Lifeboat Foundation: Safeguarding Humanity
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Category: sustainability

(Excerpt)

Beyond the managerial challenges (downside risks) presented by the exponential technologies as it is understood in the Technological Singularity and its inherent futuristic forces impacting the present and the future now, there are also some grave global risks that many forms of management have to tackle with immediately.

These grave global risks have nothing to do with advanced science or technology. Many of these hazards stem from nature and some are, as well, man made.

For instance, these grave global risks ─ embodying the Disruptional Singularity ─ are geological, climatological, political, geopolitical, demographic, social, economic, financial, legal and environmental, among others. The Disruptional Singularity’s major risks are gravely threatening us right now, not later.

Read the full document at http://lnkd.in/bYP2nDC

The Future of Scientific Management, Today! (Excerpt)

Transformative and Integrative Risk Management
Andres Agostini was asked this question:

Mr. David Shaw’s question, “…Andres, from your work on the future which management skills need to be developed? Classically the management role is about planning, organizing, leading and controlling. With the changes coming in the future what’s your view on how this management mix needs to change and adapt?…” Question was posited on an Internet Forum, formulated by Mr. David Shaw (Peterborough, United Kingdom) on October 09, 2013.

This is an excerpt from, “…The Future of Scientific Management, Today…” that discusses state-of-the-art management theories and practices. To read the entire piece, just click the link at the end of article.

CONCLUSION

In addition to being aware and adaptable and resilient before the driving forces reshaping the current present and the as-of-now future, THERE ARE SOME EXTRA MANAGEMENT SUGGESTIONS THAT I CONCURRENTLY PRACTICE:

1.- Given the vast amount of insidious risks, futures, challenges, principles, processes, contents, practices, tools, techniques, benefits and opportunities, there needs to be a full-bodied practical and applicable methodology (methodologies are utilized and implemented to solve complex problems and to facilitate the decision-making and anticipatory process).

The manager must always address issues with a Panoramic View and must also exercise the envisioning of both the Whole and the Granularity of Details, along with the embedded (corresponding) interrelationships and dynamics (that is, [i] interrelationships and dynamics of the subtle, [ii] interrelationships and dynamics of the overt and [iii] interrelationships and dynamics of the covert).

Both dynamic complexity and detail complexity, along with fuzzy logic, must be pervasively considered, as well.

To this end, it is wisely argued, …You can’t understand the knot without understanding the strands, but in the future, the strands need not remain tied up in the same way as they are today…”

For instance, disparate skills, talents, dexterities and expertise won’t suffice ever. A cohesive and congruent, yet proven methodology (see the one above) must be optimally implemented.

Subsequently, the Chinese proverb indicates, …Don’t look at the waves but the currents underneath…”

2.- One must always be futurewise and technologically fluent. Don’t fight these extreme forces, just use them! One must use counter-intuitiveness (geometrically non-linearly so), insight, hindsight, foresight and far-sight in every day of the present and future (all of this in the most staggeringly exponential mode). To shed some light, I will share two quotes.

The Panchatantra (body of Eastern philosophical knowledge) establishes, …Knowledge is the true organ of sight, not the eyes.…” And Antonio Machado argues, … An eye is not an eye because you see it; an eye is an eye because it sees you …”

Managers always need a clear, knowledgeable vision. Did you already connect the dots stemming from the Panchatantra and Machado? Did you already integrate those dots into your big-picture vista?

As side effect, British Prime Minister W. E. Gladstone considered, …You cannot fight against the future…”

THE METHOD

3.- In all the Manager does, he / she must observe and apply, at all times, a sine qua non maxim, …everything is related to everything else…”

4.- Always manage as if it were a “project.” Use, at all times, the “…Project Management…” approach.

5.- Always use the systems methodology with the applied omniscience perspective.

In this case, David, I mean to assert: The term “Science” equates to about a 90% of “…Exact Sciences…” and to about 10% of “…Social Sciences…” All science must be instituted with the engineering view.

6.- Always institute beyond-insurance risk management as you boldly integrate it with your futuring skill / expertise.

7.- In my firmest opinion, the following must be complied this way (verbatim): the corporate strategic planning and execution (performing) are a function of a grander application of beyond-insurance risk management.It will never work well the other way around. TAIRM is the optimal mode to do advanced strategic planning and execution (performing).

TAIRM (Transformative and Integrative Risk Management) is not only focused on terminating, mitigating and modulating risks (expenses of treasure and losses of life), but also concentrated on bringing under control fiscally-sound, sustainable organizations and initiatives.

TAIRM underpins sensible business prosperity and sustainable growth and progress.

8.- I also believe that we must pragmatically apply the scientific method in all we manage to the best of our capacities.

If we are “…MANAGERS…” in a Knowledge Economy and Knowledge Era (not a knowledge-driven eon because of superficial and hollow caprices of the follies and simpletons), we must do therefore extensive and intensive learning and un-learning for Life if we want to succeed and be sustainable.

As a consequence, Dr. Noel M. Tichy, PhD. argues, …Today, intellectual assets trump physical assets in nearly every industry…”

Consequently, Alvin Toffler indicates, …In the world of the future, THE NEW ILLITERATE WILL BE THE PERSON WHO HAS NOT LEARNED TO LEARN…”

We don’t need to be scientists to learn some basic principles of advanced science.

EFFORT

Accordingly, Dr. Carl Sagan, PhD. expressed, …We live in a society exquisitely dependent on science and technology, in which hardly anyone knows about science and technology…” And Edward Teller stated,…The science of today is the technology of tomorrow …”

And it is also crucial this quotation by Winston Churchill, …If we are to bring the broad masses of the people in every land to the table of abundance, IT CAN ONLY BE BY THE TIRELESS IMPROVEMENT OF ALL OF OUR MEANS OF TECHNICAL PRODUCTION…”

9.- In any management undertaking, and given the universal volatility and rampant and uninterrupted rate of change, one must think and operate in a fluid womb-to-tomb mode.

The manager must think and operate holistically (both systematically and systemically) at all times.

The manager must also be: i) Multidimensional, ii) Interdisciplinary, iii) Multifaceted, iv) Cross-functional, and v) Multitasking.

That is, the manager must now be an expert state-of-the-art generalist and erudite. ERGO, THIS IS THE NEWEST SPECIALIST AND SPECIALIZATION.

Managers must never manage elements, components or subsystems separately or disparately (that is, they mustn’t ever manage in series).

Managers must always manage all of the entire system at the time (that is, managing in parallel or simultaneously the totality of the whole at once).

10.- In any profession, beginning with management, one must always and cleverly upgrade his / her learning and education until the last exhale.

An African proverb argues, …Tomorrow belongs to the people who prepare for it…” And Winston Churchill established,…The empires of the future are the empires of the mind…” And an ancient Chinese Proverb: …It is not our feet that move us along — it is our minds…”

And Malcolm X observed,…The future belongs to those who prepare for it today…” And Leonard I. Sweet considered, …The future is not something we enter. The future is something we create…”

And finally, James Thomson argued, …Great trials seem to be a necessary preparation for great duties …”

The entire document is available at http://lnkd.in/bYP2nDC

Most of us know helium as that cheap inert lighter-than-air gas we use to fill party balloons and inhale to increase voice-pitch as a party trick for kids. However, helium has much more important uses to humanity — from medical (e.g. MRIs), military and defense (submarine detectors use liquid helium to clean up noisy signals), next-generation nuclear reactors, space shuttles, solar telescopes, infra-red equipment, diving, arc welding, particle physics research (the super-magnets in particle colliders rely on liquid helium), the manufacture of many digital devices, growing silicon crystals, the production of LCDs and optical fibers [1].

The principal reason helium is so important is due to its ultra-low boiling-point and inert nature making it the ultimate coolant of the human race. As the isotope helium-3, helium is also used in nuclear fusion research [2]. However, our Earth supplies of helium are being used at an unprecedented rate and could be depleted within a generation [4] and at the current rate of consumption we will run out within 25 to 30 years. As the gas is often thought of as a cheap gas it is often wasted. However, those who understand the situation, such as Prof Richardson, co-chair of a recent US National Research Council inquiry into the coming helium shortage, warn that the gas is not cheap due to the supply being inexhaustible, but because of the Helium Privatisation Act passed in 1996 by the US Congress.

Helium only accounts for 0.00052% of the Earth’s atmosphere and the majority of the helium harvested comes from beneath the ground being extracted from minerals or tapped gas deposits. This makes it one of the rarest elements of any form on the planet. However, the Act required the helium stores [4] held underground near Amarillo in Texas to be sold off at a fixed rate by 2015 regardless of the market value, to pay off the original cost of the reserve. The Amarillo storage facility holds around half the Earth’s stocks of helium: around a billion cubic meters of the gas. The US currently supplies around 80 percent of the world’s helium supplies, and once this supply is exhausted one can expect the cost of the remaining helium on Earth to increase rapidly — as this is in all practicality quite a non-renewable resource.

There is no chemical way of manufacturing helium, and the supplies we have originated in the very slow radioactive alpha decay that occurs in rocks. It has taken 4.7 billion years for the Earth to accumulate our helium reserves, which we will have exhausted within about a hundred years of the US’s National Helium Reserve having been established in 1925. When this helium is released to the atmosphere, in helium balloons for example, it is lost forever — eventually escaping into space [5][6]. So what shall we do when this crucial resource runs out? Well, in some cases liquid nitrogen (−195°C) may be adopted as a replacement — but in many cases liquid nitrogen cannot be used as a stand alone coolant as tends to be trickier to work with (triple point and melting point at around −210°C) — so the liquid helium is used because it is capable of staying liquid at the extreme cool temperatures required. No more helium means no more helium liquid (−269°C) that is used to cool the NMR (nuclear magnetic resonance apparels), and in other machines such as MRI scanners. One wonders therefore must we look towards space exploration to replenish our most rare of resources on Earth?

Prepare Uranus - A view of Uranus

Helium is actually the second most abundant resource in the Universe, accounting for as much as 24 percent of the Universe’s mass [7] — mostly in stars and the interstellar medium. Mining gas giants for helium has been proposed in a NASA memorandum on the topic [8] which have also have great abundance of this gas, and it has been suggested that such atmospheric mining may be easier than mining on the surfaces of outer-planet moons. While this had focused on the possibility of mining Helium-3 from the atmosphere of Jupiter, with inherent complications of delta-V and radiation exposure, a more appropriate destination for mining regular helium may rest with the more placid ice-giant Uranus (not considered in the memorandum as the predicted concentration of Helium-3 in the helium portion of the atmosphere of Uranus is quite small). Leaving aside specific needs for Helium-3 which can be mined in sufficient volume much closer — on our Moon [9], a large-scale mining mission to Uranus for the more common non-radioactive isotope could ensure the Earth does not have to compromise so many important sectors of modern technology in the near future due to an exhaustion of our helium stock. A relatively lower wind speed (900 km/h, comparing favorably to 2,100 km/h on Neptune), with a lower G-force (surface gravity 0.886 g, escape velocity 21.3 km/s) [10] and an abundance of helium in its atmosphere (15 ± 3%) could make it a more attractive option, despite the distances (approx 20 AU), extreme cold (50-70K) and radiation belts involved. Rationalising complexities in radiation, distance, time and temperatures involved for human piloting of such a cargo craft, it could be considered more suited to an automated mission, remote-controlled under robotics similar to orbiter probes — even though this would introduce an additional set of challenges — in AI and remote control.

However, we have a Catch 22 — NASA space programs use the gas to aid their shuttles [12]. Liquid fuels are volatile. They are packed with corrosive material that could destroy a spacecraft’s casing. To avoid this problem, a craft is filled with helium gas. If this could be replaced in such shuttles with some alternative, and advances in space transportation made to significantly increase the cargo of such ships over interplanetary-distances, perhaps a case could be made for such ambitious gas mining missions, though at present given current NASA expenditure, this would seem like fantasy [13]. Realistic proposals for exploration of Uranus [14] fall far short of these requirements. Helium is a rare and unique element we need for many industrial purposes, but if we don’t conserve and recycle our helium, we are dooming mankind to a future shortage of helium, with little helium left for future generations here on Earth [15] — as for now, replenishing such from space seems like a rather long shot.

————————————————

[1] 8 Surprising High-Tech Uses for Helium — TechNewsDaily
http://www.technewsdaily.com/5769-8-surprising-high-tech-helium.html
[2] Helium-3 as used in Nuclear Fusion Research
http://en.wikipedia.org/wiki/Helium-3
[3] The world is running out of helium — Nobel prize winner Prof Robert Richardson.
http://phys.org/news201853523.html#jCp
[4] The Federal Helium Reserve
http://www.blm.gov/nm/st/en/prog/energy/helium/federal_helium_program.html
[5] Why the World Will Run Out of Helium
http://scienceblogs.com/startswithabang/2012/12/12/why-the-world-will-run-out-of-helium/
[6] Will We Run Out of Helium?
http://chemistry.about.com/b/2012/11/11/will-we-run-out-of-helium.htm
[7] Where Is Helium Found — Universe Today

Where is Helium Found


[8] Bryan Palaszewski. “Atmospheric Mining in the Outer Solar System“
http://www.grc.nasa.gov/WWW/RT/2005/RT/RTB-palaszewski1.html
[9] Mining the Moon for Helium-3 — RocketCitySpacePioneers
http://www.rocketcityspacepioneers.com/space/mining-the-moon-for-helium-3
[10] Uranus — Physical characteristics
http://en.wikipedia.org/wiki/Uranus
[11] Uranus’s Magnetosphere — NASA Voyager VPL
http://voyager.jpl.nasa.gov/science/uranus_magnetosphere.html
[12] Space shuttle use of propellants and fluids — NASA KSC
http://www-pao.ksc.nasa.gov/kscpao/nasafact/pdf/ssp.pdf
[13] Project Icarus: The Gas Mines of Uranus
http://news.discovery.com/space/project-icarus-helium-3-mining-uranus-110531.htm
[14] The case for a Uranus orbiter, Mark Hofstadter et al.
http://www.lpi.usra.edu/decadal/opag/UranusOrbiter_v7.pdf
[15] Why the World Will Run Out of Helium
http://scienceblogs.com/startswithabang/2012/12/12/why-the-world-will-run-out-of-helium/

News this past week on Fukushima has not been exactly reassuring has it. Meanwhile the pro-Nuclear lobby keep counting bananas. Here I’ve gathered together some of the recent news articles on the unfolding crisis. Interested to hear some comments on this one.

Fukushima leak is ‘much worse than we were led to believe’ / Aug 22, 2013, BBC NEWS http://www.bbc.co.uk/news/science-environment-23779561
Serious: Japan hikes Fukushima radiation danger level / August 21, 2013 RT NEWS http://rt.com/news/japan-fukushima-level-three-762/
Japan’s nuclear crisis deepens, China expresses ‘shock’ / Aug 21, 2013/ reuters http://www.reuters.com/article/2013/08/21/us-japan-fukushima-severity-idUSBRE97K02B20130821
Worse than Chernobyl: The inner threat of Fukushima crisis / Aug 20, 2013/ RT http://rt.com/op-edge/chernobyl-fukushima-crisis-catastrophe-715/
Japan nuclear agency upgrades Fukushima alert level / Aug 21, 2013 / BBC NEWS http://www.bbc.co.uk/news/world-asia-23776345
Fukushima apocalypse: Years of ‘duct tape fixes’ could result in ‘millions of deaths’ / Aug 18 2013 / RT http://rt.com/news/fukushima-apocalypse-fuel-removal-598/
Fukushima’s Radioactive Water Leak: What You Should Know / National Geographic, Aug 2013 http://news.nationalgeographic.com/news/energy/2013/08/130807-fukushima-radioactive-water-leak/

By Avi Roy, University of Buckingham

In his essay “Fifty Years Hence”, Winston Churchill speculated, “We shall escape the absurdity of growing a whole chicken in order to eat the breast or wing, by growing these parts separately under a suitable medium.”

At an event in London today, the first hamburger made entirely from meat grown through cell culture will be cooked and consumed before a live audience. In June at the TED Global conference in Edinburgh, Andras Forgacs took a step even beyond Churchill’s hopes. He unveiled the world’s first leather made from cells grown in the lab.

These are historic events. Ones that will change the discussion about lab-grown meat from blue-skies science to a potential consumer product which may soon be found on supermarket shelves and retail stores. And while some may perceive this development as a drastic shake-up in the world of agriculture, it really is part of the trajectory that agricultural technology is already following.

Creating abundance

While modern humans have been around for 160,000 years or so, agriculture only developed about 10,000 years ago, probably helping the human population to grow. A stable food source had tremendous impact on the development of our species and culture, as the time and effort once put towards foraging could now be put towards intellectual achievement and the development of our civilisation.

In recent history though, agricultural technology has developed with the goal of securing food supply. We have been using greenhouses to control the environment where crops grow. We use pesticides, fertilisers and genetic techniques to control and optimise output. We have created efficiencies in plant cultivation to produce more plants that yield more food than ever before.

These patterns in horticulture can be seen in animal husbandry too. From hunting to raising animals for slaughter and from factory farming to the use of antibiotics, hormones and genetic techniques, meat production today is so efficient that we grow more bigger animals faster than ever before. In 2012, the global herd has reached 60 billion land animals to feed 7 billion people.

The trouble with meat

Now, civilisation has come to a point where we are recognising that there are serious problems with the way we produce food. This mass produced food contributes towards our disease burden, challenges food safety, ravages the environment, and plays a major role in deforestation and loss of biodiversity. For meat production, in particular, manipulating animals has led to an epidemic of viruses, resistant bacteria and food-borne illness, apart from animal welfare issues.

But we may be seeing change brought by consumer demand. The public has started caring about the ethical, environmental and health impacts of food production. And beyond consumer demand for thoughtful products, ecological limits are forcing us to evaluate the way food is produced.

A damning report by the United Nations shows that today livestock raised for meat uses more than 80% of Earth’s agricultural land and 27% of Earth’s potable water supply. It produces 18% of global greenhouse gas emissions and the massive quantities of manure produced heavily pollute water. Deforestation and degradation of wildlife habitats happens largely in part to create feed crops, and factory farming conditions are breeding grounds for dangerous disease.

Making everyone on the planet take up vegetarianism is not an option. While there is much merit to reducing (and rejecting) meat consumption, sustainable dietary changes in the Western world will be more than compensated for by the meat intake of the growing middle class in developing countries like China and India.

The future is cultured

The logical step in the evolution of humanity’s food production capacity is to make meat from cells, rather than animals. After all, the meat we consume is simply a collection of tissues. So why should we grow the whole animals when we can only grow the part that we eat?

By doing this we avoid slaughter, animal welfare issues, disease development. This method, if commercialised, is also more sustainable. Animals do not have to be raised from birth, and no resources are shunted towards non-meat tissues. Compared to conventionally grown meat, cultured meat would require up to 99% less land, 96% less water, 45% less energy, and produce up to 96% less greenhouse gas emissions.

Also even without modern scientific tools, for hundreds of years we have been using bacterial cells, yeast and fungus for food purposes. With recent advances in tissue engineering, culturing mammalian cells for meat production seems like a sensible advancement.

Efficiency has been the primary driver of agricultural developments in the past. Now, it should be health, environment and ethics. We need for cultured meat to go beyond the proof of concept. We need it to be on supermarket shelves soon.

Avi Roy does not work for, consult to, own shares in or receive funding from any company or organisation that would benefit from this article, and has no relevant affiliations.

The Conversation

This article was originally published at The Conversation.
Read the original article.

Just five years ago, anybody who spoke of technological unemployment was labeled a luddite, a techno-utopian, or just simply someone who doesn’t understand economics. Today things are very different – anybody from New York Times columnist Tom Friedman to CBS are jumping on the bandwagon.

Robots-Will-Steal-Your-Job-front

Those of us who have been speaking about the tremendous impact of automation in the workforce know very well that this isn’t a fad about to pass, but that it’s a problem that will only exacerbate in the future. Most of us agree on what the problem is (exponential growth of high-tech replacing humans faster and faster), and we agree that education will play a crucial role (and not coincidentally I started a companyEsplori – precisely to address this problem); but very few seem to suggest that we should use this opportunity to re-think our entire economic system and what the purpose of society should be. I am convinced this is exactly what we need to do. Published in 2012, my book, Robots Will Steal Your Job, But That’s OK: How to Survive the Economic Collapse and Be Happy – which you can also read online for free shows we might go about building a better tomorrow.

We have come to believe that we are dependent on governments and corporations for everything, and now that technology is ever more pervasive, our dependence on them is even stronger. And of course we don’t question the cycle of labor-for-income, income-for-survival and the conspicuous consumption model that has become dominant in virtually every country – and that not only is ecologically unsustainable, but it also generates immense income inequality.

Well, I do. I challenge the assumption that we should live to work, and even that we should work to live, for that matter. In an age where we already produce more than enough food, energy, and drinkable water for 7 billion people with little to no human labour, while 780 million lack access to clean water and 860 million are suffering from chronic hunger, it follows that the system we have in place isn’t allocating resources efficiently. And rather than going back to outdated ideologies (i.e. socialism), we can try new forms of societal structure; starting with open source philosophy, shared knowledge, self-reliance, and sustainable communities.

There are many transitional steps that we can take – reduced workweek, reform patent and copyright laws, switch to distributed and renewable energies – and there will be bumps along the road, no doubt. But if we move in the right direction, if we are ready to abandon ideologies and stick to whatever works best, I think we will prevail – simply because we will realise that there is no war other than the one we are fighting with ourselves.

boy_bubble2

There is a real power in the act of physically moving. In so doing, each and every morning I can escape the cacophonous curse of the ubiquitous ESPN in the gym locker room. I toss my bag in my locker and immediately escape to the pure, perfect, custom designed peace of my iPod’s audio world. I also well remember the glorious day I moved away from the hopelessness of my roommate’s awful sub-human, sub-slum stench and into my own private apartment. The universe changed miraculously overnight. I think you can get my drift. The simple act of moving itself can be powerfully transformational. Sometimes, there is not enough bleach and not enough distance between the walls to have the desired effect. Physically moving is quite often the only answer.

As we consider transhumanist societies, such transitional power is certainly the result by many magnitudes. My team has been engaged in developing the first permanent human undersea settlement over the past few decades. In this process we have had the distinct advantage of planning profoundly transhumanist advances specifically because of the advantageous context of relative community isolation. Further we have the benefit of deriving change as a community necessity — as a psychological and cultural imperative for this degree of advanced cultural evolution. It is a real kind of powerfully driven societal punctuated equilibrium that can be realized in few other ways.

In moving into the oceans, the submarine environment itself immediately establishes the boundary between the new, evolving culture and the old. While the effect and actual meaning of this boundary is almost always overrated, it is nonetheless a real boundary layer that allows the new culture to flourish sans the interferences or contamination from the old. Trying to accomplish transhumanist goals while culturally embedded is far more difficult and far less persuasive to those who must undergo dramatic change and for the transformation to actually take hold and survive generationally. But in a new, rather isolated environment, the pressure to evolve and integrate permanent change is not only easier, it is rather expected as a part of the reasonable process of establishment.

In one of our most powerful spin-offs back to the land-dwellers (LDs), our culture will begin on day one as a ‘waste-free culture’. It is an imperative and therefore a technological design feature. It is a value system. It is codified. It is a defining element of our new culture. It is also radically transhumanist. In our society, we teach this to one another and to our children, as well as every subsequent generation. In our undersea culture we have a process called ‘resource recovery’, since every product of every process is a resource to be utilized in the next round of community life cycle processing. Hence even the vilest sewage is just a part of the carbon cycle for the next round of our life support system engineering. Nothing is to be ‘wasted’. Nothing is to be ‘cast off’. We cannot afford ‘waste’ of any kind, hence waste will cease to exist as a concept. Everything is a resource. The life of the next cycle depends on the successful re-integration of each preceding cycle. The future life and wellbeing of the colony directly depends on the successful implementation of the conservation of resources and in turn the preservation of the natural health of its immediate environment in just this fashion.

Such advancement would be most difficult to engineer in a land-dweller community. The first problem would be simple re-education and the most elementary expectations. The next hurdle would be the re-engineering of every process that the LDs now identify as ‘waste processing’, ‘waste storage’, ‘waste distribution’ etc. Sadly, much of the LD’s unprocessed and unstabilized product is dumped into our ocean environment! But in the simple act of moving the same people to a new social structure, the impossible becomes surprisingly straightforward and even easy to implement. The difference and the power were always implicit in the move itself. The transhumanist ideal seems much better framed in this context when one considers that this is only one of countless examples of building new societies that are cleanly separated from the old.

It is certain to engender arguments to the contrary, I am sure. For how often is the rare opportunity available to move into a new cultural paradigm cleanly distinct from its predecessor? Certainly then the transhumanist concept must be able to rely on in situ prototypes that must be ultimately successful for the successful evolution of the culture. I have no argument with this, except to emphasize the intrinsic power in clean cultural separation as described in this example.

Obviously the ocean settlement is only one prototype. Space settlements and surface based seasteading are other examples to consider. The fact is clear, transhumanist cultures will always and quite easily develop in the new isolated human communities that are about to flourish in the most unexpected of places.

_________________________________________
Dennis Chamberland is the Expeditions Leader for the Atlantica Expeditions, where others may participate. Dennis is also a writer, the author of the book, Undersea Colonies and others, where many of these concepts are discussed in greater detail.

Medical science has changed humanity. It changed what it means to be human, what it means to live a human life. So many of us reading this (and at least one person writing it) owe their lives to medical advances, without which we would have died.

Live expectancy is now well over double what it was for the Medieval Briton, and knocking hard on triple’s door.

What for the future? Extreme life extension is no more inherently ridiculous than human flight or the ability to speak to a person on the other side of the world. Science isn’t magic – and ageing has proven to be a very knotty problem – but science has overcome knotty problems before.

A genuine way to eliminate or severely curtail the influence of ageing on the human body is not in any sense inherently ridiculous. It is, in practice, extremely difficult, but difficult has a tendency to fall before the march of progress. So let us consider what implications a true and seismic advance in this area would have on the nature of human life.

keep-calm-and-be-forever-young-138

One absolutely critical issue that would surround a breakthrough in this area is the cost. Not so much the cost of research, but the cost of application. Once discovered, is it expensive to do this, or is it cheap? Do you just have to do it once? Is it a cure, or a treatment?

If it can be produced cheaply, and if you only need to do it once, then you could foresee a future where humanity itself moves beyond the ageing process.

The first and most obvious problem that would arise from this is overpopulation. A woman has about 30–35 years of life where she is fertile, and can have children. What if that were extended to 70–100 years? 200 years?

Birth control would take on a vastly more important role than it does today. But then, we’re not just dropping this new discovery into a utopian, liberal future. We’re dropping it into the real world, and in the real world there are numerous places where birth control is culturally condemned. I was born in Ireland, a Catholic nation, where families of 10 siblings or more are not in any sense uncommon.

What of Catholic nations – including some staunchly conservative, and extremely large Catholic societies in Latin America – where birth control is seen as a sin?

Of course, the conservatism of these nations might (might) solve this problem before it arises – the idea of a semi-permanent extension of life might be credibly seen as a deeper and more blasphemous defiance of God than wearing a condom.

But here in the West, the idea that we are allowed to choose how many children we have is a liberty so fundamental that many would baulk to question it.

We may have to.

quizzical baby

There is another issue. What about the environmental impact? We’re already having a massive impact on the environment, and it’s not looking pretty. What if there were 10 times more of us? 100 times more? What about the energy consumption needs, in a world running out of petrol? The food needs? The living space? The household waste?

There are already vast flotillas of plastic waste the size of small nations that float across the surface of the Pacific. Carbon dioxide levels in the atmosphere have just topped 400 parts per million. We are pushing hard at the envelope of what the world of capable of sustaining, and a massive boost in population would only add to that ever-increasing pressure.

Of course, science might well sort out the answer to those things – but will it sort it out in time? The urgency of environmental science, and cultural change, suddenly takes on a whole new level of importance in the light of a seismic advance in addressing the problem of human ageing.

These are problems that would arise if the advance produced a cheap treatment that could (and would) be consumed by very large numbers of people.

But what if it wasn’t a cure? What if it wasn’t cheap? What if it was a treatment, and a very expensive one?

All of a sudden, we’re looking at a very different set of problems, and the biggest of all centres around something Charlie Chaplin said in the speech he gave at the end of his film, The Great Dictator. It is a speech from the heart, and a speech for the ages, given on the eve of mankind’s greatest cataclysm to date, World War 2.

In fact, you’d be doing yourself a favour if you watched the whole thing, it is an astounding speech.

chaplin great dictator

The quote is this:

“To those who can hear me, I say — do not despair.

The misery that is now upon us is but the passing of greed, the bitterness of men who fear the way of human progress. The hate of men will pass, and dictators die, and the power they took from the people will return to the people. And so long as men die, liberty will never perish.”

And so long as men die, liberty will never perish.

What if Stalin were immortal? And not just immortal, but immortally young?

Immortally vigourous, able to amplify the power of his cult of personality with his literal immortality.

This to me seems a threat of a very different kind, but of no less importance, than the dangers of overpopulation. That so long as men die, liberty will never perish. But what if men no longer die?

And of course, you could very easily say that those of us lucky enough to live in reasonably well-functioning democracies wouldn’t have to worry too much about this. It doesn’t matter if you live to be 1000, you’re still not getting more than 8 years of them in the White House.

But there is something in the West that would be radically changed in nature. Commercial empires.

What if Rupert Murdoch were immortal?

It doesn’t matter how expensive that treatment for ageing is. If it exists, he’d be able to afford it, and if he were able to buy it, he’d almost certainly do so.

If Fox News was run by an immortal business magnate, with several lifetimes worth of business experience and skill to know how to hold it all together, keep it going, keep it growing? What then?

Charles-Montgomery-Burns--007

Not perhaps the sunny utopia of a playground of immortals that we might hope for.

This is a different kind of issue. It’s not an external issue – the external impact of population on the environment, or the external need of a growing population to be fed. These problems might well sink us, but science has shown itself extremely adept at finding solutions to external problems.

What this is, is an internal problem. A problem of humanity. More specifically, the fact that extreme longevity would allow tyranny to achieve a level of entrenchment that it has so far never been capable of.

But then a law might be passed. Something similar to the USA’s 8 year term limit on Presidents. You can’t be a CEO for longer than 30 years, or 40 years, or 50. Something like that might help, might even become urgently necessary over time. Forced retirement for the eternally young.

Not an unproblematic idea, I’m sure you’ll agree. Quite the culture shock for Western societies loathe to accept government intervention in private affairs.

But it is a new category of problem. A classic problem of humanity, amplified by immortality. The centralisation of control, power and influence in a world where the people it centres upon cannot naturally die.

This, I would say, is the most obvious knotty problem that would arise, for humanity, in the event of an expensive, but effective, treatment for ageing.

But then, let’s just take a quick look back at the other side of the coin. Is there a problem inherent in humanity that would be amplified were ageing to be overcome, cheaply, worldwide?

Let me ask you a question.

Do people, generally speaking, become more open to new things, or less open to new things, as they age?

Do older people – just in general terms – embrace change or embrace stasis?

Well, it’s very obvious that some older people do remain young at heart. They remain passionate, humble in their beliefs, they are open to new things, and even embrace them. Some throw the influence and resources they have accrued throughout their lifetimes into this, and are instrumental to the march of progress.

More than this, they add a lifetime of skill, experience and finesse to their passion, a melding of realism and hope that is one of the most precious and potent cocktails that humanity is capable of mixing.

But we’re not talking about the few. We’re talking about the many.

Is it fair to say that most older people take this attitude to change? Or is it fairer to say that older people who retain that passion and spark, who not only have retained it, but have spent a lifetime fuelling it into a great blaze of ability and success – is it fair to say that these people are a minority?

I would say yes. They are incredibly precious, but part of that preciousness is the fact that they are not common.

Perhaps one day we will make our bodies forever young. But what of our spirit? What of our creativity?

I’m not talking about age-related illnesses like Parkinson’s, or Alzheimer’s disease. I’m talking about the creativity, passion and fire of youth.

The temptation of the ‘comfort zone’ for all human beings is a palpable one, and one that every person who lives well, who breaks the mold, who changes the future, must personally overcome.

Do the majority of people overcome it? I would argue no. And more than this, I would argue that living inside a static understanding of the world – even working to protect that understanding in the face of naked and extreme challenges from reality itself – is now, and has historically been, through all human history, the norm.

Those who break the mold, brave the approbation of the crowd, and look to the future with wonder and hope, have always been a minority.

mind closed till further notice

Now add in the factor of time. The retreat into the comforting, the static and the known has a very powerful pull on human beings. It is also not a binary process, but an analogue process – it’s not just a case of you do or you don’t. There are degrees of retreat, extremes of intellectual conservatism, just as there are extremes of intellectual curiosity, and progress.

But which extremes are the more common? This matters, because if all people could live to 200 years old or more, what would that mean for a demographic shift in cultural desire away from change and toward stasis?

A worrying thought. And it might seem that in the light of all this, we should not seek to open the Pandora’s box of eternal life, but should instead stand against such progress, because of the dangers it holds.

But, frankly, this is not an option.

The question is not whether or not human beings should seek to conquer death.

The question is whether or not conquering death is possible.

If it is possible, it will be done. If it is not, it will not be.

But the obvious problem of longevity – massive population expansion – is something that is, at least in principle, amenable to other solutions arising from science as it now practiced. Cultural change is often agonising, but it does happen, and scientific progress may indeed solve the issues of food supply and environmental impact. Perhaps not, but perhaps.

At the very least, these sciences take on a massively greater importance to the cohesion of the human future than they already have, and they are already very important indeed.

But there is another, deeper problem of a very different kind. The issue of the human spirit. If, over time, people (on average) become more calcified in their thinking, more conservative, less likely to take risks, or admit to new possibilities that endanger their understanding, then longevity, distributed across the world, can only lead to a culture where stasis is far more valued than change.

Pandora’s box is already open, and its name is science. Whether it is now, or a hundred years from now, if it is possible for human beings to be rendered immortal through science, someone is going to crack it.

We cannot flinch the future. It would be churlish and naive to assume that such a seemingly impossible vision will forever remain impossible. Not after the last century we just had, where technological change ushered in a new era, a new kind of era, where the impossibilities of the past fell like wheat beneath a scythe.

Scientific progress amplifies the horizon of possible scientific progress. And we stand now at a time when what it means to be a human – something which already undergone enormous change – may change further still, and in ways more profound than any of us can imagine.

If it can be done, it will be done. And so the only sane approach is to look with clarity at what we can see of what that might mean.

The external problems are known problems, and we may yet overcome them. Maybe. If there’s a lot of work, and a lot of people take a lot of issues a lot more seriously than they are already doing.

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But there is a different kind of issue. An issue extending from human nature itself. Can we overcome, as a people, as a species, our fear, and the things that send us scurrying back from curiosity and hope into the comforting arms of wilful ignorance, and static belief?

This, in my opinion, is the deepest problem of longevity. Who wants to live forever in a world where young bodies are filled with withered souls, beaten and embittered with the frustrations of age, but empowered to set the world in stone to justify them?

But perhaps it was always going to come to this. That at some point technological advancement would bring us to a kind of reckoning. A reckoning between the forces of human fear, and the value of human courage.

To solve the external problems of an eternal humanity, science must do what science has done so well for so long – to delve into the external, to open up new possibilities to feed the world, and balance human presence with the needs of the Earth.

But to solve the internal problems of an eternal humanity, science needs to go somewhere else. The stunning advances in the understanding of the external world must begin to be matched with new ways of charting the deeps of human nature. The path of courage, of open-mindedness, of humility, and a willingness to embrace change and leave behind the comforting arms of old static belief systems – this is not a path that many choose.

But many more must choose it in a world of immortal people, to counterbalance the conservatism of those who fail the test, and retreat, and live forever.

Einstein lived to a ripe old age, and never lost his wonder. Never lost his humility, or his courage to brave the approbation and ridicule of his peers in that task he set himself. To chart the deep simplicities of the real, and know the mind of God. The failure of the human spirit is not written in the stars, and never will be.

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We are none of us doomed to fail in matters of courage, curiosity, wonder or hope. But we are none of us guaranteed to succeed.

And as long as courage, hope and the ability to break new ground remain vague, hidden properties that we squeamishly refuse to interrogate, each new generation will have to start from scratch, and make their own choices.

And in a world of eternal humans, if any individual generation fails, the world will be counting that price for a very long time.

It is a common fear that if we begin to make serious headway into issues normally the domain of the spiritual, we will destroy the mystique of them, and therefore their preciousness.

Similar criticisms were, and sometimes still are, laid at the feet of Darwin’s work, and Galileo’s. But the fact is that an astronomer does not look to the sky with less wonder because of their deeper understanding, but more wonder.

Reality is both stunningly elegant, and infinitely beautiful, and in these things it is massively more amazing than the little tales of mystery humans have used to make sense of it since we came down from the trees.

In the face of a new future, where the consequences of human courage and human failure are amplified, the scientific conquest of death must be fused with another line of inquiry. The scientific pioneering of the fundamental dynamics of courage in living, and humility to the truth, over what we want to believe.

It will never be a common path, and no matter how clear it is made, or how wide it is opened, there will always be many who will never walk it.

But the wider it can be made, the clearer it can be made, the more credible it can be made as an option.

And we will need that option. We need it now.

And our need will only grow greater with time.

In an enormously influential article published in 1974 in Psychology Today, and in a longer version published later that year in BioScience, Garrett Hardin introduced the metaphor of the lifeboat for economic and ethical consideration. This conceptual construction was intended as an improvement over the then-popular ecological metaphor of “spaceship earth” coined by Kenneth Boulding in 1966. Interestingly, in the opening paragraph of “Living on a lifeboat”, Hardin indicates that metaphors in general may be understood as only an early stage in mentally approaching difficult problems, and that this stage may be surpassed as theory advances and becomes more rigorous.

In Hardin’s analogy, large entities such as nations or the biosphere are likened to a boat, while smaller entities – for example, migrating individuals or groups – are likened to swimmers trying to board the already cramped vessel and exploit whatever resources are on board. In the imagined scenario, it is believed that the boat is near carrying capacity, but exactly how near is not known with certainty given the many future possibilities. A central question focuses on at what point, if any, the risk of sinking the entire boat outweighs the good provided for each additional rescued swimmer.

The metaphor of the lifeboat has structured thought about conservation, economics, ethics, and any number of other disciplinary areas for decades. The question I would like to pose is the following: Is the lifeboat scenario still (or was it ever) an apt metaphor for structuring thought about ethical conservation of resources, or have we reached a stage where the boat should be scuttled in favor of either a new metaphor or more literal language? Please feel free to post any thoughts you may have on this issue.

1. Thou shalt first guard the Earth and preserve humanity.

Impact deflection and survival colonies hold the moral high ground above all other calls on public funds.

2. Thou shalt go into space with heavy lift rockets with hydrogen upper stages and not go extinct.

The human race can only go in one of two directions; space or extinction- right now we are an endangered species.

3. Thou shalt use the power of the atom to live on other worlds.

Nuclear energy is to the space age as steam was to the industrial revolution; chemical propulsion is useless for interplanetary travel and there is no solar energy in the outer solar system.

4. Thou shalt use nuclear weapons to travel through space.

Physical matter can barely contain chemical reactions; the only way to effectively harness nuclear energy to propel spaceships is to avoid containment problems completely- with bombs.

5. Thou shalt gather ice on the Moon as a shield and travel outbound.

The Moon has water for the minimum 14 foot thick radiation shield and is a safe place to light off a bomb propulsion system; it is the starting gate.

6. Thou shalt spin thy spaceships and rings and hollow spheres to create gravity and thrive.

Humankind requires Earth gravity and radiation to travel for years through space; anything less is a guarantee of failure.

7. Thou shalt harvest the Sun on the Moon and use the energy to power the Earth and propel spaceships with mighty beams.

8. Thou shalt freeze without damage the old and sick and revive them when a cure is found; only an indefinite lifespan will allow humankind to combine and survive. Only with this reprieve can we sleep and reach the stars.

9. Thou shalt build solar power stations in space hundreds of miles in diameter and with this power manufacture small black holes for starship engines.

10. Thou shalt build artificial intellects and with these beings escape the death of the universe and resurrect all who have died, joining all minds on a new plane.