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Over the years some of the themes I’ve touched upon in this blog have been about the outdated paradigms shaping public policy. The realisation came to our acute attention with the ongoing economic crisis since 2008. The crisis has precipitated and energised new thinking in economics, as evidenced by the creation of the Institute for New Economic Thinking. The Institute is a place to explore cutting edge ideas, and challenge calcified theories that have prevented the field from keeping pace with the intellectual advances in the natural sciences. However in the coming years the social sciences and humanities will also see great leaps forward in thinking that can potentially transform our political and socio-economic systems.

A book to be published by IPPR, the Institute for Public Policy Research contributes to bringing about this transformation. The book, ‘Complex new world: Translating new economic thinking into public policy’, explores various economic complexities that challenge traditional economic theory.

We live in uncertain economic times. The financial crash and subsequent downturn have shaken the global economic system to its core. If one thing is certain, it is that the events of recent years have thrown mainstream economic thinking into disrepute. In the aftermath of the crash, scholars and commentators are turning to new, heterodox economic theories as a way of better understanding how the economy really works and how the economic system might be managed more effectively. Yet although new economic thinking offers a far better account of how the economic system functions, we don’t yet have a clear idea of its implications for policymaking. In economic policymaking, orthodox economics remains the only game in town.

The shaking of disciplines is also evident in history as the field of cliodynamics attempts to apply scientific methods to understand human history. There are some historians who are deeply sceptical, which a Nature article highlighted earlier this month,

Most historians have abandoned the belief in general laws.


SOURCE: Turchin, P. J. Peace Res. 49, 577–591 (2012)

The challenge for humanity’s intellectuals is to unravel the complexities of human systems and discover the ‘laws’ which govern them so that we are able to meet the great challenges facing us this century. As my colleagues keep telling me we need more social scientists, as we try to build a great team of thinkers. It’s a good time to be in the arts, social sciences and humanities. Great changes are afoot.

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The image shows research by Peter Turchin who “analysed historical records on economic activity, demographic trends and outbursts of violence in the United States, and has come to the conclusion that a new wave of internal strife is already on its way.”

AI scientist Hugo de Garis has prophesied the next great historical conflict will be between those who would build gods and those who would stop them.

It seems to be happening before our eyes as the incredible pace of scientific discovery leaves our imaginations behind.

We need only flush the toilet to power the artificial mega mind coming into existence within the next few decades. I am actually not intentionally trying to write anything bizarre- it is just this strange planet we are living on.

http://www.sciencedaily.com/releases/2012/08/120813155525.htm

http://www.sciencedaily.com/releases/2012/08/120813123034.htm

This essay was posted previously last year and removed and has appeared in abridged form in the European Space Safety online Magazine and can also be found on Yahoo voices.

Several dates are cited as marking the beginning of the space age. Sputnik, October 4th, 1957, Yuri’s day April 12th, 1961, and the first successful V-2 launch by the Nazis on October 3rd, 1942, to name a few. Some prefer December 21st, 1968, when human beings first escaped the Earth’s gravitational field on Apollo 8. When studying the events that allowed man to leave Earth, future historians may agree on a date not generally associated with space flight. July 16th, 1945 was Trinity, the first nuclear weapon test. Stanislaw Ulam, a 36-year-old Polish mathematician who helped build “the gadget”, visited ground zero after the test. Ulam later conceived the idea of propelling a spaceship with atomic bombs. Near the end of his life the eccentric genius stated the idea was his greatest work.

When considering nuclear propulsion, it must be understood that space is not an ocean, though often characterized as one. The distances and conditions are not comparable. While chemical energy has allowed humankind to travel across and above the surface of Earth, the energy required to travel in space is of a different order. Water, in the form of steam, was the agent of change that brought about the industrial revolution. Fossil fuel, burned and transformed by steam into mechanical work, would radically change the world in the span of a century. What is difficult for moderns to understand is not only how limited human capabilities were before steam, but how limited they are in the present in terms of space travel. The psychological limits of human beings limit space journeys to a few years. Chemical propulsion is not capable of taking human beings to the outer solar system and back within those crew limits. The solution is a reaction one million times more powerful. Nuclear energy is to the space age as steam was to the industrial age.

Space is not an ocean and this was the correct lesson drawn by Stanislaw Ulam after that suddenly bright morning in 1945. While metal can barely contain and harness chemical energy, Ulam thought outside that box and accepted nuclear energy could never be contained efficiently by any material. However, nuclear energy could be harnessed to push a spaceship in separate events to the fantastic velocities required for interplanetary travel without any containment problems at all- by using bombs. An uncontained burst of nuclear generated plasma could be withstood by a surface momentarily before the physical matter had time to melt.

Sixty years after Ulam’s stroke of genius, atomic bomb propulsion still has no competition as the only available propulsion system for practical interplanetary travel. This fact is almost completely unknown to the public. The term “ISP”, expressed in seconds, is used in measuring the efficiency of a rocket engine and chemical rockets have low ISP numbers but high thrust. The most efficient rocket engines, such as the space shuttle main engines, with a listed ISP of 453 seconds are also among the most powerful. Atomic bomb propulsion, thanks to the billions of dollars poured into star wars weapons research, would have an ISP exceeding 100,000 seconds. While other propulsion systems that use electricity have similar or higher numbers, the amount of thrust is trivial and requires months or years of continuous operation to develop any significant velocity. Considering space travel as not only a speed and distance problem, but also a time and distance problem, low thrust lengthens any missions to the outer solar system beyond crew limits. The thrust imparted by atomic bombs can in a short period easily accelerate thousands of tons to the comparatively extreme speeds necessary and then coast. Unlike an electric propulsion failure, a few dud bombs need not doom a mission or crew.

Though an incredible use of awesome power, the obstacles to employing bomb propulsion are not technical as some of the best engineers and physicists on the planet evaluated and validated the concept. A cadre of celebrity scientists also endorsed atomic bomb propulsion, including Werner Von Braun, who was present as a Nazi SS officer at the first successful V-2 launch, and as an American citizen at the launch of Apollo 8. Arthur C. Clarke and Carl Sagan were also supporters. The first serious work on bomb propulsion was done by physicist Freeman Dyson and weapon designer Ted Taylor on the top secret project Orion. Dyson’s son, in his book Project Orion, refers to the classified star wars project Casaba Howitzer. This device focused most of the energy of a nuclear explosion in one direction. Ted Taylor’s specialty was small warheads and he designed the Orion bombs, aka “pulse units.” The “unclassified” state of the art in nuclear weapons can direct 80 percent of bomb energy into a slab of propellant, converting this mass into a jet of superheated plasma. A pusher plate would absorb the blast without melting for the fraction of a second it lasts and accelerate the spaceship in steps with each bomb. Perhaps the closest experience to riding in an atomic bomb propelled spaceship would be repeated aircraft carrier catapult launches. Instead of the ocean- space, instead of supersonic fighters- a thousand ton spaceship.

Project Orion was canceled due to nuclear weapon treaties requiring international consent for using any such devices in space. A parallel to the failure of atomic bomb propulsion may be found in an examination of the industrial age. In The Most Powerful Idea in the World: A Story of Steam, Industry, and Invention, author William Rosen theorizes English patent law was the key enabler of the industrial age by allowing inventors to retain and profit from their intellectual property. The atomic bomb originated with a letter to President Roosevelt in 1939 from pacifist Albert Einstein- who was afraid the Nazi’s might build one first. With the human race living at the bottom of a deep, damp, and easily contaminated gravity well, atom bombs have never been applied successfully to a peaceful purpose. Stan Ulam, who lost most of his family in the holocaust, held the patent on atomic bomb propulsion. In the space age, nuclear weapon treaties and anti-nuclear activism have had the opposite effect of patent law and prevented atomic bomb propulsion from opening up the solar system to human exploration and colonization. Ironically, the nuclear industry is not safe on Earth- but deep space seems designed for it. There are no contamination or waste hazards, no long-term storage problems.

The problems with space travel are more than just the political barriers to detonating nuclear devices. The space industry is ipso facto a nuclear industry. Not only is nuclear energy the only practical source of propulsion in deep space, nuclear radiation generated by supernova and other celestial sources permeate space outside the protection of the earth’s atmosphere. All astronauts are radiation workers. Most, but sadly not all, space radiation is relatively easy to shield against. Many will argue using atomic bombs for propulsion is unnecessary. The presence of a small percentage of highly damaging and deeply penetrating particles- the heavy nuclei component of galactic cosmic rays makes a super powerful propulsion system mandatory. The tremendous power of atomic bomb propulsion is certainly able to propel the heavily shielded capsules required to protect space travelers. The great mass of shielding makes chemical engines, inefficient nuclear thermal rockets, the low thrust forms of electrical propulsion, and solar sails essentially worthless for human deep space flight. Which is why atomic bomb propulsion is left as the only “off the shelf” viable means of propulsion. For the foreseeable future, high thrust and high ISP to propel heavy shielding to the required velocities is only possible using bombs. The most useful and available form of radiation shielding is water. While space may not be an ocean, it appears human beings will have to take some of the ocean with them to survive.

The water comes before the bombs in human space flight because of the humans. The radiation hazards of long duration human space flight beyond earth orbit are only recently being addressed after decades of space station experience. The reason for this neglect is low earth orbit space stations are shielded from much of the radiation found outside the Earth’s Van Allen belts and magnetic field. An appreciation of the heavy nuclei component of galactic cosmic radiation, as well as solar events, will put multi-year human missions beyond earth orbit on hold indefinitely until a practical shield is available. While vested interests continue to promote inferior or non-existent technology, dismissing the radiation hazards and making promises they cannot keep, radiation scientists studying deep space conditions are skeptical- to say the least.

In the March 2006 issue of Scientific American magazine, Dr. Eugene Parker explained in simple terms survivable deep space travel. In “Shielding Space Travelers”, Parker states, “cosmic rays pose irreducible risks.” The premise of this statement is revealed when the only guaranteed solution to reducing the risk- a shield massing hundreds of tons- is deemed impractical. Active magnetic shields and other schemes are likewise of no use because while they may stop most radiation, the only effective barrier to heavy nuclei is mass and distance. The impracticality of a massive shield is due to first the expense of lifting hundreds of tons of shielding into space from Earth, and secondly propelling this mass around the solar system. Propelling this mass is not a problem if using atomic bombs, however, another problem arises. Even if the bombs could be politically managed, there is still the need to escape Earth’s gravitational field with all that shielding. Bomb propulsion is ideal for deep space but cannot be used in Earth orbit due to the Earth’s magnetic field trapping radioactive fallout that eventually enters the atmosphere. Not only lifting the shielding into orbit but chemically boosting it to a higher escape velocity away from the Earth is thus doubly problematic. Earth is a deep gravity well to climb out of.

The situation changed in March 2010 when NASA reported Mini-SAR radar aboard the Chandrayaan-1 lunar space probe had detected what appeared to be ice deposits at the lunar North Pole. An estimated 600 million tons of ice in sheets a couple meters thick. Moon water would allow a spaceship in lunar orbit to fill an outer hull with the 500+ tons of water required to effectively shield a capsule from heavy nuclei. This would enable an empty spaceship to “travel light” to the Moon and then boost out of lunar orbit using atomic bomb propulsion with a full radiation shield. Parker’s guaranteed but impractical solution had suddenly become practical. Fourteen feet of water equals the protection of the Earth’s air column at an altitude of 18,000 feet above sea level. This would protect astronauts not only from all forms of cosmic radiation but the most intense solar storms and the radiation belts found near the moons of Jupiter. With water and bombs, epic missions of exploration to the asteroid belt and outer planets are entirely possible. The main obstacles are again political, not technical. Bombs work, water works, and the Moon is in range of chemically propelled spacecraft launched from Earth.

There are other challenges to long duration beyond earth orbit human space flight but the solutions have been known for many decades. Zero gravity debilitation causes astronauts to weaken and permanently lose bone and bone marrow mass. The most practical solution, theorized since the early 1930′s, was investigated in 1966 during the Gemini 11 mission. A 100-foot tether experiment with the capsule attached to an Agena booster was successful in generating a small amount of artificial gravity by spinning the two vehicles. Equal masses on the ends of a tether can efficiently generate centrifugal force equal to one gravity. The concept is to “split the ship” when not maneuvering under power so the 500+ tons of shielded capsule is on one end and the rest of the craft of equal mass is reeled out on the other end of a thousand foot or more tether. Looking out through 14 feet of water, the crew of such a spaceship would view a slowly rotating star field. Long duration missions may last close to half a decade and the only option for providing air and water is to use a miniature version of Earth’s ecosystem. Equipment to enable a closed cycle life support system providing years of air and water is now available in the form of plasma reformers and facilitated by tons of water in which to grow algae or genetically modified organisms. With Earth radiation, Earth gravity, and air and water endlessly purified on board, crews can push their psychological limits as many years and as far out into the solar system as the speed of their atomic spaceships allow.

At the time of this writing, in early 2011, the outlook for human space flight is not encouraging. There are zero prospects for funding a long duration beyond earth orbit mission. Using atomic bombs to push minimum spaceship masses of over one thousand tons around the solar system for years at a time would cost as much as several major U.S. department of defense projects combined. Space flight is inherently expensive; there is no cheap. However, there is a completely valid military mission for atomic bomb propelled spaceships. Planetary protection became an issue in 1980 after the Chicxulub impact crater in Mexico was assigned blame for the mass extinction of the dinosaurs. Though overshadowed by the cold war, the impact threat remains. Comet and asteroid impacts are also the stuff of Hollywood movies and this is unfortunate in that a grave threat to the survival of life on earth is viewed as fictional entertainment. The impact threat is not science fiction; it is quite real, as the frequent near misses and geologic evidence of repeated extinction events show. Optimized directional bombs used in bomb propulsion could also be employed to deflect comets and asteroids long before they approach Earth.

While the consequences of ignoring the threat of an inevitable tsunami, earthquake, or hurricane are bad, the consequences of ignoring the inevitable comet or asteroid impact are apocalyptic. It is not only random impacts that could strike at any time the human race need guard against. In April of 2010 renowned physicist Stephen Hawking warned of alien civilizations posing a possible threat to humanity. Several large comets purposely crashed into a planet to wipe out the majority of indigenous life and prepare for the introduction of invasive alien species may be a common occurrence in the galaxy. Before readers scoff, they might consider towers brought down by jetliners, the discovery of millions of planets, and other recent unlikely events. It is within our power to defend Earth from the very real threat of an impact, and at this time self-defense is the only valid reason to go into space instead of spending the resources on Earth improving the human condition. Protecting our species from extinction is the penultimate moral high ground above all other calls on public funds. The vast treasure expended by nations threatening each other is not protecting the human race at all. Earth is defenseless. President Ronald Reagan in his 1983 Star Wars speech said, “I call upon the scientific community who gave us nuclear weapons to turn their great talents to the cause of mankind and world peace.” President Barack Obama has expressed a desire to reduce the world nuclear arsenal and converting these weapons to propulsion devices would do so. A powerful force of nuclear powered, propelled, and armed spaceships cannot guarantee Earth will not suffer a catastrophe. The best insurance for our species is to establish, in concert with a spaceship fleet, several independent self-supporting off world colonies in the outer solar system. The first such colony would mark the beginning of a new age.

Time line

1939 (August) Einstein sends letter recommending atomic bomb.

1939 (September) Germany invades Poland, World War 2 begins.

1942 First successful V-2 rocket launch by the Nazis.

1945 Trinity, the first atomic bomb is detonated.

1957 Sputnik achieves orbit using a rocket designed to carry an atomic bomb.

1961 Yuri Gagarin orbits Earth.

1966 Gemini 11 mission demonstrates artificial gravity.

1967 Outer Space Treaty restricts nuclear weapons in space.

1968 Apollo 8 crew escapes Earth’s gravitational field.

1980 Chicxulub impact crater revealed as dinosaur killer.

1983 Ronald Reagan gives Star Wars speech.

2006 Eugene Parker explains survivable deep space travel.

2010 (March) Millions of tons of ice are discovered on the Moon.

2010 (April) Stephen Hawking warns of alien civilization threat.

References

George Dyson, 2002, Project Orion: The True story of the Atomic Spaceship, Henry Holt and Company, LLC

Eugene Parker, March 2006, Shielding Space Travelers, Scientific American Magazine

William Rosen, 2010, The Most Powerful Idea in the World: A Story of Steam, Industry, and Invention, Random House

Recently Seth Shostak of the SETI Institute, wrote an article in the Huffington Post How to Find Extraterrestrial Life. He had proposed that the search for extraterrestrial life was a three-way horse race. According to Shostak:

(1) Discover Life Nearby: This is the search for life in our solar system.

(2) Sniff It Out: Do the sort of spectral analysis that might detect atmospheric gases caused by biology.

(3) Eavesdrop On ET: Otherwise known as SETI, is the effort to detect radio signals or laser flashes from technically savvy extraterrestrials.

Neat, Shostak has set the frame work for further dscussions. Note that the (1) is the search for the existance of life based molecules. That (2) is the search for life forms, whether past or present. And (3) is the search for extraterrestrial intelligence.

He says that a priori all are equally likely to be successful. Lets think again.

With respect to (1) Discover Life Nearby, lets look at the record. Using the Mars Exploration Rovers, Spirit & Opportunity, as examples, Spirit which was 2.3m wide, covered 8.81 km over 581 sols (a Martian day that is approximately an Earth day), that is approximately 19 m2 per day. Given that the surface of Mars is 144,798,500 km2 it will take Spirit about 7.6 x 1012 days or 208,340,844 centuries, to examine the total surface of Mars. That is, assuming randomness, and that life did exist on Mars in the past, the quick & dirty probability of finding life on Mars on any day with current technology is 1.3 x 10-13. We have a better idea of Mars. It is mostly barren. However, not a clue about the Europa the moon of Jupiter, that is believed to have oceans beneath its ice.

With current projections it likely that NASA will have a satellite at Europa in the 2020–2030 time frame.

So, we can make 2 types of guesses. Assuming that life started on Europa some millions ago, then the probability (from a detection perspective) of finding life on Europa is good, close to 1. However, if Europa is a liquid version of Mars, then the probability is on the order of 1 x 10-13.

Therefore, the time frame for discovery of extraterrestrial life by (1) Discover Life Nearby, is about 2025 assuming no budgets cuts or other re-prioritizations.

With respect to (2) Sniff It Out, scientists estimate that there are about 1 x 1010 Earth like planets in our Milky Way. Lets assume that the Goldilocks Zone is a necessity. Using Pluto as the outer extreme of planets in a Star Local system, and Mars and Venus as boundaries of our Goldilocks Zone, then the approximate probability of finding one of these Earth-like planets in the Goldilocks Zone is 2.89 x 10-2. This reduces the number of Earth-like planets capable of supporting life to 289,340,102. Or the probability of finding life on at least one of these planets (assuming life is present) is at least 3.45 x 10-9.

I would estimate that the time frame for detecting extraterrestrial life is between today, and 35 years from now to 2047.

It could be any day now as the Dutch using the Very Large Telescope in the Chilean Andes have detected carbon monoxide on a planet hugging the star Tau Bootis that is 51 light-years away. The other end of my estimate is 2047. This is because developing a technology like the James Webb telescope was 30 years in the making.

So (2) Sniff It Out, has a better chance of finding evidence of life than (1) Discover Life Nearby.

Now how about (3) Eavesdrop On ET? As the author of the 12-year study An Introduction to Gravity Modification, it is slim. Sorry, Tarter, Shostak and all of you at the SETI Institute. But wait, I haven’t finished.

Look at our civilization. In 1895 Guglielmo Marconi proved that long distance radio transmission was possible. In 117 years we have exponentially evolved our technological sophistication to what it is today, 2012.

As the author of the 12-year study An Introduction to Gravity Modification I have proposed (see page 195) the existence of subspace, where everything is probabilistic, and light speed is not a restriction. Therefore, if confirmed, there is the strong possibility that by 2025/2035 this planet will go radio silent, because all our transmissions will be through subspace.

That is, the window to observe a radio intelligent extraterrestrial civilization is about 100 to 150 years, then they go silent. 100–150 years is an immensely thin slice or duration compared to the distances of stars even within our own galaxy, the Milky Way. Or the probability of detecting extraterrestrial radio transmissions within our own galaxy is approximately 1.25 x 10-6. It is actually a little better than this but I am using quick & dirty for this blog posting, and this will do. This is much better than a posteriori 1 x 10-13 for (1) Discover Life Nearby and 3.45 x 10-9 for (2) Sniff It Out.

So SETI, keep eavesdropping, and we can expect confirmation of Extraterrestrial Life by 2047 latest.

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Benjamin T Solomon is the author & principal investigator of the 12-year study into the theoretical & technological feasibility of gravitation modification, titled An Introduction to Gravity Modification, to achieve interstellar travel in our lifetimes. For more information visit iSETI LLC, Interstellar Space Exploration Technology Initiative

“If the rate of change on the outside
exceeds the rate of change on the inside, the end is near”
- Jack Welch

Complex societies are heavily addicted to expensive, vulnerable and potentially hazardous infrastructure. We rely on a healthy environment for production of food and access to clean water. We depend on technological infrastructure for energy supplies and communications. We are deeply addicted to economic growth to support growing populations and consumption. If one of these pillars of modern society crumbles our existence will collapse like a house of cards.

The interdependencies and complexities of the system we call modern society has become so intertangled that finding a robust and simple solution to our problems has become close to impossible. Historically the cold war gave us the logic of a “balance of terror”. This logic, originally concerned with a balance of U.S. vs. Soviet military capacities, has lead to an increasingly expensive way of reducing risk and ever expanding bureaucracies to keep us “virtually safe”.

With the onset of a global economic recession, drastic climate change, deadly natural disasters, raging civil wars and diminishing natural resources we need a new logic. A set of moral laws for reducing risk and mitigating consequences applicable at a low cost from the bottom up of entire societies.

The concept of resilience is based on the idea that disasters are inevitable and a natural part of existence. Our best defense is preparedness and engineering systems that not only can withstand heavy strains but also absorb damage. The Institute for Resilient Infrastructure at the University of Leeds gives this definition of “Resilience”;

Resilience can also be explained in terms of durability. A durable material, component or system is one which can cope with all the known, predictable loads to which it will be subjected throughout its life. As well as physical loads – stresses and strains – we include environmental loads (e.g. temperature, weather), economic loads (e.g. the scarcity of resources or financial turmoil) and social loads (e.g. changes in legislation or of use, terrorist attack, changes in demography or society’s expectations and demands).

In the 1970s about 100 disasters were recorded worldwide every year. According to the International Disaster Database an average of 392 disasters were reported per year in the last decade. In 2011 we saw record greenhouse gas emissions, melting Arctic sea ice, extreme weather and the earthquake in Japan resulting in the world’s second worst nuclear disaster. Current systems for mitigation of risk are obviously not capable of handling the overwhelming challenges confronting us.

The price tag for disasters in 2011 reached a record high of $265 billion. Most of that cost ($210 billion) came from the tsunami in Japan, but flooding in Australia, tornadoes in the United States and earthquakes in New Zealand contributed substantially. The increasingly turbulent weather patterns wreaking havoc across the planet may only be the beginning of a period of drastic climate change.

In addition to climate change industrial society faces depleted natural resources, degradation of infrastructure and systemic limits to growth. The ongoing economic crisis is a symptom of a deeper structural failure. Governments are running out of options when solving a debt crisis with more debt is the last resort. We rely on short term solutions for long term problems.

We are facing a different type of threat originating from within the system itself, an endogenous and internal failure of our civilizational paradigm. Growing populations stress our dependency on non-renewable resources supported by potentially hazardous nuclear power. The case of the Fukushima nuclear accident illustrates that large population located on limited land is extremely vulnerable to unpredictable events like earthquakes or other catastrophic “wild cards”. From the perspective of risk analysis the state of Japan is a model of the entire planet.

To make the situation even more acute the horizon of Homo Sapiens is full of threats like global pandemics and emerging technologies that could permanently wipe us off the face of the earth. Nanotechnology, synthetic biology and geoengineering hold the promise of a quick fix but also have the potential to cause irreversible harm to the biosphere and human life.

Technology is without a doubt a part of a permanent solution for sustainable life on the planet. The bottom up approach to resilience is about awakening a culture that rewards autonomy and self-sufficiency. Resilience is more than durable engineering. Resilience has to become an obligatory way of thinking and eventually a way of life.

10 robust resilient strategies:
1. Sustain a culture that rewards autonomy and self-sufficiency.
2. Share practical solutions and stockpile resilient ideas instead of canned food.
3. Support intra-generational sharing of knowledge on how to live in accord with nature.
4. Develop alternative economic systems; use Bitcoins and barter when possible.
5. Refine high-tech solutions but favor low tech; HAM radios beat cell phones in emergencies.
6. Grow your own food; become an urban gardener or start a farm revival project.
7. Reduce energy consumption with geothermal energy, local water mills, wind mills and solar panels.
8. Use a condom; think eugenically — act passionately.
9. Keep a gun; if you are forced to pull it – know how to use it.
10. Stay alive for the sake of the next generation.

This article is co-published on Interesting Times Magazine.

The unknown troubles and attracts us. We long to discover a reason for our existence. We look out to the stars through the darkness of space to observe phenomena incredibly far distances away. Many of us are curious about the things we see, these unknowns.

Yet, many of us look skyward and are uninspired, believing that our time and resources best be kept grounded. Despite our human-centered ideologies, our self-assured prophecies, our religious and philosophical beliefs, no existential rationale seems apparent.

We as people welcome technology into our lives and use it constantly to communicate and function. Scientific discoveries pique the interest of every citizen in every country, and technological revolutions have always preceded social and political revolutions from the creation of the internet back to man’s first use of simple tools. Leaders of nations proclaim the importance of science and discovery to our welfare to be utmost.

But what we have seen done recently contradicts these proclamations: space programs are closed; science funding for schools always falls short; and we see no emphasis of the significance of science in our modern culture. Our governments call for the best but provide capital for only the satisfactory, if even. We no longer succumb to the allure of learning simply for the sake of knowing what we once did not know. We have stopped dreaming.

The exploration of space is as related to earthly affairs as any trek, perhaps even more so, because what we learn along the way directly affects the knowledge we apply to our politics, our religions, societies, and sciences. We learn about ourselves, our dreams, our fears. We learn about our strengths and our weaknesses as nations and as a species. In searching the void all around us we learn how to interact with each other and bridge differences between races, religions, genders, and ideologies. The societies of Earth need to emphasize the importance of discovery and innovation to the longevity of mankind, as well as the very human need for the pursuit of challenge.

We are and always have been an adaptable species capable of creating dreams and accomplishing them. We should seek to explore our new frontier and chase ideas yet to even be conceived. The exploration of space has lifted our human spirit, enlightened us, and has made lucid and close our fragility and responsibilities. Perhaps our inhibitions and worries, and our craving to overcome them fuels our explorative ambitions.

If we desire greater purpose then let us earn it; through hardship to the stars! The sky is no longer a limit, but a starting point. We can define our lives, and our existence, by how we accept and handle the unknown; our significance as humans set forth by our bravery and intelligence. Regardless of our qualms and fears, exploration of the unknown is an intrinsic passion of mankind. Why not remind ourselves of what has advanced us thus far?

As the astrophysicist and activist Carl Sagan said, “We were hunters and foragers. The frontier was everywhere. We were bounded only by the earth and the ocean and the sky.” Let us now explore the boundless, and go forth into the starry-night, fresh and inspired, ready to accept any challenge, just as those before us did, when they first set sail for the unknown.

Read the original post at bmseifert.com.

ENVIRONMENT & BACKGROUND

China is a rising world power with: increasing international economic power; improving military strength; tumultuous social issues. Exiting from the recent global economic and financial crisis, China sees itself strengthening and growing while America (and much of the ‘Western’ world) struggles to recuperate. This recovery disparity has given support to Chinese sentiment suggesting the superiority of Chinese policy and social culture.

China’s newfound (or newly revived) superiority complex has complicated American interaction with the government, where China now appears to be doing everything it can to avoid looking weak and to resist US/Western influence. With China’s rise, incentives for America to pressure democratization, establishment of free market economics, and improvement of human rights have grown in intensity. The US has very direct interests in the ‘Westernization’ of China and China does see benefits to cooperation, however they seem to resist or avert most American challenges to the Sino-status quo.

AVAILABLE OPTIONS

America can become aggressive, passive, apathetic, or cooperative in its relationship with China. The US could seek to dominate China, let China strengthen its own dominance, ‘step out of the picture’, or work with China to grow and develop both countries simultaneously.

It is more likely that the US will work to cooperate with China, perhaps doing so with a passive-aggressive bias that asserts American interests without direct systemic attempts to alter Chinese institutions. China and the US have committed to positive and cooperative relations, however it can be expected that such a commitment will only be honored as long as it serves the interests of both states.

INFLUENCES

Differences over human rights, domestic/foreign policy, democratization, and economic/financial theory and practice will greatly influence how the two states interact. Economically and politically it behooves both states to cooperate in the short and long runs. Also, much of Asia supports and welcomes American presence in the region. As long as the US restrains itself from imperializing the region and overthrowing China’s presence, and as long as China does not attempt to oust America, a relatively stable base that assures permanent presence of both parties in the region can be used to develop further policy on.

America is influenced by its democracy, free market policies, and strong human rights, as well as its desire to impose these principles on other states. The base previously described provides the US with a simple supportive argument; ‘if we’re both going to interact in the same place, we better learn how to interact productively’. The simple presence of such an argument influences America’s decisions as it provides a point China cannot ignore.

The US is very economically interested and invested in the greater Asian region. America will surely seek out policy that improves US — China relations, however it will levy importance on policy that enhances economic efficiency and effectiveness in the region (perhaps at the expense of US — China relations).

Another great influence on America’s decision making process is the power China has in the international system. As a permanent member of the UN Security Council, China’s ability to veto measures and resolutions greatly affects America’s (perceived) international power. Learning to effectively interact with China would improve international US — Chinese efforts.

FINAL DECISION/RECOMMENDATION

US — Chinese relations should focus around three main points: policy cooperation; healthy economic competition; political and cultural respect.

The US should help China grow as a world power, including it in international issues and decision making processes as well as new and/or existing trade organizations. By helping China to grow it shows America is interested in seeing the country develop rather than restraining it. This will make negotiation easier and will help to keep China from making extremist policy decisions. Cooperation shows desire for mutual progress.

Provision of challenging economic competition motivates economic improvement and progress. China artificially inflates its currency, dramatically boosting its exports. However, China has realized it cannot grow/mature on export economics. The US should focus on aiding China to develop its own domestic market. As China’s economy develops, its growth rate will slow as it begins to peak its international efficiency under current economic conditions. China will not remain a manufacturing economy forever. When export-based economic policy no longer supports the country the way it does now China will have to consider new ways to compete efficiently and effectively, and the best way (and currently only way) to do so is to enact free market economic policies. Establishing and continuing healthy economic competition (with reduction of protectionist barriers) will naturally drive China towards free market economics over time as China becomes dissatisfied with its socioeconomic disparities, low GDP-per capita, lack of economic diversification, and constant threat of unemployment-related unrest.

Henry Kissinger stated, “Lecturing a country with a history of millennia about its need to ‘grow up’ and behave ‘responsibly’ can be needlessly grating”. Including China in important international and regional decision making processes shows respect to Chinese policy makers and culture. China is attempting to assert new power domestically, regionally, and internationally. Though the US is concerned with China’s growing power and influence, America needs to realize the main challenge for China has been to maintain domestic stability while simultaneously maintaing sustainable economic development. By respecting Chinese sovereignty and withholding from direct intervention and overly-aggressive assertion, Chinese policy makers are less likely to become defensive. China is intent on showing the world its strength and capability as an important and powerful international and regional actor. Allowing China to develop respect will give America a long-term edge in policy making. The US does need to constantly voice its stance on human rights, economic development, and democratization, though. Failing to maintain its stance would render the US as weak/defeated in Chinese eyes.

DECISION EXPLANATION/RATIONALE

China does not desire poor relations with the United States. Both the US and China want good, stable relations that maximize the capabilities of the two states to seek their own interests while allowing a degree of economic, political, and social cooperation to exist. However America is the regional hegemon. China seeks to displace America. In seeking to displace America, China will resist American influence.

There is a common Chinese perception that the US is damaged/weakening while China is growing and becoming stronger. China will do anything to prevent itself from appearing weak, influenceable, and without regional/international political, economic, and social clout. Therefore, the US should refrain from attempting to directly influence and intervene in Chinese policy as this will only galvanize Chinese self-inflated power and make current and future cooperation more difficult. China will not accept foreign ideas, suggestions, or demands as this would make it look inferior to and impressionable by foreign states. If the US wants to change China it needs to make China believe itself that US-desired reform is in its best interest.

The US needs to get China to come to democratization, free market capitalism, and associated levels of human rights on its own accord, as US intervention will only make these doctrines less attractive to Chinese policy makers. By cooperating on policy development, continuing economic competition, and respecting Chinese sovereignty (and dignity), the US puts itself in an advantageous long-term relations position.

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America has been a spacefaring nation since 1958. Over the past fifty-three years, America overtook its first rival, the Soviet Union (spacefaring since 1957), and maintained its supremacy in the aerospace and aeronautical industries, having the most developed and successful space program, the strongest private aerospace/aeronautical industry, and the most intelligent engineers and scientists. During times where space exploration and advanced scientific research programs seem inappropriate to publicly fund and continue where economic difficulties, contested military actions, and other civil/financial issues seem to demand precedence, it needs to be promoted that NASA (National Aeronautics and Space Administration) is of immense importance to the security and welfare of the United States of America and must remain a national priority. NASA drives STEM (science, technology, engineering, and mathematics) education as well as the development of commercial and defense technologies and works with private engineering and science companies across the country, employing thousands of brilliant engineers, scientists, and technicians to ensure the safety of the American people and maintain the technological and explorational prestige this country has always possessed.

NASA’s accomplishments are inspirational to students. It is capable of orbiting people around the planet in minutes, building a space station, and placing man on the moon, and in doing so powerfully inspires individuals to aspire for careers with the organization. In order to become involved with NASA, a student must study science, technology, engineering and/or mathematics, and by creating a strong incentive for people to study these topics, demand for STEM education increases. As demand increases, more STEM programs will develop and more people will become involved in STEM disciplines. Students studying STEM subjects develop critical thinking skills and strong senses of logic to overcome various problems and conflicts. New generations of engineers and scientists will rise to replace the retiring generations and surpass them in their accomplishments, but only will do so if opportunities to take such careers exist. Should NASA decay, it won’t only be NASA careers disappearing. Jobs at firms like Lockheed Martin, The Boeing Company, Northrop Grumman, Raytheon, and SpaceX among others will be lost as well and some of these firms will face immense downsizing or possibly even be forced to shut down, severely harming motivation for younger American students to pursue a degree or career in STEM related fields.

One of the greatest positive externalities of NASA is the technology developed as ‘spin-off’ used in the commercial and defense industries. When NASA was tasked with putting man on the moon, NASA realized the Apollo capsule would need computing systems installed within it that were far greater in power and far smaller than those currently in use and therefore tasked private industry with the development of compact computing devices that later became the PC and laptop. Without NASA funding, heart rate monitors, thermal video imaging, light emitting diodes, and velcro among many other technologies would not have been developed. While current domestic debate surrounds whether or not NASA should be downsized, enlarged, or completely phased out over time, foreign countries and blocs such as China, India, and the European Space Agency are investing even more time and money into improving their programs, their educational efforts, and plan to surpass American capabilities within the near future. Technological innovation, though still very prevalent within the United States, is beginning to grow very rapidly in foreign countries and more new technologies are being imported rather than exported every day. Instead of questioning whether or not NASA is necessary, America should be questioning what seemingly impossible task NASA should be working on next. Originally, the Apollo project seemed insurmountably difficult. But when national security threats (Soviet technological capabilities during the Cold War) met technological challenges (the Apollo program), NASA proved to be an irreplaceable source of innovation and wonder that united a nation, inspired a generation with dreams of space exploration, and provided a feeling of security to millions of people who feared another devastating war.

Which is also why NASA is critically important in the defense industry as a customer. NASA helps improve private and public defense and communication technologies. The relationship between NASA and the private industry is very symbiotic. NASA develops a plan or project and administers/contracts production and testing tasks out to the private industry, challenging thousands of engineers and scientists to improve their designs and inspires technological and manufacturing developments, which in turn allow NASA to complete its mission in an efficient and effective manner. China has proven it is capable of destroying our satellites by destroying one of its own and has announced its desire to develop a space program separated from America’s influence and plans to land on the moon in 2020. India, Israel, Iran, Pakistan, Romania, Japan, and Ukraine among others have all had confirmed launches and are working to become space powers themselves, developing their own aerospace industries and programs. Iraq and North Korea have also both touted successful launches, though their success are unconfirmed. NASA helps to keep America competitive by constantly challenging private industry and by making sure its goals for space and technological development are always beyond those of other countries, which helps to prevent enemies from defeating our technologies, thus keeping us safe.

NASA’s importance as a national priority is great. It inspires and motivates American students to study math, science, and engineering, expands our knowledge of physics, chemistry, biology, psychology, economics, geography, and oceanography, develops unimaginable technologies, promotes international teamwork with a healthy amount of competition, and unites a nation under a common passion and history for exploration of the unknown. We were once afraid of what may have been beyond the edge of the ocean. Now we’ve become curious about what lies beyond the edge of the universe, and NASA’s journey to explore our reality has so far improved our quality of life, improved our technological advantages, and solidified our defenses against national threats.

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Every year Médecins Sans Frontières/ Doctors Without Borders (MSF) hold a conference to present scientific research carried out by their teams from different parts of the world. This year’s conference highlighted some of the strategic challenges facing MSF, and challenged some of our conceptions of medical humanitarian aid, and international development in light of groundbreaking digital technologies. We are as Paul Conneally passionately articulated in his keynote speech – Digital Humanitarian – ‘on the cusp of a global health revolution’.

Some of the groundbreaking technologies touched upon included crisis mapping, a technology that is still in its infancy, and the era of big data. The possibilities of how healthcare and humanitarian aid will be transformed by the convergence of ideas and technologies were evident in the poster session; humanitarian technology applications showed refugee camps in Kenya being monitored using satellite imagery and a humanitarian field software kit called joekit. Of the talks demonstrating real world examples, a talk by Isabella Panunzi on teleradiology proved to be immensely inspiring.

Isabella’s talk on her experience of applying teleradiology to improve diagnosis of tuberculosis in Thyolo District Hospital, Malawi showcased humanitarian innovation at its best. X-rays are taken at the Malawi hospital and the images are then sent to radiologists in the USA to interpret the images. As a result teleradiology has reduced critical delays and missed diagnosis of TB. This example of digital humanitarianism symbolises a small fraction of what can be potentially achieved in transforming our world. It opens up new possibilities in the transfer of technology and knowledge to the developing world. It also highlights the need for a different approach to modelling the strategic challenges of medical humanitarian aid and international development, and this is where complexity thinking and science can bring together different parts of problems and solutions to construct true holistic solutions.

A talk by Jonathan Smith, lecturer in Global Health and Epidemiology of Microbial Diseases at Yale University, brought together the disciplines of the arts and sciences as he gave an inventive take on using research in the digital age. Visually documenting disease and connecting the ‘emotional component to epidemiological data’ is extremely powerful to create change in global health observed Jonathon, as he showed part of a documentary film he is directing, ‘They Go to Die’, a film about,

four former migrant gold minework­ers in South Africa and Swazi­land who have contracted drug-resistant tuberculosis (TB) and HIV while working at the gold mine. When the miners fail to improve their TB status at the mining hospital, they are sent home to rural areas of South Africa often with no continuation of care or means for treatment. This practice is often referred to as “sending them home to die” by leading health officials. The film raises concerns of disease and human rights violations uniquely though the context of life, love, and family; unlike traditional health films, it focuses on relationships and bonding, not death and disease. It is a film of uniting across cultures and paints a portrait of common humanity.

Jonathon is spearheading the Visual Epidemiology Project, a really exciting project ‘that will integrate sensory engagement (film, artistry) with academic discourse’ and ‘produce future academically valid documentaries on other global health issues.’

I feel like picking up a film camera.

Russia’s hastily convened international conference in St. Petersburg next month is being billed as a last-ditch effort at superpower cooperation in defense of Earth against dangers from space.

But it cannot be overlooked that this conference comes in response to the highly controversial NATO anti-ballistic missile deployments in Eastern Europe. These seriously destabilizing, nuclear defenses are pretexted as a defense against a non-nuclear Iran. In reality, the western moves of anti-missile systems into Poland and Romania create a de facto nuclear first-strike capability for NATO, and they vacate a series of Anti-Ballistic Missile Treaties with the Russians that go back forty years.

Deeply distrustful of these new US and NATO nuclear first-strike capabilities, the Russians announced they will not attend NATO’s planned deterrence summit in Chicago this month. Instead, they are testing Western intentions with a proposal for cooperative project for near-space mapping, surveillance, and defense against Earth-crossing asteroids and other dangerous space objects.

The Russians have invited NATO members as well as forward-thinking space powers to a conference in June in Petrograd. The agenda: Planetary defense against incursions by objects from space. It would be a way of making cooperative plowshares from the space technologies of hair-trigger nuclear terror (2 minutes warning, or less, in the case of the Eastern European ABMs).

It’s an offer the US and other space powers should accept.