the 6th century CE, fell behind for 1,200 years, then leapt ahead again up to the present day. (The "West" for Morris is the civilizational core that developed agriculture and then cities and empires in the eastern Mediterranean, later spreading across Europe and North America. The "East" is China.) Geography determines how and when regions develop, but new societal capabilities keep redefining what geography means. At first agriculture was limited to regions with reliable rainfall, but once societies grew able to manage large-scale irrigation, the empires of parched regions like Mesopotamia and Egypt could take off, and their rivers became trade routes. The vast steppes of north-central Asia long separated Western and Eastern empires, but once their riches became worth plundering, mounted nomads from the steppes invaded repeatedly, defeating the agrarian armies and carrying germs that unleashed waves of epidemics. The West had the advantage of a trade highway in the Mediterranean that wasn't matched in the East until the 6th century, when the Sui emperors built the Grand Canal 1,500 miles long linking north and south China. Everything then changed with the invention of ocean-going ships and guns in the 13th and 14th centuries. (The gun innovation took only 40 years to spread from China to Europe.) Suddenly the most important geographic fact was the differing sizes of the Atlantic and Pacific oceans. Europeans had only 3,000 miles to travel to conquer the Americas; the Chinese (who had capable ships) faced a 6,000 mile barrier. Atlantic trade gave Europe the wealth and science to start the industrial revolution, and with that the West unleashed a global economy, within which players in the East are now flourishing rapidly. Extending the story to the rest of this century, Morris says that if present trends merely continue, the East will retake leadership by the end of the century. But the accelerating pace of social development may make geography irrelevant. By his index, societies have risen to an index value of 900 during the past fifteen millennia. They are likely to be at a level of 5,000 by century's end, meaning there will be five times as much progress (or catastrophe) in this 100 years as in the past 15,000 years. Books about the future, Morris noted, nearly always portray the future as much like the present. "That," he said, "won't happen." Ian Morris is the author of [_Why the West Rules - For Now_](http://www.amazon.com/Why-West-Rules-Now-Patterns/dp/0374290024).

Alexander Rose, Long Now Executive Director and project manager for the Clock of the Long Now, discussed lessons learned in multi-millennial site design. Rose covers his trip to the Svalbard Global Seed Vault as well as other sites and precedents like the Mormon Genealogical Vault and the Yucca Mountain Nuclear Waste site.