Molecular Manufacturing : Lethal Aspacts
Overview: Molecular manufacturing (MM) will be a significant breakthrough, comparable perhaps to the Industrial Revolution—but compressed into a few years. This has the potential to disrupt many aspects of society and politics. The power of the technology may cause two competing nations to enter a disruptive and unstable arms race. Weapons and surveillance devices could be made small, cheap, powerful, and very numerous. Cheap manufacturing and duplication of designs could lead to economic upheaval. Overuse of inexpensive products could cause widespread environmental damage. Attempts to control these and other risks may lead to abusive restrictions, or create demand for a black market that would be very risky and almost impossible to stop; small nanofactories will be very easy to smuggle, and fully dangerous. There are numerous severe risks—including several different kinds of risk—that cannot all be prevented with the same approach. Simple, one-track solutions cannot work. The right answer is unlikely to evolve without careful planning.
| Molecular manufacturing suddenly will create many risks. | The potential benefits of molecular manufacturing (MM) are immense, but so are the dangers. In order to avert the dangers, we must thoroughly understand them, and then develop comprehensive plans to prevent them. As explained in our Timeline and Products pages, MM will allow the rapid prototyping and inexpensive manufacture of a wide variety of powerful products. This capability will arrive rather suddenly, since the final steps of developing the technology are likely to be much easier than the initial steps, and many of them can be pre-planned. The sudden arrival of molecular manufacturing may not allow time to adjust to its implications. Adequate preparation is essential. |
| CRN has identified several separate and severe risks.
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The first step in understanding the dangers is to identify them. CRN has begun that process here, listing and describing several separate and severe risks. Although probably incomplete, the list is worrisome already:
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| Some of the dangers described here are existential risks, that is, they may threaten the continued existence of humankind. Others could produce significant disruption but not cause our extinction. A combination of several risks could exacerbate the seriousness of each; any solution must take into account its effect on other risks. | |
| Some of these risks arise from too little regulation, and others from too much regulation. Several different kinds of regulation will be necessary in several different fields. An extreme or knee-jerk response to any of these risks will create fertile ground for other risks. The temptation to impose apparently obvious and simple solutions to problems in isolation must be avoided. Other pages address the possibilities for regulation; this one is concerned with discussing and analyzing the dangers. |
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| Disruption of the basis of economy is a strong possibility. | The purchaser of a manufactured product today is paying for its design, raw materials, the labor and capital of manufacturing, transportation, storage, and sales. Additional money—usually a fairly low percentage—goes to the owners of all these businesses. If personal nanofactories can produce a wide variety of products when and where they are wanted, most of this effort will become unnecessary. This raises several questions about the nature of a post-nanotech economy. Will products become cheaper? Will capitalism disappear? Will most people retire—or be unemployed? The flexibility of nanofactory manufacturing, and the radical improvement of its products, imply that non-nanotech products will not be able to compete in many areas. If nanofactory technology is exclusively owned or controlled, will this create the world’s biggest monopoly, with extreme potential for abusive anti-competitive practices? If it is not controlled, will the availability of cheap copies mean that even the designers and brand marketers don’t get paid? Much further study is required, but it seems clear that molecular manufacturing could severely disrupt the present economic structure, greatly reducing the value of many material and human resources, including much of our current infrastructure. Despite utopian post-capitalist hopes, it is unclear whether a workable replacement system could appear in time to prevent the human consequences of massive job displacement. |
| Major investment firms are conscious of potential economic impact. | In the mainstream financial community, there is growing recognition that nanotechnology represents a significant wave of innovation with the potential to restructure the economy. Here, for example, is an excerpt from an analysis prepared for investors by Credit Suisse First Boston: |
| Nanotechnology is a classic, general-purpose technology (GPT). Other GPTs, including steam engines, electricity, and railroads, have been the basis for major economic revolutions. GPTs typically start as fairly crude technologies, with limited uses, but then rapidly spread into new applications. | |
| All prior GPTs have led directly to major upheavals in the economy—the process of creative destruction. And nanotechnology may be larger than any of the other GPTs that preceded it. Creative destruction is the process by which a new technology or product provides an entirely new and better solution, resulting in the complete replacement of the original technology or product. Investors should expect that creative destruction will not only continue, but will also likely accelerate, and nanotechnology will be at the core. | |
| What does this mean from a practical standpoint? Because of the advent of nanotechnology, we believe new companies will displace a high percentage of today’s leading companies. The majority of the companies in today’s Dow Jones industrials Index are unlikely to be there 20 years from now. (Excerpted with permission from “Big Money in Thinking Small”, authored by Michael Mauboussin and Kristen Bartholdson.) | |
| Along those same lines, Josh Wolfe of Lux Capital, editor of the Forbes/Wolfe Nanotech Report, writes: “Quite simply, the world is about to be rebuilt (and improved) from the atom up. That means tens of trillions of dollars to be spent on everything: clothing… food… cars… housing… medicine…the devices we use to communicate and recreate…the quality of the air we breathe…and the water we drink, are all about to undergo profound and fundamental change. And as a result, so will the socio and economic structure of the world. Nanotechnology will shake up just about every business on the planet.” | |
| Nano-built products may be vastly overpriced relative to their cost, perpetuating unnecessary poverty. | By today’s commercial standards, products built by nanofactories would be immensely valuable. A monopoly would allow the owners of the technology to charge high rates for all products, and make high profits. However, if carried to its logical conclusion, such a practice would deny cheap lifesaving technologies (as simple as water filters or mosquito netting) to millions of people in desperate need. Competition will eventually drive prices down, but an early monopoly is likely for several reasons. Due to other risks listed on this page, it is unlikely that a completely unregulated commercial market will be allowed to exist. In any case, the high cost of development will limit the number of competing projects. Finally, a company that pulls ahead of the pack could use the resulting huge profits to stifle competition by means such as broad enforcement of expansive patents and lobbying for special-interest industry restrictions. |
| The price of a product usually falls somewhere between its value to the purchaser and its cost to the seller. Molecular manufacturing could result in products with a value orders of magnitude higher than their cost. It is likely that the price will be set closer to the value than to the cost; in this case, customers will be unable to gain most of the benefit of “the nanotech revolution”. If pricing products by their value is accepted, the poorest people may continue to die of poverty, in a world where products costing literally a few cents would save a life. If (as seems likely) this situation is accepted more by the rich than by the poor, social unrest could add its problems to untold unnecessary human suffering. A recent example is the agreement the World Trade Organization was working on to provide affordable medicines to poor countries—which the Bush administration partially prevented (following heavy lobbying by American pharmaceutical companies) despite furious opposition from every other WTO member. | |
| Criminals and terrorists could make effective use of the technology. | Criminals and terrorists with stronger, more powerful, and much more compact devices could do serious damage to society. Defenses against these devices may not be installed immediately or comprehensively. Chemical and biological weapons could become much more deadly and easier to conceal. Many other types of terrifying devices are possible, including several varieties of remote assassination weapons that would be difficult to detect or avoid. |
| As a result of small integrated computers, even tiny weapons could be aimed at targets remote in time and space from the attacker. This will not only impair defense, but also will reduce post-attack detection and accountability. Reduced accountability could reduce civility and security, and increase the attractiveness of some forms of crime. | |
| If nanofactory-built weapons were available from a black market or a home factory, it would be quite difficult to detect them before they were launched; a random search capable of spotting them would almost certainly be intrusive enough to violate current human rights standards. | |
| Extreme solutions and abusive regulations may be attempted. | A patchwork of extreme solutions may be created in response to the other risks described here. This would not be a good idea. Many of these problems appear to have an obvious solution. However, in each case, that solution, applied to the extreme necessary to impact the target problem, would exacerbate another problem and make the overall situation worse. A collection of extreme solutions will surely be undesirable; it will either be ineffective (and ineffective policies can still be quite harmful) or will create massive human suffering or human rights violation. |
| There is a possibility that abusive restrictions and policies may be attempted, such as round-the-clock surveillance of every citizen. Such surveillance might be possible with AI (artificial intelligence) programs similar to one under development at MIT, which is able to analyze a video feed, learn familiar patterns, and notice unfamiliar patterns. Molecular manufacturing will allow the creation of very small, inexpensive supercomputers that conceivably could run a program of constant surveillance on everyone. Surveillance devices would be easy to manufacture cheaply in quantity. Surveillance is only one possible kind of abuse. With the ability to build billions of devices, each with millions of parts, for a total cost of a few dollars, any automated technology that can be applied to one person can be applied to everyone. Any scenario of physical or psychiatric control that explores the limits of nanotechnology will sound science-fictional and implausible. The point is not the plausibility of any given scenario; it is that the range of possibilities is limited mainly by the imagination and cruelty of those with power. Greed and power are strong motivators for abusive levels of control; the fear of nanotech and other advanced technologies in private hands adds an additional impetus for abusive rule. | |
| Society could be disrupted by the availability of new “immoral” products. | New products and lifestyles may cause significant social disruption. For example, medical devices could be built into needles narrower than a bacterium, perhaps allowing easy brain modification or stimulation, with effects similar to any of a variety of psychoactives. Most societies have found it desirable to forbid certain products: guns in Britain, seedless watermelon in Iran, sex toys in Texas, various drugs in various societies such as hashish in the United States and alcohol in Muslim societies. Although many of these restrictions are based on moral principles not shared by the majority of the world’s population, the fact that the restrictions exist at all indicates the sensitivity of societies—or at least their rulers—to undesired products. The ability to make banned products using personal factories could be expected to be at least somewhat disruptive to society, and could provide an impetus for knee-jerk and overly broad restrictions on the technology. New lifestyles enabled by new technology could also cause social disruption. Whereas demand for banned products already exists, lifestyles develop over time, so the effects of lifestyle change are likely to be less acute. However, some lifestyle possibilities (particularly in the areas of sex, drugs, entertainment, and body or genetic modification) are likely to be sufficiently disturbing to onlookers that their very existence would cause disruption. |
| Nanotech weapons would be extremely powerful and could lead to a dangerously unstable arms race. | Molecular manufacturing raises the possibility of horrifically effective weapons. As an example, the smallest insect is about 200 microns; this creates a plausible size estimate for a nanotech-built antipersonnel weapon capable of seeking and injecting toxin into unprotected humans. The human lethal dose of botulism toxin is about 100 nanograms, or about 1/100 the volume of the weapon. As many as 50 billion toxin-carrying devices—theoretically enough to kill every human on earth—could be packed into a single suitcase. Guns of all sizes would be far more powerful, and their bullets could be self-guided. Aerospace hardware would be far lighter and higher performance; built with minimal or no metal, it would be much harder to spot on radar. Embedded computers would allow remote activation of any weapon, and more compact power handling would allow greatly improved robotics. These ideas barely scratch the surface of what’s possible. |
| An important question is whether nanotech weapons would be stabilizing or destabilizing. Nuclear weapons, for example, perhaps can be credited with preventing major wars since their invention. However, nanotech weapons are not very similar to nuclear weapons. Nuclear stability stems from at least four factors. The most obvious is the massive destructiveness of all-out nuclear war. All-out nanotech war is probably equivalent in the short term, but nuclear weapons also have a high long-term cost of use (fallout, contamination) that would be much lower with nanotech weapons. Nuclear weapons cause indiscriminate destruction; nanotech weapons could be targeted. Nuclear weapons require massive research effort and industrial development, which can be tracked far more easily than nanotech weapons development; nanotech weapons can be developed much more rapidly due to faster, cheaper prototyping. Finally, nuclear weapons cannot easily be delivered in advance of being used; the opposite is true of nanotech. Greater uncertainty of the capabilities of the adversary, less response time to an attack, and better targeted destruction of an enemy’s visible resources during an attack all make nanotech arms races less stable. Also, unless nanotech is tightly controlled, the number of nanotech nations in the world could be much higher than the number of nuclear nations, increasing the chance of a regional conflict blowing up. | |
| Admiral David E. Jeremiah, Vice-Chairman (ret.), U.S. Joint Chiefs of Staff, in an address at the 1995 Foresight Conference on Molecular Nanotechnology said: “Military applications of molecular manufacturing have even greater potential than nuclear weapons to radically change the balance of power.” | |
| An excellent essay by Tom McCarthy (unaffiliated with CRN) explores these points in more detail. He discusses the ways that nanotechnology can destabilize international relations: molecular manufacturing will reduce economic influence and interdependence, encourage targeting of people as opposed to factories and weapons, and reduce the ability of a nation to monitor its potential enemies. It may also, by enabling many nations to be globally destructive, eliminate the ability of powerful nations to “police” the international arena. By making small groups self-sufficient, it can encourage the breakup of existing nations. | |
| Collective environmental damage is a natural consequence of cheap manufacturing, as are health risks. (MORE) | Molecular manufacturing allows the cheap creation of incredibly powerful devices and products. How many of these products will we want? What environmental damage will they do? The range of possible damage is vast, from personal low-flying supersonic aircraft injuring large numbers of animals to collection of solar energy on a sufficiently large scale to modify the planet’s albedo and directly affect the environment. Stronger materials will allow the creation of much larger machines, capable of excavating or otherwise destroying large areas of the planet at a greatly accelerated pace. It is too early to tell whether there will be economic incentive to do this. However, given the large number of activities and purposes that would damage the environment if taken to extremes, and the ease of taking them to extremes with molecular manufacturing, it seems likely that this problem is worth worrying about. Some forms of damage can result from an aggregate of individual actions, each almost harmless by itself. Such damage is quite hard to prevent by persuasion, and laws frequently don’t work either; centralized restriction on the technology itself may be a necessary part of the solution. Finally, the extreme compactness of nanomanufactured machinery will tempt the use of very small products, which can easily turn into nano-litter that will be hard to clean up and may cause health problems. |
| Grey goo was an early concern of nanotechnology. | When nanotechnology-based manufacturing was first proposed, a concern arose that tiny manufacturing systems might run amok and ‘eat’ the biosphere, reducing it to copies of themselves. In 1986, Eric Drexler wrote, “We cannot afford certain kinds of accidents with replicating assemblers.” More recent designs by Drexler and others make it clear, though, that replicating assemblers will not be used for manufacturing—nanofactories will be much more efficient at building products, and a nanofactory is nothing like a ‘grey goo’ robot. |
| Grey goo would entail five capabilities integrated into one small package. These capabilities are: Mobility – the ability to travel through the environment; Shell – a thin but effective barrier to keep out diverse chemicals and ultraviolet light; Control – a complete set of blueprints and the computers to interpret them (even working at the nanoscale, this will take significant space); Metabolism – breaking down random chemicals into simple feedstock; and Fabrication – turning feedstock into nanosystems. A nanofactory would use tiny fabricators, but these would be inert if removed or unplugged from the factory. The rest of the listed requirements would require substantial engineering and integration. | |
| Grey goo won’t happen by accident, but eventually could be developed on purpose. | Although grey goo has essentially no military and no commercial value, and only limited terrorist value, it could be used as a tool for blackmail. Cleaning up a single grey goo outbreak would be quite expensive and might require severe physical disruption of the area of the outbreak (atmospheric and oceanic goos deserve special concern for this reason). Another possible source of grey goo release is irresponsible hobbyists. The challenge of creating and releasing a self-replicating entity apparently is irresistible to a certain personality type, as shown by the large number of computer viruses and worms in existence. We probably cannot tolerate a community of “script kiddies” releasing many modified versions of goo. |
| Development and use of molecular manufacturing poses absolutely no risk of creating grey goo by accident at any point. However, goo type systems do not appear to be ruled out by the laws of physics, and we cannot ignore the possibility that the five stated requirements could be combined deliberately at some point, in a device small enough that cleanup would be costly and difficult. Drexler’s 1986 statement can therefore be updated: We cannot afford criminally irresponsible misuse of powerful technologies. Having lived with the threat of nuclear weapons for half a century, we already know that. | |
| We wish we could take grey goo off CRN’s list of dangers, but we can’t. It eventually may become a concern requiring special policy. Grey goo will be highly difficult to build, however, and non-replicating nano-weaponry may be substantially more dangerous and more imminent. NOTE: In June 2004, Eric Drexler and Chris Phoenix published a new paper on “Safe Exponential Manufacturing“, which puts the perceived grey goo threat into perspective. |
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| Too little or too much regulation can result in unrestricted availability. | Uncontrolled availability of nanofactory technology can result from either insufficient or overzealous regulation. Inadequate regulation would make it easy to obtain and use an unrestricted nanofactory. Overzealous regulation would create a pent-up demand for nanotech products, which if it gets strong enough, would fund espionage, cracking of restricted technology, or independent development, and eventually create a black market beyond the control of central authorities (nanofactories are very smugglable). Note that sufficiently abusive or restrictive regulation can motivate internal espionage; at least one atomic spy in the US was idealistically motivated. Uncontrolled availability of molecular manufacturing greatly increases many of the dangers cited above. |
| Competing nanotech programs increase the danger. | The existence of multiple programs to develop molecular manufacturing greatly increases some of the risks listed above. Each program provides a separate opportunity for the technology to be stolen or otherwise released from restriction. Each nation with an independent program is potentially a separate player in a nanotech arms race. The reduced opportunity for control may make restrictions harder to enforce, but this may lead to greater efforts to impose harsher restrictions. Reduced control also makes it less likely that a non-disruptive economic solution can develop. |
| Relinquishment is counterproductive. | Facing all these risks, there will be a strong temptation simply to outlaw the technology. However, we don’t believe this can work. Many nations are already spending millions on basic nanotechnology; within a decade, advanced nanotech will likely be within the reach of large corporations. It can’t be outlawed worldwide. And if the most risk-aware countries stop working on it, then the less responsible countries are the ones that will be developing it and dealing with it. Besides, legal regulation may not have much effect on covert military programs. |
| Molecular manufacturing may be delayed by strict regulation, but this would probably make things worse in the long run. If MM development is delayed until it’s relatively easy, it will then be a lot harder to keep track of all the development programs. Also, with a more advanced technology base, the development of nano-built products could happen even faster than we have described, leaving less time to adjust to the societal disruptions. | |
| Solving these problems won’t be easy. | Some of these risks arise from too little regulation, and others from too much regulation. Several different kinds of regulation will be necessary in several different fields. An extreme or knee-jerk response to any of these risks will simply create fertile ground for other risks. The risks are of several different types, so a single approach (commercial, military, free-information) cannot prevent all of them. Some of the risks are sufficiently extreme that society cannot adjust to the risk while testing various approaches to prevent it. A single grey goo release, or unstable nanotech arms race, is intolerable. Threading a path between all these risks will require careful advance planning. |
Benefits of Molecular Manufacturing
Overview: Molecular manufacturing (MM) can solve many of the world’s current problems. For example, water shortage is a serious and growing problem. Most water is used for industry and agriculture; both of these requirements would be greatly reduced by products made by molecular manufacturing. Infectious disease is a continuing scourge in many parts of the world. Simple products like pipes, filters, and mosquito nets can greatly reduce this problem. Information and communication are valuable, but lacking in many places. Computers and display devices would become stunningly cheap. Electrical power is still not available in many areas. The efficient, cheap building of light, strong structures, electrical equipment, and power storage devices would allow the use of solar thermal power as a primary and abundant energy source. Environmental degradation is a serious problem worldwide. High-tech products can allow people to live with much less environmental impact. Many areas of the world cannot rapidly bootstrap a 20th century manufacturing infrastructure. Molecular manufacturing technology can be self-contained and clean; a single packing crate or suitcase could contain all equipment required for a village-scale industrial revolution. Finally, MM will provide cheap and advanced equipment for medical research and health care, making improved medicine widely available. Much social unrest can be traced directly to material poverty, ill health, and ignorance. MM can contribute to great reductions in all of these problems, and in the associated human suffering.
| Advanced nanotech can solve many human problems. | Technology is not a panacea. However, it can be extremely useful in solving many kinds of problems. Improved housing and plumbing will increase health. More efficient agriculture and industry save water, land, materials, and labor, and reduce pollution. Access to information, education, and communication provides many opportunities for self improvement, economic efficiency, and participatory government. Cheap, reliable power is vital for the use of other technologies and provides many conveniences. Today, technology relies on distributed manufacturing, which requires many specialized materials and machines and highly trained labor. It is a difficult and slow process to develop an adequate technology base in an impoverished area. However, molecular manufacturing does not require skilled labor or a large supporting infrastructure; a single personal nanofactory (PN) with a single chemical supply and power supply can produce a wide range of useful, reliable products, including copies of itself to double the manufacturing infrastructure in hours, if desired. Thus PNs, and many of their products, are “appropriate technology” for almost any setting. |
| Many diverse problems are related to water. | A few basic problems create vast amounts of suffering and tragedy. According to a World Bank document, water is a major concern of the U.N. Almost half the world’s population lacks access to basic sanitation, and almost 1.5 billion have no access to clean water. Of the water used in the world, 67% is used for agriculture, and another 19% for industry. Residential use accounts for less than 9%. Much industry can be directly replaced by molecular manufacturing. Agriculture can be moved into greenhouses. Residential water can be treated and recycled. Adoption of these steps could reduce water consumption by at least 50%, and probably 90%. Water-related diseases kill thousands, perhaps tens of thousands, of children each day. This is entirely preventable with basic technology, cheap to manufacture—if the factories are cheap and portable. MNT can provide similar opportunities in many other areas. |
| Much water today is wasted because it is almost but not entirely pure. Simple, reliable mechanical and electrical treatment technologies can recover brackish or tainted water for agricultural or even domestic use. These technologies require only initial manufacturing and a modest power supply. Physical filters with nanometer-scale pores can remove 100% of bacteria, viruses, and even prions. An electrical separation technology that attracts ions to supercapacitor plates can remove salts and heavy metals. The ability to recycle water from any source for any use can save huge amounts of water, and allow the use of presently unusable water resources. It can also eliminate downstream pollution; a completely effective water filter also permits the generation of quite “dirty” waste streams from agricultural and industrial operations. As long as the waste is contained, it can be filtered, concentrated, and perhaps even purified and used profitably. As with anything built by molecular nanotechnology, initial manufacturing costs for a water treatment system would be extremely low. Power will be cheap (see below). Well-structured filter materials and smaller actuators will allow even the smallest filter elements to be self-monitoring and self-cleaning. Self-contained, small, completely automated filter units can be integrated in systems scalable over a wide range. | |
| Cheap greenhouses can save water, land, and food. | Moving agriculture into greenhouses can recover most of the water used, by dehumidifying the exhaust air and treating and re-using runoff. Additionally, greenhouse agriculture requires less labor and far less land area than open-field agriculture, and provides greater independence from weather conditions including seasonal variations and droughts. Greenhouses, with or without thermal insulation, would be extremely cheap to build with nanotechnology. A large-scale move to greenhouse agriculture would reduce water use, land use, and weather-related food shortages. |
| Nanotech makes solar energy feasible. | The main source of power today is the burning of carbon-containing fuels. This is generally inefficient, frequently non-renewable, and dumps carbon dioxide and other waste products (including radioactive substances from coal) into the atmosphere. Solar energy would be feasible in most areas of the globe if manufacturing and land were sufficiently cheap and energy storage were sufficiently effective. Solar electricity generation depends on either photovoltaic conversion, or concentrating direct sunlight. The former works, although with reduced efficiency, on cloudy days; the latter can be accomplished without semiconductors. In either case, not much material is required, and mechanical designs can be made simple and fairly easy to maintain. Sun-tracking designs can benefit from cheap computers and compact actuators. Energy can be stored efficiently for several days in relatively large flywheels built of thin diamond and weighted with water. Smaller energy storage systems can be built with diamond springs, providing a power density similar to chemical fuel storage and much higher than today’s batteries. Water electrolysis and recombination provide scalable, storable, transportable energy. However, there is some cost in efficiency and in complexity of technology to deal safely with large-scale hydrogen storage or transportation. |
| Solar solutions can be implemented on an individual, village, or national scale. The energy of direct sunlight is approximately 1 kW per square meter. Dividing that by 10 to account for nighttime, cloudy days, and system inefficiencies, present-day American power demands (about 10 kW per person) would require about 100 square meters of collector surface per person. Multiplying this figure by a population of 325 million (estimated by the US Census Bureau for 2020) yields a requirement for approximately 12,500 square miles of area to be covered with solar collectors. This represents 0.35% of total US land surface area. Much of this could be implemented on rooftops, and conceivably even on road surfaces. | |
| Living spaces can be greatly improved. | A person’s living space has a significant effect on their quality of life. The ability to exclude insects will greatly reduce certain diseases. Thermal insulation can increase comfort and often reduce energy consumption. Water and sewage piping and fixtures increase sanitation and decrease disease. House styles are as varied as cultures, and living spaces cannot and should not be standardized worldwide. However, building supplies and home systems (e.g. power, plumbing) require less diversity, and useful components may be built from predesigned plans. In many areas of the world, something as simple as a water filter or a mosquito net can save many lives. Such small, simple products would cost almost nothing to produce. In areas that already use rectilinear apartment construction, including most inner cities, double-layer, vacuum-insulated wall panels can greatly decrease noise transmission between adjacent living spaces as well as providing excellent thermal insulation. Living space reform cannot be approached as a single problem with an easy solution, but the worst problems can easily be addressed piecemeal. |
| Computers will be cheap enough for everyone. | Molecular manufacturing can create computer logic gates a few nanometers on a side, and efficient enough to be stacked in 3D. An entire supercomputer can fit into a cubic millimeter, and cost a small fraction of a cent. With actuators smaller than a bacterium, a thin, high-resolution computer display will be easy (and cheap) to build. With GHz mechanical frequencies, a mostly-mechanical device can sense and produce radio waves. Thus computation, communication, and display are all feasible with pure diamondoid technology. Computers, PDAs, and cell phones can be cheap enough for even the poorest people on earth to own one, and contain more than enough processing capability for a voice interface for illiterate people. Distributed networking hardware can likewise be very cheap, and distributed networking software, though not trivial, is already being developed. The whole world could get “wired” within a year. |
| Nanotech can help the environment. | Environmental degradation is a serious problem with many sources and causes. One of the biggest causes is farming. Greenhouses can greatly reduce water use, land use, runoff, and topsoil loss. Mining is another serious problem. When most structure and function can be built out of carbon and hydrogen, there will be far less use for minerals, and mining operations can be mostly shut down. Manufacturing technologies that pollute can also be scaled back. In general, improved technology allows operations that pollute to be more compact and contained, and cheap manufacturing allows improvements to be deployed rapidly at low cost. Storable solar energy will reduce ash, soot, hydrocarbon, NOx, and CO2 emissions, as well as oil spills. In most cases, there will be strong economic incentives to adopt newer, more efficient technologies as rapidly as possible. Even in areas that currently do not have a technological infrastructure, self-contained molecular manufacturing will allow the rapid deployment of environment-friendly technology. |
| Improved medicine can be widely available. (MORE) | Molecular manufacturing will impact the practice of medicine in many ways. Medicine is highly complex, so it will take some time for the full benefits to be achieved, but many benefits will occur almost immediately. The tools of medicine will become cheaper and more powerful. Research and diagnosis will be far more efficient, allowing rapid response to new diseases, including engineered diseases. Small, cheap, numerous sensors, computers, and other implantable devices may allow continuous health monitoring and semi-automated treatment. Several new kinds of treatment will become possible. As the practice of medicine becomes cheaper and less uncertain, it can become available to more people. |
| Removing causes of distress may reduce social unrest. | Much social unrest can be traced directly to material poverty, ill health, and ignorance. Molecular manufacturing can eliminate material poverty—at least by today’s standards; post-MM standards may be considerably higher. Products of molecular manufacturing can greatly improve health by eliminating conditions that cause disease, including poor sanitation, insects, and malnutrition. Widespread availability of computers and communication devices can provide exposure to other cultures and diverse points of view, and create an understanding of a broader social context in which to evaluate actions and beliefs. (Unfortunately, mass communication also gives demagogues a wider audience, which may undo some of this benefit.) MM certainly will not cure or prevent social unrest, but it will remove many tangible causes of distress. |
Risks and Benefits of Nanoscale Technology
As implied in “Introduction to Nanoscale Technology” this collection of technologies can benefit us in many ways, including better health, faster computers, and greater awareness of our environment. In some cases, nanoscale technologies will provide only an incremental improvement over existing technologies. But in other cases, they can open the door to new techniques, products, and even fields. Materials will become stronger; sensors will become cheaper, more sensitive, and detect a broader range of phenomena; computers will become faster and more efficient; medicine will improve in many ways.
Nanoscale technology does not generally create unfamiliar types of risk. As today, materials may or may not be toxic; products may or may not be dangerous; a few applications may raise ethical issues.
Nanoparticle toxicity has become a significant issue. Whether made of new materials or smaller versions of existing materials, nanoparticles may have surprising properties. This has led to the worry (sometimes exaggerated for effect, but sometimes confirmed by experiment) that the medical or environmental effect of nanoparticles may not be predictable. Some groups, such as ETC, have called for banning nanoparticles even for research purposes until more is known about them.
