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An obvious next step in the effort to dramatically lower the cost of access to low Earth orbit is to explore non-rocket options. A wide variety of ideas have been proposed, but it’s difficult to meaningfully compare them and to get a sense of what’s actually on the technology horizon. The best way to quantitatively assess these technologies is by using Technology Readiness Levels (TRLs). TRLs are used by NASA, the United States military, and many other agencies and companies worldwide. Typically there are nine levels, ranging from speculations on basic principles to full flight-tested status.

The system NASA uses can be summed up as follows:

TRL 1 Basic principles observed and reported
TRL 2 Technology concept and/or application formulated
TRL 3 Analytical and experimental critical function and/or characteristic proof-of concept
TRL 4 Component and/or breadboard validation in laboratory environment
TRL 5 Component and/or breadboard validation in relevant environment
TRL 6 System/subsystem model or prototype demonstration in a relevant environment (ground or space)
TRL 7 System prototype demonstration in a space environment
TRL 8 Actual system completed and “flight qualified” through test and demonstration (ground or space)
TRL 9 Actual system “flight proven” through successful mission operations.

Progress towards achieving a non-rocket space launch will be facilitated by popular understanding of each of these proposed technologies and their readiness level. This can serve to coordinate more work into those methods that are the most promising. I think it is important to distinguish between options with acceleration levels within the range human safety and those that would be useful only for cargo. Below I have listed some non-rocket space launch methods and my assessment of their technology readiness levels.

Spacegun: 6. The US Navy’s HARP Project launched a projectile to 180 km. With some level of rocket-powered assistance in reaching stable orbit, this method may be feasible for shipments of certain forms of freight.

Spaceplane: 6. Though a spaceplane prototype has been flown, this is not equivalent to an orbital flight. A spaceplane will need significantly more delta-v to reach orbit than a suborbital trajectory requires.

Orbital airship: 2. Though many subsystems have been flown, the problem of atmospheric drag on a full scale orbital airship appears to prevent this kind of architecture from reaching space.

Space Elevator: 3. The concept may be possible, albeit with major technological hurdles at the present time. A counterweight, such as an asteroid, needs to be positioned above geostationary orbit. The material of the elevator cable needs to have a very high tensile strength/mass ratio; no satisfactory material currently exists for this application. The problem of orbital collisions with the elevator has also not been resolved.

Electromagnetic catapult: 4. This structure could be built up the slope of a tall mountain to avoid much of the Earth’s atmosphere. Assuming a small amount of rocket power would be used after a vehicle exits the catapult, no insurmountable technological obstacles stand in the way of this method. The sheer scale of the project makes it difficult to develop the technology past level 4.

Are there any ideas we’re missing here?

Lee Smolin is said to believe (according to personal communication from Danila Medvedev who was told about it by John Smart. I tried to reach Smolin for comments, but failed) that global catastrophe is impossible, based on the following reasoning: the multiverse is dominated by those universes that are able to replicate. This Self-replication occurs in black holes, and in especially in those black holes, which are created civilizations. Thus, the parameters of the universe are selected so that civilization cannot self-destruct before they create black holes. As a result, all physical processes, in which civilization may self-destruct, are closed or highly unlikely. Early version of Smolin’s argument is here: http://en.wikipedia.org/wiki/Lee_Smolin but this early version was refuted in 2004, and so he (probably) added existence of civilization as another condition for cosmic natural selection. Anyway, even if it is not Smolin’s real line of thoughts, it is quite possible line of thoughts.

I think this argument is not persuasive, since the selection can operate both in the direction of universes with more viable civilizations, and in the direction of universes with a larger number of civilizations, just as biological evolution works to more robust offspring in some species (mammals) and in the larger number of offspring with lower viability (plants, for example, dandelion). Since some parameters for the development of civilizations is extremely difficult to adjust by the basic laws of nature (for example, the chances of nuclear war or a hostile AI), but it is easy to adjust the number of emerging civilizations, it seems to me that the universes, if they replicated with the help of civilizations, will use the strategy of dandelions, but not the strategy of mammals. So it will create many unstable civilization and we are most likely one of them (self indication assumption also help us to think so – see recent post of Katja Grace http://meteuphoric.wordpress.com/2010/03/23/sia-doomsday-the-filter-is-ahead/)

But still some pressure can exist for the preservation of civilization. Namely, if an atomic bomb would be as easy to create as a dynamite – much easier then on Earth (which depends on the quantity of uranium and its chemical and nuclear properties, ie, is determined by the original basic laws of the universe), then the chances of the average survival of civilization would be lower. If Smolin’s hypothesis is correct, then we should encounter insurmountable difficulties in creating nano-robots, microelectronics, needed for strong AI, harmful experiments on accelerators with strangelet (except those that lead to the creation of black holes and new universes), and in several other potentially dangerous technology trends that depend on their success from the basic properties of the universe, which may manifest itself in the peculiarities of its chemistry.

In addition, the evolution of universes by Smolin leads to the fact that civilization should create a black hole as early as possible in the course of its history, leading to replication of universes, because the later it happens, the greater the chances that the civilization will self-destruct before it can create black holes. In addition, the civilization is not required to survive after the moment of “replication” (though survival may be useful for the replication, if civilization creates a lot of black holes during its long existence.) From these two points, it follows that we may underestimate the risks from Hadron Collider in the creation of black holes.

I would repeat: early creation of a black hole suggested by Smolin and destroying the parent civilization, is very consistent with the situation with the Hadron Collider. Collider is a very early opportunity for us to create a black hole, as compared with another opportunity — to become a super-civilization and learn how to connect stars, so that they collapse into black holes. It will take millions of years and the chances to live up to this stage is much smaller. Also collider created black holes may be special, which is requirement for civilization driven replication of universes. However, the creation of black holes in collider with a high probability means the death of our civilization (but not necessarily: black hole could grow extremely slowly in the bowels of the Earth, for example, millions of years, and we have time to leave the Earth, and it depends on the unknown physical conditions.) In doing so, black hole must have some feature that distinguishes it from other holes that arise in our universe, for example, a powerful magnetic field (which exist in collider) or a unique initial mass (also exist in LHC: they will collide ions of gold).

So Smolin’s logic is sound but not proving that our civilization is safe, but in fact proving quiet opposite: that the chances of extinction in near future is high. We are not obliged to participate in the replication of universes suggested by Smolin, if it ever happens, especially if it is tantamount to the death of the parent civilization. If we continue our lives without black holes, it does not change the total number of universes have arisen, as it is infinite.

8th European conference on Computing And Philosophy — ECAP 2010
Technische Universität München
4–6 October 2010

Submission deadline of extended abstracts: 7 May 2010
Submission form

Theme

Historical analysis of a broad range of paradigm shifts in science, biology, history, technology, and in particular in computing technology, suggests an accelerating rate of evolution, however measured. John von Neumann projected that the consequence of this trend may be an “essential singularity in the history of the race beyond which human affairs as we know them could not continue”. This notion of singularity coincides in time and nature with Alan Turing (1950) and Stephen Hawking’s (1998) expectation of machines to exhibit intelligence on a par with to the average human no later than 2050. Irving John Good (1965) and Vernor Vinge (1993) expect the singularity to take the form of an ‘intelligence explosion’, a process in which intelligent machines design ever more intelligent machines. Transhumanists suggest a parallel or alternative, explosive process of improvements in human intelligence. And Alvin Toffler’s Third Wave (1980) forecasts “a collision point in human destiny” the scale of which, in the course of history, is on the par only with the agricultural revolution and the industrial revolution.

We invite submissions describing systematic attempts at understanding the likelihood and nature of these projections. In particular, we welcome papers critically analyzing the following issues from a philosophical, computational, mathematical, scientific and ethical standpoints:

  • Claims and evidence to acceleration
  • Technological predictions (critical analysis of past and future)
  • The nature of an intelligence explosion and its possible outcomes
  • The nature of the Technological Singularity and its outcome
  • Safe and unsafe artificial general intelligence and preventative measures
  • Technological forecasts of computing phenomena and their projected impact
  • Beyond the ‘event horizon’ of the Technological Singularity
  • The prospects of transhuman breakthroughs and likely timeframes

Amnon H. Eden, School of Computer Science & Electronic Engineering, University of Essex, UK and Center For Inquiry, Amherst NY

Experts regard safety report on Big Bang Machine as insufficient and one-dimensional

International critics of the high energy experiments planned to start soon at the particle accelerator LHC at CERN in Geneva have submitted a request to the Ministers of Science of the CERN member states and to the delegates to the CERN Council, the supreme controlling body of CERN.

The paper states that several risk scenarios (that have to be described as global or existential risks) cannot currently be excluded. Under present conditions, the critics have to speak out against an operation of the LHC.

The submission includes assessments from expertises in the fields markedly missing from the physicist-only LSAG safety report — those of risk assessment, law, ethics and statistics. Further weight is added because these experts are all university-level experts – from Griffith University, the University of North Dakota and Oxford University respectively. In particular, it is criticised that CERN’s official safety report lacks independence – all its authors have a prior interest in the LHC running and that the report uses physicist-only authors, when modern risk-assessment guidelines recommend risk experts and ethicists as well.

As a precondition of safety, the request calls for a neutral and multi-disciplinary risk assessment and additional astrophysical experiments – Earth based and in the atmosphere – for a better empirical verification of the alleged comparability of particle collisions under the extreme artificial conditions of the LHC experiment and relatively rare natural high energy particle collisions: “Far from copying nature, the LHC focuses on rare and extreme events in a physical set up which has never occurred before in the history of the planet. Nature does not set up LHC experiments.”

Even under greatly improved circumstances concerning safety as proposed above, big jumps in energy increase, as presently planned by a factor of three compared to present records, without carefully analyzing previous results before each increase of energy, should principally be avoided.

The concise “Request to CERN Council and Member States on LHC Risks” (Pdf with hyperlinks to the described studies) by several critical groups, supported by well known critics of the planned experiments:

http://lhc-concern.info/wp-content/uploads/2010/03/request-to-cern-council-and-member-states-on-lhc-risks_lhc-kritik-et-al_march-17-2010.pdf

The answer received by now does not consider these arguments and studies but only repeats again that from the side of the operators everything appears sufficient, agreed by a Nobel Price winner in physics. LHC restart and record collisions by factor 3 are presently scheduled for March 30, 2010.

Official detailed and well understandable paper and communication with many scientific sources by ‘ConCERNed International’ and ‘LHC Kritik’:

http://lhc-concern.info/wp-content/uploads/2010/03/critical-revision-of-lhc-risks_concerned-int.pdf

More info:
http://lhc-concern.info/

A few months ago, my friend Benjamin Jakobus and I created an online “risk intelligence” test at http://www.projectionpoint.com/. It consists of fifty statements about science, history, geography, and so on, and your task is to say how likely you think it is that each of these statements is true. We calculate your risk intelligence quotient (RQ) on the basis of your estimates. So far, over 30,000 people have taken our test, and we’re currently writing up the results for some peer-reviewed journals.

Now we want to take things a step further, and see whether our measure correlates with the ability to make accurate estimates of future events. To this end we’ve created a “prediction game” at http://www.projectionpoint.com/prediction_game.php. The basic idea is the same; we provide you with a bunch of statements, and your task is to say how likely you think it is that each one is true. The difference is that these statements refer not to known facts, but to future events. Unlike the first test, nobody knows whether these statements are true or false yet. For most of them, we won’t know until the end of the year 2010.

For example, how likely do you think it is that this year will be the hottest on record? If you think this is very unlikely you might select the 10% category. If you think it is quite likely, but not very likely, you might put the chances at 60% or 70%. Selecting the 50% category would mean that you had no idea how likely it is.

This is ongoing research, so please feel free to comment, criticise or make suggestions.

Another risk is loss of human rationality, while preserving human life. In a society there are always so many people with limited cognitive abilities, and most of the achievements are made by a small number of talented people. Genetic and social degradation, reducing the level of education, loss of skills of logic can lead to a temporary decrease in intelligence of individual groups of people. But as long as humanity is very large in population, it is not so bad, because there will always be enough intelligent people. Significant drop in population after nonglobal disaster may exacerbate this problem. And the low intelligence of the remaining people will reduce their chances of survival. Of course, one can imagine such an absurd situation that people are so degraded that by the evolutionary path new species arise from us, which is not having a full-fledged intelligence — and that back then this kind of evolving reasonable, developed a new intelligence.
More dangerous is decline of intelligence because of the spread of technological contaminants (or use of a certain weapon). For example, I should mention constantly growing global arsenic contamination, which is used in various technological processes. Sergio Dani wrote about this in his article “Gold, coal and oil.” http://sosarsenic.blogspot.com/2009/11/gold-coal-and-oil-regulatory-crisis-of.html, http://www.medical-hypotheses.com/article/S0306-9877 (09) 00666-5/abstract
Disengaged during the extraction of gold mines in the arsenic remains in the biosphere for millennia. Dani binds arsenic with Alzheimer’s disease. In his another paper is demonstrated that increasing concentrations of arsenic leads to an exponential increase in incidence of Alzheimer’s disease. He believes that people are particularly vulnerable to arsenic poisoning, as they have large brains and longevity. If, however, according to Denis, in the course of evolution, people will adapt to high levels of arsenic, it will lead to a decline in the brain and life expectancy, resulting in the intellect of people will be lost.
In addition to arsenic contamination occurs among many other neurotoxic substances — CO, CO2, methane, benzene, dioxin, mercury, lead, etc. Although the level of pollution by each of them separately is below health standards, the sum of the impacts may be larger. One reason for the fall of the Roman Empire was called the total poisoning of its citizens (though not barbarians) of lead from water pipes. Of course, they could not have knowledge about these remote and unforeseen consequences — but we also may not know about the many consequences of our affairs.
In addition to dementia is alcohol and most drugs, many drugs (eg, side effect in the accompanying sheets of mixtures of heartburn called dementia). Also rigid ideological system, or memes.
Number of infections, particularly prion, also leads to dementia.
Despite this, the average IQ of people is growing as life expectancy.

AI is our best hope for long term survival. If we fail to create it, it will happened by some reason. Here I suggest the complete list of possible causes of failure, but I do not believe in them. (I was inspired bu V.Vinge artile “What if singularity does not happen”?)

I think most of these points are wrong and AI finaly will be created.

Technical reasons:
1) Moore’s Law will stop by physical causes earlier than would be established sufficiently powerful and inexpensive apparatus for artificial intelligence.
2) Silicon processors are less efficient than neurons to create artificial intelligence.
3) Solution of the AI cannot be algorithmically parallelization and as a result of the AI will be extremely slow.

Philosophy:
4) Human beings use some method of processing information, essentially inaccessible to algorithmic computers. So Penrose believes. (But we can use this method using bioengineering techniques.) Generally, the final recognition of the impossibility of creating artificial intelligence would be tantamount to recognizing the existence of the soul.
5) The system cannot create a system more complex then themselves, and so the people cannot create artificial intelligence, since all the proposed solutions are too simple. That is, AI is in principle possible, but people are too stupid to do it. In fact, one reason for past failures in the creation of artificial intelligence is that people underestimate the complexity of the problem.
6) AI is impossible, because any sufficiently complex system reveals the meaninglessness of existence and stops.
7) All possible ways to optimize are exhausted.AI does not have any fundamental advantage in comparison with the human-machine interface and has a limited scope of use.
8. The man in the body has a maximum level of common sense, and any incorporeal AIs are or ineffective, or are the models of people.
9) AI is created, but has no problems, which he could and should be addressed. All the problems have been solved by conventional methods, or proven uncomputable.
10) AI is created, but not capable of recursive self-optimization, since this would require some radically new ideas, but they had not. As a result, AI is there, or as a curiosity, or as a limited specific applications, such as automatic drivers.
11) The idea of artificial intelligence is flawed, because it has no precise definition or even it is an oxymoron, like “artificial natural.” As a result, developing specific goals or to create models of man, but not universal artificial intelligence.
12) There is an upper limit of the complexity of systems for which they have become chaotic and unstable, and it slightly exceeds the intellect of the most intelligent people. AI is slowly coming to this threshold of complexity.
13) The bearer of intelligence is Qualia. For our level of intelligence should be a lot events that are indescribable and not knowable, but superintellect should understand them, by definition, otherwise it is not superintellect, but simply a quick intellect.

Economic:
14) The growth of computer programs has led to an increase in the number of failures that were so spectacular that of automation software had to be abandoned. This led to a drop in demand for powerful computers and stop Moore’s Law, before it reached its physical limits. The same increase in complexity and number of failures made it difficult the creation of AI.
15) AI is possible, but it does not give a significant advantage over the man in any sense of the results, nor speed, nor the cost of computing. For example, a simulation of human worth one billion dollars, and she has no idea how a to self-optimize. But people found ways to break up their intellectual abilities by injecting the stem cell precursors of neurons, which further increases the competitive advantage of people.
16) No person engaged in the development of AI, because it is considered that this is impossible. It turns out self-fulfilling prophecy. AI is engaged only by fricks, who do not have enough of their own intellect and money. But the scale of the Manhattan Project could solve the problem of AI, but just no one is taking.
17) Technology of uploading consciousness into a computer has so developed, that this is enough for all practical purposes, have been associated with AI, and therefore there is no need to create an algorithmic AI. This upload is done mechanically, through scanning, and still no one understands what happens in the brain.

Political:
18) AI systems are prohibited or severely restricted for ethical reasons, so that people still feel themselves above all. Perhaps are allowed specialized AI systems in military and aerospace.
19) AI is prohibited for safety reasons, as it represents too great global risk.
20) AI emerged and established his authority over the Earth, but does not show itself, except it does not allow others to develop their own AI projects.
21) AI did not appear as was is imagined, and therefore no one call it AI (eg, the distributed intelligence of social networks).

I recently watched James Cameron’s Avatar in 3D. It was an enjoyable experience in some ways, but overall I left dismayed on a number of levels.

It was enjoyable to watch the lush three-dimensional animation and motion capture controlled graphics. I’m not sure that 3D will take over – as many now expect – until we get rid of the glasses (and there are emerging technologies to do that albeit, the 3D effect is not yet quite as good), but it was visually pleasing.

While I’m being positive, I was pleased to see Cameron’s positive view of science in that the scientists are “good” guys (or at least one good gal) with noble intentions on learning the wisdom of the Na’vi natives and on negotiating a diplomatic solution.

The Na’vi were not completely technology-free. They basically used the type of technology that Native Americans used hundreds of years ago – same clothing, domesticated animals, natural medicine, and bows and arrows.

They were in fact exactly like Native Americans. How likely is that? Life on this distant moon in another star system has evolved creatures that look essentially the same as earthly creatures, with very minor differences (dogs, horses, birds, rhinoceros-like animals, and so on), not to mention humanoids that are virtually the same as humans here on Earth. That’s quite a coincidence.

Cameron’s conception of technology a hundred years from now was incredibly unimaginative, even by Hollywood standards. For example, the munitions that were supposed to blow up the tree of life looked like they were used in World War II (maybe even World War I). Most of the technology looked primitive, even by today’s standards. The wearable exoskeleton robotic devices were supposed to be futuristic, but these already exist, and are beginning to be deployed. The one advanced technology was the avatar technology itself. But in that sense, Avatar is like the world of the movie AI, where they had human-level cyborgs, but nothing else had changed: AI featured 1980’s cars and coffee makers. As for Avatar, are people still going to use computer screens in a hundred years? Are they going to drive vehicles?

I thought the story and script was unimaginative, one-dimensional, and derivative. The basic theme was “evil corporation rapes noble natives.” And while that is a valid theme, it was done without the least bit of subtlety, complexity, or human ambiguity. The basic story was taken right from Dances with Wolves. And how many (thousands of) times have we seen a final battle scene that comes down to a battle between the hero and the anti-hero that goes through various incredible stages — fighting on a flying airplane, in the trees, on the ground, etc? And (spoiler alert) how predictable was it that the heroine would pull herself free at the last second and save the day?

None of the creatures were especially creative. The flying battles were like Harry Potter’s Quidditch, and the flying birds were derivative of Potter creatures, including mastering flying on the back of big bird creatures. There was some concept of networked intelligence but it was not especially coherent. The philosophy was the basic Hollywood religion about the noble cycle of life.

The movie was fundamentally anti-technology. Yes, it is true, as I pointed out above, that the natives use tools, but these are not the tools we associate with modern technology. And it is true that the Sigourney Weaver character and her band of scientists intend to help the Na’vi with their human technology (much like international aid workers might do today in developing nations), but we never actually see that happen. I got the sense that Cameron was loath to show modern technology doing anything useful. So even when Weaver’s scientist becomes ill, the Na’vi attempt to heal her only with the magical life force of the tree of life.

In Cameron’s world, Nature is always wise and noble, which indeed it can be, but he fails to show its brutal side. The only thing that was brutal, crude, and immoral in the movie was the “advanced” technology. Of course, one could say that it was the user of the technology that was immoral (the evil corporation), but that is the only role for technology in the world of Avatar.

In addition to being evil, the technology of the Avatar world of over 100 years from now is also weaker than nature, so the rhinoceros-like creatures are able to defeat the tanks circa 2100. It was perhaps a satisfying spectacle to watch, but how realistic is that? The movie shows the natural creatures communicating with each other with some kind of inter-species messaging and also showed the tree of life able to remember voices. But it is actually real-world technology that can do those things right now. In the Luddite world of this movie, the natural world should and does conquer the brutish world of technology.

In my view, there is indeed a crudeness to first-industrial-revolution technology. The technology that will emerge in the decades ahead will be altogether different. It will enhance the natural world while it transcends its limitations. Indeed, it is only through the powers of exponentially growing info, bio, and nano technologies that we will be able to overcome the problems created by first-industrial-revolution technologies such as fossil fuels. This idea of technology transcending natural limitations was entirely lost in Cameron’s vision. Technology was just something crude and immoral, something to be overcome, something that Nature does succeed in overcoming.

It was visually pleasing; although even here I thought it could have been better. Some of the movement of the blue natives was not quite right and looked like the unrealistic movement one sees of characters in video games, with jumps that show poor modeling of gravity.

The ending (spoiler alert) was a complete throwaway. The Na’vi defeat the immoral machines and their masters in a big battle, but if this mineral the evil corporation was mining is indeed worth a fortune per ounce, they would presumably come back with a more capable commander. Yet we hear Jake’s voice at the end saying that the mineral is no longer needed. If that’s true, then what was the point of the entire battle?

The Na’vi are presented as the ideal society, but consider how they treat their women. The men get to “pick” their women, and Jake is offered to take his choice once he earns his place in the society. Jake makes the heroine his wife, knowing full well that his life as a Na’vi could be cut off at any moment. And what kind of child would they have? Well, perhaps these complications are too subtle for the simplistic Avatar plot.

Danila Medvedev asked me to make a list of actual projects that can reduce the likelihood of global catastrophe.

EDITED: This list reflects only my personal opinion and not opinion of LF. Suggeted ideas are not final but futher discussion on them is needed. And these ideas are mutual independed.

1. Create the book “Guide to the restoration of civilization”, which describe all the necessary knowledge of hunting, industry, mining, and all the warnings about the risks for the case of civilization collapse.Test its different sections on volunteers. Print the book in stone / metal / other solid media in many copies throughout the world. Bury treasure with the tools / books / seeds in different parts of the world. 1–100 million USD. Reduction of probability of extinction (assuming that real prior probability is 50% in XXI century): 0.1%.
2. Collect money for the work of Singularity Institute in creating a Friendly AI. They need 3 million dollars. This project has a maximum ratio of the cost-impact. That is, it can really increase the chances of survival of humanity at about 1 percent. (This is determined by the product of estimates of the probabilities of events — the possibility of AI, what SIAI will solve this problem, the fact that it chooses the problem first, and that it solves the problem of friendliness, and the fact that the money they have will be enough.)
3. Krisave in the ice of Antarctica (the temperature of −57 C, in addition, you can create a stable region of lower temperature by use of liquid nitrogen which would be pumped and cooled it) a few people, so that if on earth there another advanced civilization, it could revive them. cost is several million dollars. Another project on the preservation of human knowledge in the spirit of the proposed fund by LongNow titanium discs with recorded information.
4. Send human DNA on the moon in the stable time capsule. Several tens of millions of dollars. You can also send the criopreserved human brain. The idea here is that if mankind would perish, then someday the aliens arrive and revive people based on these data. Expenses is 20–50 million dollars, the probability of success of 0.001%. Send human DNA in space in other ways.
5. Accelerated development of universal vaccines. Creation of the world’s reserves of powerful means of decontamination in the event of a global epidemic, the stockpiling antvirus drugs and vaccines to the majority of known viruses, which would be enough for a large part of humanity. Establishment of virus monitoring and instant diagnosis (test strips). Creation and production of many billions of pieces of advanced disinfecting tools such as personal UV lamps, nanotech dressing for the face, gloves, etc. The billions or hundreds of billions of dollars a year. Creating personal stockpiles of food and water at each house for a month. Development of supply system with no contact of people with one another. Jump to slow global transport (ships) in the event of a pandemic. Training of medical personnel and the creation of spare beds in hospitals. Creating and testing on real problems huge factories, which in a few weeks can develop and produce billions of doses of vaccines. Improvement of legislation in the field of quarantine. There are also risks. Increase the probability of survival 2–3 percent.
6. Creating a self-contained bunker with a supply of food for several decades and with the constant “crews”, able to restore humanity. About $ 1 billion. Save those types of resources that humanity could use the post-apocalyptic stage for recovery.
7. The creation of scientific court for Hadron Collider and other potentially dangerous projects, in which the theoretical physicist will be paid large sums of money for the discovery of potential vulnerabilities.
8. Adaptation of the ISS function for bunker in case of disasters on Earth — the creation of the ISS series of additional modules, which may support the existence of the crew for 10 years. Cost is tens of billions of dollars.
9. Creation of an autonomous self-sustaining base on the Moon. At the present level of technology — about $ 1 trillion or more. Proper development of strategy of space exploration would cheapen it — that is, investments in new types of engines and cheap means of delivery. Increase survival by 1 percent. (But there are also new risks).
10. The same is true on Mars. Several trillion. Increase survival of 1–2 per cent.
11. Creating star nuclear Ark ship- — tens of trillions of dollars. Increase survival of 1–2 per cent.
12. (The following are items for which are not enough money, but political will is also needed.) Destruction of rogue states and the establishment of a world state. 10 percent increase in survival. However, the high risks in the process.
13. Creating a global center for rapid response to global risks. Something like Special Forces or the Ministry of Emergency Situations, which can throw on the global risks. Enable it to instant action, including the hostilities, as well as intelligence. Giving its veto on the dangerous experiments. Strengthening of civil defense in the field.
14. The ban on private science (in the sense in the garage) and the creation of several centers of certified science (science town with centralized control of security in the process) with a high level of funding of breakthrough research. In the field of biotechnology, nuclear technology, artificial intelligence and nano. This will help prevent the dissemination of knowledge of mass destruction, but it will not stop progress. It is only after the abolition of nation states. A few percent increase in survival. These science towns can freely exchange technical information between themselves, but do not have the right to release it into the outside world.
15. The legislation required the duplication of a vital resource and activities — which would make impossible the collapse of civilization in a domino effect on failure at one point. The ban on super complex system of social organization, whose behavior is unpredictable and too prone to a domino effect, and replace them on the linear repetitive production system — that is, opposition to economic globalization.
16. Certification and licensing researchers in bio, nano, AI and nuclear technologies. Legislative requirement to check all their own and others’ inventions for the global risks associated with them, and the commitment to develop both a means of protection in the event of their inventions go out of control.
17. Law on raising intelligence of people half the population of fertilization from a few hundred of the best fathers in terms of intelligence and common sense and dislike of the risks. (Second half of the breed in the usual manner to maintain genetic diversity, the project is implemented without violence due to cash payments.) Plus education reform, where the school is replaced by a system of training, which given the important role of good sense and knowledge of logic.
18. Limitation of capitalist competition as the engine of the economy, because it leads to an underestimation of risk in the long term.
19. Leading investment in the field like nanotechnology breakthrough in the best and most critical facilities, to quickly slip dangerous period.
20. The growth of systems of information control and surveillance of the total, plus the certification data in them, and pattern recognition. Control of the Internet and the personal authorization for network logons. Continuous monitoring of all persons who possess potentially dangerous knowledge.
This could be creating a global think tank from the best experts on global risks and the formulation of their objectives to develop a positive scenario. Thus it is necessary to understand which way to combine these specialists would be most effective, so A) they do not eat each other because of different ideas and feelings of their own importance. B) that it does not become money feedbox. B) but that they received money for it, which would allow them to concentrate fully on this issue. That is, it should be something like edited journal, wiki, scientific trial or predictions market. But the way of association should not be too exotic, as well as exotic ways should be tested on less important matters.
However, the creation of accurate and credible for all models of the global risk would reduce by at least twice the probability of global catastrophe. And we are still at the stage of creating such a model. Therefore, how to create models and ways of authentication are now the most important, though, may have already been lost.
I emphasize that the main problems of global risks lies within the scope of knowledge, rather than to the sphere of action. That is the main problem that we do not know where we should prepare, not that we do not have instrument of defence. Risks are removed by the knowledge and expertise.
Implementation of these measures is technically and economically possible and could reduce the chance of extinction in the XXI century, in my estimation, 10 times.

Any ideas or missed projects?

Because of the election cycle, the United States Congress and Presidency has a tendency to be short-sighted. Therefore it is a welcome relief when an organization such as the U.S. National Intelligence Council gathers many smart people from around the world to do some serious thinking more than a decade into the future. But while the authors of the NIC report Global Trends 2025: A Transformed World[1] understood the political situations of countries around the world extremely well, their report lacked two things:

1. Sufficient knowledge about technology (especially productive nanosystems) and their second order effects.

2. A clear and specific understanding of Islam and the fundamental cause of its problems. More generally, an understanding of the relationship between its theology, technological progress, and cultural success.
These two gaps need to be filled, and this white paper attempts to do so.

Technology
Christine Peterson, the co-founder and vice-president of the Foresight Nanotech Institute, has said “If you’re looking ahead long-term, and what you see looks like science fiction, it might be wrong. But if it doesn’t look like science fiction, it’s definitely wrong.” None of Global Trends 2025 predictions look like science fiction, though perhaps 15 years from now is not long-term (on the other hand, 15 years is not short-term either).

The authors of Global Trends 2025 are wise in the same way that Socrates was wise: They admit to possibly not knowing enough about technology: “Many stress the role of technology in bringing about radical change and there is no question it has been a major driver. We—as others—have oftentimes underestimated its impact. (p. 5).”

Predicting the development and total impact of technology more than a few years into the future is exceedingly difficult. For example, of all the science fiction writers who correctly predicted a landing on the Moon, only one obscure writer predicted that it would be televised world-wide. Nobody would have believed, much less predicted, that we wouldn’t return for more than 40 years (and counting).

Other than orbital mechanics and demographics, there has been nothing more certain in the past two centuries than technological progress.[2] So it is perplexing that the report claims (correctly) that “[t]he pace of technology will be key [in providing solutions to energy, food, and water constraints],” (p. iv) but it then does not adequately examine the solutions pouring out of labs all over the world. To the authors’ credit, they foresaw that nanofibers and nanoparticles will increase the supply of clean water. In addition, they foresaw that nuclear bombs and bioweapons will become easier to manufacture. However, the static nanostructures they briefly discuss are only the first of four phases of nanotechnology maturation—they will be followed by active nanodevices, then nanomachines, and finally productive nanosystems. Ignoring this maturation of nanotechnology will lead to significant under-estimates of future capabilities.

If the pace of technological development is key, then on what factors does it depend?

The value of history is that it helps us predict the future. We should therefore consider the following questions while looking backwards as far as we wish to look forward:

Where were thumb drives 15 years ago? My twenty dollar 8GB thumb drive would have cost $20,000 and certainly wouldn’t have fit on my keychain. How powerful will my cell phone be 15 years from now? What are the secondary impacts of throwaway supercomputers?
In 1995 the Internet had six million hosts. There are now over 567 million hosts and 1.4 billion users. At this linear rate, in 15 years there will be a trillion users, most of them automated machines, and many of them mobile.
In 1995 there were over 10 million cell phone users in the USA; now there are around 250 million. Globally, the explosion was significantly larger, with over 2.4 billion current cell phone users. What will the effect be of a continuation of smart, mobile interconnectedness?
The World Wide Web was born in 1993 with the release of the Mosaic browser. Where was Google in 1995? Three years in the future. What else can we have besides the world’s information at our fingertips?
The problem with using recent history to guide predictions about the future is that the pace of technological development is not linear but exponential—and exponential growth is often surprising: recall the pedagogical examples of the doubling grains of rice (from India[3] and China[4]) or lily pads on the pond (from France[5]). In exponential growth, the early portion of the curve is fairly flat, while the latter portion is very steep.

Therefore, to predict technological development accurately, we should probably look back more than 15 years; perhaps we should be looking back 150 years. Exactly how far we should look back farther is difficult to determine—some metrics have not changed at all despite technological advances. For example, the speed limit is still 65 MPH, and there are no flying cars commercially available. On the other hand, cross-country airline flights are still the same price they were thirty years ago, despite inflation. Moore’s Law of electronics has had a doubling time of about 18 months, but some technologies have grown much slower. Others, such as molecular biology, have progressed significantly faster.

More important would be qualitative changes that are difficult to quantify. For example, the audio communication of telephones has a measurable bit rate greater than that of the telegraph system, but the increased level of understanding communicated by the emotion in people’s voices is much greater than can be quantified by bit rate. Similarly, search engines have qualitatively increased the value of the Internet’s TC/IP data communication capabilities. Some innovators have pushed Web 2.0 in different directions, but it’s not clear what the qualitative benefits might be, other than better-defined relationships between pieces of data. What happens with Web 3.0? Cloud computing? How many generations of innovation will it take to get to wisdom, or distributed sentience? It may be interesting to speculate about these matters, but since it often involves new science (or even new metaphysics), it is not possible to predict events with any accuracy.

Inventor and author Ray Kurzweil has made a living out of correctly timing his inventions. Among other things, he correctly predicted the growth of the Internet when it was still in its infancy. His method is simple: he plots data on a logarithmic graph, and if he gets a straight line, then he has discovered something that grows exponentially. His critics claim that his data is cherry-picked, but there are too many examples in a wide variety of technologies. The important point is why Kurzweil’s “law of accelerated returns” works, and what its limitations are: it applies to technologies for which information is an essential component. This phenomenon, made possible because information does not follow many of the rules of physics (i.e. lack of mass, negligible energy and copying costs, etc.) partially explains Moore’s Law in electronics, and also the exponential progress in molecular biology that began to occur once we understood enough of its informational basis.

Technology Breakthroughs
The “Technology Breakthroughs by 2025″ foldout matrix in the NIC report (pp. 47–49) is a great start on addressing the impact of technology, but barely a start. It is woefully conservative–some of the items listed in the report have already been proven in labs. For example, “Energy Storage” (in terms of batteries) has already been improved by ten-fold[6] (Caveat: the authors correctly point out that there is a delay between invention and wide adoption; usually about a decade for non-information based product—but 2019 is still considerably before 2025.) Hardly any other nanotech-enhanced products were examined, and they should have been.[7]

The ten specific technologies represented, and their drivers, barriers, and impact were well considered, but there were no clear criteria for picking these ten technologies. The report should have made clear that the most important technologies are those that can destroy or reboot the world’s economy or ecosystem. Almost as important are technologies that have profound effects on government, education, transportation, and family life. Past examples of such technologies include the nuclear bomb, the automobile, the telephone, the birth control pill, the personal computer, the internet, and search engines.

Though there were no clear criteria for choosing critical technology; however the report correctly included the world-changing technologies of ubiquitous computing, clean water, energy storage, biogerontechnology (life extension/age amelioration), and service robotics.

The inclusion of clean coal and biofuels is understandable given a linear projection of current trends. However, trends are not always linear—especially in information-dependent fields. Coal-based energy generation is dependent on the well-understood Carnot cycle, and is currently close to the theoretical maximum. Therefore, new knowledge about coal or the Carnot cycle will not help us in any significant way—especially since no new coal is being made. In contrast, photovoltaic solar power is currently expensive, inefficient, and underused. This is partially because of our lack of detailed understanding of the physics of photon capture and electron transfer, and partially because of our current inability to control the nanostructures that can perform those operations. As we develop more powerful scientific tools at the nanoscale, and as our nanomanufacturing capabilities grows, the price of solar power will drop significantly. This is why global solar power has resulted in exponential growth (with a two-year doubling time) for the past decade or so. This also means that in the next five years, we will likely reach a point at which it will be obvious that no other energy source can match photovoltaic solar power.

It is puzzling why exoskeleton human strength augmentation made the report’s list. First, we already commercialized compact fork-lifts and powered wheelchairs, so further improvements (in the form of exoskeletons) will necessarily be incremental and therefore will have little impact. Second, an exoskeleton is simply a sophisticated fork-lift/wheelchair and not true human strength augmentation, so it will not elicit the revulsion that might be generated by injecting extra IGF-1 genes or implanting electro-bionic actuators.

While being smarter is certainly a desirable condition, many forms of human cognitive augmentation elicit fear and loathing in many people (as the report recognizes). In terms of potential game-changing potential, it certainly deserves to be included as a disruptive technology. But this is a prediction of new science, not new engineering, and as such, should be labeled as “barely plausible.” If human cognitive augmentation is included, so should other, very high impact but very highly unlikely scenarios such as “gray goo” (i.e. out-of-control self-replicating nanobots), alien invasion, and human-directed meteor strikes.

What should have made the list are many forms of productive nanosystems, especially DNA Origami,[8] Bis-proteins,[9] Patterned Atomic Layer Epitaxy,[10] and Diamondoid Mechanosynthesis.[11],[12],[13]. Other technologies that should have been on the list include replicating 3D printers (such as Rep-Rap[14]), the weather machine,[15] Solar Power Satellites (which DoD is currently investigating[16]), Utility Fog,[17] and the Space Pier.[18]

Technologically Sophisticated Terrorism
The report correctly notes that the diffusion of technologies and scientific knowledge will increase the chance that terrorist or other malevolent groups might acquire and employ biological agents or nuclear devices (p. ix). But this danger is seriously underestimated, given the exponential growth of technology. Also underestimated is the future ability to clean up hazardous wastes of all types (including actinides, most notably uranium and plutonium) using nanomembranes and highly selective adsorbents. This is significant, especially in the case of Self-Assembled Monolayers on Mesoporous Supports (SAMMS) developed at Pacific Northwest National Labs,[19] because anything that can remove parts per billion concentrations of plutonium and uranium from water can also concentrate it. As the price drops for this filtration technology, and for nuclear enrichment tools,[20],[21] eventually small groups and even individuals will be able to collect enough fissile material for nuclear weapons.

The partial good news is that while these concentrating technologies are being developed, medical technology will also be progressing, making severe radiation exposure significantly more survivable. Unfortunately, the end result is an increasing likelihood that nuclear weapons will be used as “ordinary” tactical weapons.

The Distribution of Technology
While it is true that in the energy sector it has taken “an average of 25 years for a new production technology to become widespread,” (p. viii) there are a few things to keep in mind:

Informational technologies spread much faster than non-informational technologies. The explosion of the internet, web browsers, and the companies that depend on them have occurred in just a few years, if not months. Even now, for example, updates for the Firefox Mozilla browser are spread worldwide in days. This increase in distribution will occur because productive nanosystems will make atoms as easy to manipulate as bits.

Reducing monopolies and their attended inefficiencies is necessary. Even sufficiently powerful technologies have trouble emerging in the face of monopolies. The report mentions “selling energy back to the grid,” but understates the value that such a distributed energy network would have on increasing our nation’s security. The best part about building such a robust energy system is that it does not require large amounts of government investment — only the placement of an innovation-friendly policy that mandates that utilities buy energy at fair rates.

Mandating Gasoline/Ethanol/Methanol-flexibility (GEM) and/or electric hybrid flexibility in automobiles could break the oil cartel.[22] This simple governmental mandate would have huge political implications with little cost impact on consumers (a GEM requirement would only raise the cost of cars by $100-$300).

Miscellaneous Technology Observations
The 2025 report states that “Unprecedented economic growth, coupled with 1.5 billion more people, will put pressure on resources—particularly energy, food, and water—raising the specter of scarcities emerging as demand outstrips supply (p. iv).”

This claim is not necessarily true. The carrying capacity of an arbitrary volume of biome is dependent on technology—increased wealth can pay for advanced technologies. However, war, injustice, and ignorance drastically raise the effort required to avoid scarcities.

The report listed climate change as a possible key factor (p. v) and stated that “Climate change is expected to exacerbate resource scarcities” (p. viii). But even the most pessimistic predictions don’t expect much to happen by 2025. And there is evidence that by 2025, we will almost certainly have the power to stop it with trivial effort.[23], [24]

The Foresight Nanotech Institute and Lux Research have also identified clean water as being one of the areas in which technology will have a major impact. There are a number of different nanomembranes that are very promising, and the Global Trends 2025 recognizes them as being probable successes.

The Global Trends 2025 report identified Ubiquitous Computing, RFID (Radio Frequency Identification), and the “Internet of Things” as improving efficiency in supply chains, but more importantly, as possibly integrating closed societies into the global community (p. 47). SCADA (Supervisory Control And Data Acquisition) which is used to run everything from water treatment plants to nuclear power plants, is a harbinger of the “Internet of Things”, but the news is not always good. An “Internet of Things” will simply give more opportunities for hackers and terrorists to do harm. (SCADA manuals have been found in Al-Qaeda safe houses.)

Wealth depends on Technology
The 2025 report predicts that “the unprecedented transfer of wealth roughly from West to East now under way will continue for the foreseeable future… First, increases in oil and commodity prices have generated windfall profits for the Gulf states and Russia. Second, lower costs combined with government policies have shifted the locus of manufacturing and some service industries to Asia.”(p. vi)

But why would that transfer continue? If the current exponential growth of solar power continues, then within five years it will be obvious that oil is dead. Some of the more astute Arab leaders understand this; one Saudi prince said, “The Stone Age didn’t end because we ran out of stones, and the oil age won’t end because we run out of oil.”

China and India have gained a lion’s share of the world’s manufacturing, but is there any reason to believe that this will continue? Actually, there is one reason it might: most of the graduate students at most American Universities are foreign-born, and manufacturing underlies a vital part of the real wealth of a society; this in turn depends on its access to science and engineering. On the other hand, many of those foreign graduate students remain in the United States to become U.S. citizens. Even those who return to their home countries maintain personal relationship with American citizens, and generally spread positive stories about their experiences in the U.S., leading to more graduate students coming to the United States to settle.

The prediction that the United States will become a less dominant power is a sobering one for Americans. However, of the reasons listed in the report (advances by other countries in Science and Technology (S&T), expanded adoption of irregular warfare tactics, proliferation of long-range precision weapons, and growing use of cyber warfare attacks) the only significant item is S&T (Science and Technology). This is not only because S&T is the foundation for the other reasons listed, but also because it can often provide a basis for defending against new threats.

S&T is not only the foundation of military might, more importantly it is a foundation of economic might. However our economy rests not only on S&T, but also on economic policy. And unfortunately, everyone’s crystal ball is cloudy in this area. Historically , our regulated capitalism seems to be the basis for much of our wealth, and has been partially responsible for funding S&T. This is important because while human intelligence and ingenuity are scattered relatively evenly among the human race,[25] successful inventions are not. This is because it generally requires money to turn money into knowledge—that is research. After the research is done, the process of innovation—turning knowledge into money—begins, and is very dependent on the surrounding economic and political environment. At any rate, the relationship between the technology and economics is not clear, and certainly needs closer examination.

Wealth depends on Technology depends on Theology
The 2025 report contained some unspecified assumptions regarding economics, without defining what real wealth is, and on what it depends. At first glance, wealth is stored human labor—this was Marx’s assumption, and is slightly correct. However, one skilled person can do significantly more with good tools, hence the conclusion that tools are the lever of riches (hence Mokyr’s book of the same name[26]).

But tools are not enough. As Zhao (Peter) Xiao, a former Communist Party member and adviser to the Chinese Central Committee, put it:

“From the ancient time till now everybody wants to make more money. But from history we see only Christians have a continuous nonstop creative spirit and the spirit for innovation… The strong U.S. economy is just on the surface. The backbone is the moral foundation.” [27]

He goes on to explain that we are all made in the image and likeness of God, and are therefore His children, this means that:

The Rule of Law is not just something to cleverly avoid, but the means to happiness.
There is a constraint on unbridled and unjust capitalism.
People become rich by working hard to create real wealth, not by gaming the system—which creates waste and inefficiency. [28]

Xiao does not believe in “prosperity gospel” (i.e. send a televangelist $20 and God will make you rich). He understands that a economic system works more efficiently without false signals and other corruption—i.e. a nation will only have a prosperous economy if it has enough moral, law-abiding citizens. In addition, he may be hinting that the idea of Imago Dei (“Image of God”) explains how human intelligence drives Moore’s Law in the first place—if God is infinite, then it makes sense that His images will be able to endlessly do more with less.

Islam
The 2025 report mentions Islam fairly often but does not analyze it in depth. Oddly enough, the United States has been at war with Islamic nations longer than any other; starting with the Barbary pirates. So it behooves us to understand Islam to see if there are any fundamental issues that might be the root cause of some of these wars. Many Americans have denigrated Islam as a barbaric 6th century relic, not realizing the Judeao-Christian roots of this nation go back even farther (and are just as barbaric at times). Peter Kreeft has done an excellent job of examining the strengths of Islam, exhorting readers to learn from the followers of Mohammed.[29] But the purpose of this white paper is to investigate how Islamic beliefs hurt Muslims—and us.

There is no question that most Islamic nations have serious economic problems. Islamabad columnist Farrukh Saleem writes:

Muslims are 22 percent of the world population and produce less than five percent of global GDP. Even more worrying is that the Muslim countries’ GDP as a percent of the global GDP is going down over time. The Arabs, it seems, are particularly worse off. According to the United Nations’ Arab Development Report: ‘Half of Arab women cannot read; One in five Arabs live on less than $2 per day; Only 1 percent of the Arab population has a personal computer, and only half of 1 percent use the Internet; Fifteen percent of the Arab workforce is unemployed, and this number could double by 2010; The average growth rate of the per capita income during the preceding 20 years in the Arab world was only one-half of 1 percent per annum, worse than anywhere but sub-Saharan Africa.‘[30]

There are two possible reasons for the high rate of poverty in the Muslim world:

Diagnosis 1: Muslims are poor, illiterate, and weak because they have “abandoned the divine heritage of Islam”. Prescription: They must return to their real or imagined past, as defined by the Qur’an.

Diagnosis 2: Muslims are poor, illiterate, and weak because they have refused to change with time. Prescription: They must modernize technologically, governmentally, and culturally (i.e. start ignoring the Qur’an).[31]

Different Muslims will make different diagnosis, resulting in a continuation of the simultaneous rise of both secularized and fundamentalist Islam. This is the unexplained reason behind the 2025 report’s prediction that “the radical Salafi trend of Islam is likely to gain traction (p. ix).” While it is true that economics is an important causal factor, we must remember that economics are filtered through human psychology, which is filtered through human assumptions about reality (i.e. metaphysics and religion). The important question about Islam and nanotechnology is this: How will exponential increases in technology affect the answers of individual Muslims to the question raised above? One relatively easy prediction is that it will drive Muslims even more forcefully into both secularism and fundamentalism—with fewer adherents between them.

We must also address the underlying question: What is it about Islam beliefs that causes poverty? Global Trends 2025 points out that there is a significant correlation between the poverty of a nation and female literacy rates (p. 16). But the connection goes deeper than that.

A few hundred years ago, the Islam world was significantly ahead of Europe–technologically and culturally—but then Islamic leaders declared as heretics their greatest philosophers, especially Averroes (Ibn Rushd) who tried to reconcile faith and reason. Christianity struggled with the same tension between faith and reason, but ended up declaring as saints their greatest philosophers, most notably Thomas Aquinas. In addition, Christianity declared heretical those who derided reason, such as Tertulian, who mocked philosophy by asking “What does Athens have to do with Jerusalem”. Reason is vital to science and technology. But the divorce between faith and reason in Islam is not a historical accident; just as it is not an accident in Christianity that the two are joined—these results are due to their respective theologies.

In Islam, the relationship between Allah and humans is a master/slave relationship, and this is reflected in everything–most painfully in the Islam concept of marriage and how women are treated as a result (hence the link between poverty and female literacy). This belief is rooted in more fundamental dogma regarding the absolute transcendence of Allah, which is also manifested in the Islamic attitude towards science. The practical result, as pointed out earlier, is economic poverty (documented in Mokyr’s The Lever to Riches, and recognized in the 2025 report (p. 13) where it points out that science and technology is related to economic growth). Pope Benedict pointed out that If Allah is completely transcendent, then there is no rational order in His creation[32]—therefore there would be little incentive trying to discover it. This is the same reason that paganism did not develop science and technology. Aristotle started science by counterbalancing Plato’s rationalism with empiricism, but they (and Socrates) had to jettison most of their pagan beliefs in order to lay these foundations of science. And it still required many centuries to get to Bacon and the scientific method.

The trouble with most Americans is that we have no sense of history. Islam has been at war (mostly with Judaism and Christianity) for millennia (the pagans in their path didn’t last long enough to make any difference). There is little indication that anything will change by 2025. Israel and its Arab neighbors have hated each other ever since Isaac and Ishmael, almost 4000 years ago (if the Qur’an is to be believed in Sura 19:54). The probability that the enmity between these ancient enemies will cool in the next 15 years is infinitesimally small. To make matters worse, extracts of statements by Osama Bin Laden indicate that the 9/11 attack occurred because:

America is the great Satan. Actually, many Christian Evangelicals and traditional Catholics and Jews sympathize with Bin Laden’s accusation in this case (while deploring his methods), noting our cultural promotion of pornography, abortion, and homosexuality.
American bases are stationed in Saudi Arabia (the home of Mecca), which many Muslims see as a blasphemy. It is difficult for Americans to understand why this is so bad—we even protect the right to burn and desecrate our own flag.
Our support for Israel. Since Israel is one of the few democracies in the Mideast, and since it’s culture doesn’t raise suicide bombers, it seems quite reasonable that we should support it—it’s the right thing to do. As an appeal to self-interest, we can always remember that over the past 105 years, 1.4 billion Muslims have produced only eight Nobel Laureates while a mere 14 million Jews have produced 167 Nobel Laureates.

Given the history of Islam’s relationship with all other belief systems, the outlook looks gloomy. If the past 1400 years are any guide, Islam will continue to be at war with Paganism, Atheism, Hinduism, Judaism, and Christianity—both in hot wars of conquest and in psychological battles for the hearts and minds of the world.[33]

Muslim Demographics
The 2025 report made a wise decision in covering demographic issues, since they are predictable. But it did not investigate the causal sources (personal and cultural beliefs) of crucial demographic trends. The report writes that “the radical Salafi trend of Islam is likely to gain traction” in “those countries that are likely to struggle with youth bulges and weak economic underpinnings. (Page ix)”

This is certainly an accurate prediction. But what human beliefs lead to behavior that leads to youth bulges and weak economies? The answer is quite complex, partially because the Quran is not crystal clear on this issue. But generally “Muslim religiosity and support for Shari’a Law are associated with higher fertility” and that better education, higher wealth, and urbanization do not reduce Muslim fertility (as it does with other religions). The result is that while religious fundamentalism in Islam does not boost fertility as much as it does for Jewish traditionalists in Israel, it is still true that “fertility dynamics could power increased religiosity and Islamism in the Muslim world in the twenty-first century.“[34]

Other Practical Aspects of Islam Theology
One of the reasons the Western world is at odds with Islam is because of different views on freedom and virtue. Americans generally value freedom over virtue. In Islam, however, virtue is far more important than freedom, despite the fact that virtue requires an act of free will. In other words, Muslims don’t seem to realize that if good behavior is forced, then it is not really virtuous. Meanwhile, here in the USA we seem to have forgotten that vices enslave us—as demonstrated by addictions to drugs, gambling, and sex; we have forgotten that true freedom requires us to be virtuous—that we must bridle our passions in order to be truly free.

A disturbing facet of Islam is that it requires the death of an apostate. Theologically, this is because Allah is master, not father or spouse (as most often portrayed in the Bible), and submission to Allah is mandatory in Islam. While it is true that Christianity authorized the secular authorities to burn a few thousand heretics over two thousand years, these were in extreme situations of maximum irrationality that were fixed fairly quickly hundreds of years ago (often a single thoughtful bishop or priest stopped an outbreak). In contrast, fatwahs demanding the death penalty for apostates and heretics are still common in Islamic countries.[35]

Theology, Technological Progress, and Cultural Success
Religions do not make people stupid or cowardly. President Bush may have called the 9/11 Islamic terrorists cowardly, but they were not. They went to their deaths as bravely as any American soldier. Nor were they stupid—otherwise they never would have been able to pull off the most devastating terrorist attack on the U.S. in our relatively short history, cleverly devising a way to use our open society and our technology to maximal effect. But as individuals they were deluded, and their culture could not design or build jumbo jets; hence they used ours. This means that Islamic terrorists will be glad to use nanotechnological weapons as eagerly as nuclear ones—once they get their hands on them. The problem, of course, is that nano-enhanced weapons will be much easier to develop than nuclear ones.

Conclusion
Ever since the time of the Pilgrims, Americans have considered themselves citizens of a “bright, shining city on the hill” and much of the world agreed, with immigrants pouring in for three centuries to build the most powerful nation in history. Our representative democracy and loosely-regulated capitalism, regulated by individual consciences based on a Judeo-Christian foundation of rights and responsibilities, has been copied all over the world (at least superficially). But will this shining city endure?

It is the task of the U.S. National Intelligence Council to make sure that it does, and their effort to understand the future is an important step in that direction. Hopefully they will examine more closely the impact that technology, especially productive nanosystems, will have on political structures. In addition, they need to understand the theological underpinnings of Islam, and how it will affect the technological capabilities of Muslim nations.

Addendum
For a better government-sponsored report on how technology will affect us, see Toffler Associates’ Technology and Innovation 2025 at http://www.toffler.com/images/Toffler_TechAndInnRep1-09.pdf.

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[1] National Intelligence Council, Global Trends 2025: A Transformed World http://www.dni.gov/nic/PDF_2025/2025_Global_Trends_Final_Report.pdf and www.dni.gov/nic/NIC_2025_project.html

[2] Earlier exceptions are rare, though technology has been lost occasionally—most notably 5th century Europe after the fall of the Roman Empire, and 15th century China after the last voyage of Admiral Zeng He’s Treasure Fleet of the Dragon Throne.

[3] Singularity Symposium, Exponential Growth and the Legend of Paal Paysam. http://www.singularitysymposium.com/exponential-growth.html

[4] Ray Kurzweil, The Law of Accelerating Returns. March 7, 2001. http://www.kurzweilai.net/articles/art0134.html?printable=1

[5] Matthew R. Simmons, Revisiting The Limits to Growth: Could The Club of Rome Have Been Correct, After All? (Part One). Sep 30 2000. http://www.energybulletin.net/node/1512 Note that technological optimists always quote the chess example, while environmental doomsayers always quote the lily pad example.

[6] High-performance lithium battery anodes using silicon nanowires, Candace K. Chan, Hailin Peng, Gao Liu, Kevin McIlwrath, Xiao Feng Zhang, Robert A. Huggins & Yi Cui, Nature Nanotechnology 3, 31 — 35 (2008). http://www.nature.com/nnano/journal/v3/n1/abs/nnano.2007.411.html

[7] See Nanotechnology’s biggest stories of 2008 http://www.newscientist.com/article/dn16340-nanotechnologys-biggest-stories-of-2008.html and Top Ten Nanotechnology Patents of 2008 http://tinytechip.blogspot.com/2008/12/top-ten-nanotechnology-patents-of-2008.html

[8] Paul Rothemund. Folding DNA to create nanoscale shapes and patterns, Nature, V440N16. March 2006.

[9] Christian E. Schafmeister. The Building Blocks of Molecular Nanotechnology. Conference on Productive Nanosystems: Launching the Technology Roadmap. Arlington, VA. Oct. 9–10, 2007.

[10] John N. Randall. A Path to Atomically Precise Manufacturing. Conference on Productive Nanosystems: Launching the Technology Roadmap. Arlington, VA. Oct. 9–10, 2007.

[11] Ralph Merkle and Robert Freitas Jr., “Theoretical analysis of a carbon-carbon dimer placement tool for diamond mechanosynthesis,” Journal of Nanoscience and Nanotechnology. 3(August 2003):319-324; http://www.rfreitas.com/Nano/JNNDimerTool.pdf

[12] Robert A. Freitas Jr. and Ralph C. Merkle, A Minimal Toolset for Positional Diamond Mechanosynthesis, Journal of Computational and Theoretical Nanoscience. Vol.5, 760–861, 2008

[13] Jingping Peng, Robert. Freitas, Jr., Ralph Merkle, James Von Ehr, John Randall, and George D. Skidmore. Theoretical Analysis of Diamond Mechanosynthesis. Part III. Positional C2 Deposition on Diamond C(110) Surface Using Si/Ge/Sn-Based Dimer Placement Tools. Journal of Computational and Theoretical Nanoscience. Vol.3, 28-41, 2006. http://www.molecularassembler.com/Papers/JCTNPengFeb06.pdf

[14] Adrian Bowyer, et al. RepRap-Wealth without money. http://reprap.org/bin/view/Main/WebHome

[15] John Storrs Hall, The Weather Machine. December 23, 2008, http://www.foresight.org/nanodot/?p=2922

[16] National Security Space Office. Space-Based Solar Power As an Opportunity for Strategic Security: Phase 0 Architecture Feasibility Study. http://www.scribd.com/doc/8736624/SpaceBased-Solar-Power-Interim-Assesment-01

[17] John Storrs Hall, Utility Fog: The Stuff that Dreams are Made Of. http://autogeny.org/Ufog.html

[18] John Storrs Hall, The Space Pier: A hybrid Space-launch Tower concept. http://autogeny.org/tower/tower.html

[19] Pacific Northwest National Laboratory, SAMMS: Self-Assembled Monolayers on Mesoporous Supports. http://samms.pnl.gov/

[20] OECD Nuclear Energy Agency. Trends in the nuclear fuel cycle: economic, environmental and social aspects, Organization for Economic Co-operation and Development 2001

[21] Mark Clayton. Will lasers brighten nuclear’s future? The Christian Science Monitor/ August 27, 2008. http://features.csmonitor.com/innovation/2008/08/27/will-lasers-brighten-nuclears-future/

[22] Paul Werbos, What should we be doing today to enhance world energy security, in order to reach a sustainable global energy system? http://www.werbos.com/energy.htm See also Robert Zubrin, Energy Victory: Winning the War on Terror by Breaking Free of Oil. Prometheus Books. November 2007.

[23] John Storrs Hall, The weather machine. December 23, 2008, http://www.foresight.org/nanodot/?p=2922

[24] Tihamer Toth-Fejel, A Few Lesser Implications of Nanofactories: Global Warming is the Least of our Problems, Nanotechnology Perceptions, March 2009.

[25] Exceptions would be small groups who were subject to selective pressure to increase intelligence, such as the Ashkenazi Jews.

[26] Joel Mokyr , The Lever of Riches: Technological Creativity and Economic Progress. Oxford University Press, USA (April 9, 1992). http://www.amazon.com/Lever-Riches-Technological-Creativity-Economic/dp/0195074777

[27] Zhao (Peter) Xiao, Market Economies With Churches and Market Economies Without Churches http://www.danwei.org/business/churches_and_the_market_econom.php

[28] ibid.

[29] Peter Kreeft, Ecumenical Jihad: Ecumenism and the Culture War, Ignatius Press (March 1996). More specifically, Kreeft points out that Muslims have lower rates of abortion, adultery, fornication, and sodomy; and higher rates of prayer and devotion to God. Kreeft then repeats the Biblical admonition that God blesses those who obey His commandments. For atheists and agnostics, it might be more palatable to think of it as evolution in action: If a group encourages behavior that reduces the number of capable offspring, then it is doomed.

[30] Farrukh Saleem, Muslims amongst world’s poorest weakest, illiterate: What Went Wrong. November 08, 2005 http://islamicterrorism.wordpress.com/2008/07/01/muslims-amongst-worlds-poorest-weakest-illiterate-what-went-wrong/

[31] ibid.

[32] Pope Benedict XVI. Faith, Reason and the University: Memories and Reflections. University of Regensburg, September 2006. http://www.vatican.va/holy_father/benedict_xvi/speeches/2006/september/documents/hf_ben-xvi_spe_20060912_university-regensburg_en.html

[33] Note that this report is not a critique of Muslim people—only their beliefs (though it may not feel that way to them).

[34] Kaufmann, E. P. , “Islamism, Religiosity and Fertility in the Muslim World,” Annual meeting of the ISA’s 50th Annual Convention: Exploring the Past, Anticipating the Future. New York, NY. Feb 13-15, 2009. http://www.allacademic.com/meta/p312181_index.html

[35] On the other hand (to put things in perspective), compared to the atheists Stalin, Mao, and Pol Pot, even the most deadly Muslims extremists are rank amateurs at mass murder. Perhaps that is why Communism has barely lasted two generations, while Islam has lasted fourteen centuries. You just can’t go around killing people.

Tihamer Toth-Fejel, MS
General Dynamics Advanced Information Systems
Michigan Research and Development Center