Worldwide Horizon Scanning

Today I had a meeting with a young man from Denmark, a PhD student currently working as an independent scholar in Washington, D.C. on regulation of nanotechnology at the Woodrow Wilson International Center for Scholars. He did a two-hour interview with me using a method called "MultiCriteria Mapping." This approach, developed by Professor Andrew Stirling at the University of Sussex (UK), provides "a structured way to explore which criteria different stakeholders use when they compare different policy options." After about two dozen interviews are completed, they will be analyzed and compiled for publication in a peer-reviewed journal. As soon as I receive the overall results, I will pass them on to you.

In other news, I had my second meeting in the last ten months with a delegation from Singapore's Centre of Excellence for National Security. That small but wealthy South Asian country is making a concerted effort to stay ahead of the curve, if that is possible, in understanding and preparing for emerging risks. In March, 2007, they held a symposium on International Risk Assessment & Horizon Scanning. I received a report from the symposium that contains brief overviews of each presentation. You can download a copy here [PDF].

It seems clear that people around the world are becoming more and more aware of the rapid acceleration in technology and the revolutionary upheavals that may await society as a result. It's rewarding to see the increased interest in CRN's work.

Mike Treder

Tags: nanotechnology nanotech nano science technology ethics weblog blog

Nano Knowledge Cluster

The Canadian Institute for Environmental Law and Policy (CIELAP) is an independent, not-for-profit research and education organization whose mission is to provide leadership in the research and development of environmental law and policy that promotes the public interest and sustainability.

On March 16, 2007, CIELAP gathered members from a cross-section of perspectives, including government, industry, non-profits, and academics, to discuss how to move towards an appropriate policy framework for Nanotechnology. [Note: CRN was invited to participate, but due to schedule conflicts we were unable to attend.] Out of the discussions CIELAP prepared its Discussion Paper on a Policy Framework for Nanotechnology.

Susan Holtz, Senior Policy Analyst and author of the discussion paper, will use the May Knowledge Cluster Meeting to discuss the framework and seek input from participants.

Since December 2005 CIELAP has been holding knowledge cluster meetings to bring together people who are interested in areas of our research. People who come to these meetings have the opportunity to hear about our research, give input, discuss how CIELAP can address this issue, and offer help and expertise. This help may include brainstorming ideas for new research and funding sources, reviewing or helping with research for a report or funding proposal, referring us to contacts or other information sources, or taking part in any other stage of the research process.

Everyone is invited to these meetings. In fact, we are seeking individuals with a variety of knowledges: scientific and technical knowledge, knowledge about Canadian and provincial law, politics, history, institutions, and civil society, knowledge about sustainable development values, communicating and presenting ideas and information, and the kind of processes that can move sustainability forward, and knowledge about being a citizen facing these issues.

If you would like to attend this meeting, you are asked to get in touch with Carolyn Webb, Communications Officer, via email or phone (416-923-3529 ext. 26).

Tags: nanotechnology nanotech nano science technology ethics weblog blog

"Leave Me Alone"

How many emails do you get every day? How much of your working day, or your leisure time, is spent dealing with email -- sorting it, deleting it, answering it, or putting it off until later?

For some people, it's gotten to be just too much.

Last month, venture capitalist Fred Wilson drew a lot of attention on the Internet when he declared a 21st century kind of bankruptcy. In a posting on his blog about technology, Wilson announced he was giving up on responding to all the e-mail piled up in his inbox.

"I am so far behind on e-mail that I am declaring bankruptcy," he wrote. "If you've sent me an e-mail (and you aren't my wife, partner, or colleague), you might want to send it again. I am starting over."

College professors have done the same thing, and a Silicon Valley chief executive followed Wilson's example the next day...

Those declaring bankruptcy are swearing off e-mail entirely or, more commonly, deleting all old messages and starting fresh.

So, is email making your life easier and your work work more efficient? Or is it just the opposite?

E-mail overload gives many workers the sense that their work is never done, said senior analyst David Ferris, whose firm, Ferris Research, said there were 6 trillion business e-mails sent in 2006. "A lot of people like the feeling that they have everything done at the end of the day," he said. "They can't have it anymore."

So some say they're moving back to the telephone as their preferred means of communication.

"From here on out I am going back to voice communication as my primary mechanism for interacting with people," wrote Jeff Nolan, chief executive of the business software company Teqlo, in his blog announcing his e-mail boycott.

These excerpts are from a Washington Post article titled E-Mail Reply to All: 'Leave Me Alone'. Similar observations have been made about the expected transition to 'paperless' offices promised by email proponents. We all know that never happened.

It might make you wonder if the touted benefits of molecular manufacturing will really be as good as they sound. It could be that not everyone will want to have a desktop nanofactory, or if they do, they'll find out that it's more trouble than it's worth. Is that even remotely possible? Or am I just being extra curmudgeonly today?

Mike Treder

Tags: nanotechnology nanotech nano science technology ethics weblog blog

A False Dilemma?

If you read CRN's Overview of Current Findings, you'll notice that at the bottom of each page is a section we call "Devil's Advocate." It's where we address some of the concerns and complaints that people have about our work; the honest disagreements about how the complex issues of responsible nanotechnology should be approached.

Recently we received a message from Noah Ennis, who offered the following critique of our page on The Need for Early Development:

Very interesting series of articles. I wonder, though, if "millions of people will die each year nanotechnology isn't developed" is not a false dilemma. After all, the choice is not strictly between developing nanotechnology and letting millions in the third world perish. The choice is between those two extremes and the middle ground of alleviating poverty through existing technologies -- for example, vaccines and mosquito nets -- which are already well within the West's technological and economic capabilities to produce in large quantities. The reason they don't is not economic at all, but political.

The conclusions drawn by CRN about MNT point to far more powerful intellectual property protections, as well as centralized control of the manufacturing, which seem to make the situation worse, not better. So although MNT has a huge amount to offer for mitigating the effects of poverty and developing third world infrastructure, posing its development as a moral imperative is somewhat of a red herring when there are alternatives within our means that are subject to the same imperative without any of the relevant moral risks. There are many superlative reasons for advocating MNT, but the moral implication that failure to do so costs X many lives, inasmuch as MNT is a technological instead of political solution, strikes me as misleading.

Here is how we responded:

Thanks, Noah. Your point is well taken. Millions of people around the world are suffering and dying needlessly today, not because we lack basic technologies that could help them, but because we lack political will to implement basic solutions. A large part of CRN's work is aimed at understanding these political mechanisms and the underlying social systems that drive them. We agree that creating a powerful new technology, like MNT, is only half the battle -- or maybe much less than half. The real challenge is in finding effective ways to guide the development and proliferation of the technology so that the most beneficial outcomes can be achieved, while the greatest risks can be averted. We've said all along that it won't be easy, and that's why we urge responsible government agencies, educational institutions, concerned businesses, and civil society groups to adopt some or all of CRN's Thirty Studies as an important first step toward clarifying the many issues involved.

We encourage anyone who reads our material and has a question or concern to contact us.

Tags: nanotechnology nanotech nano science technology ethics weblog blog

Looking for a Miracle

Not Necessarily Relevant Quote of the Week:

For some reason or other man looks for the miracle, and to accomplish it he will wade through blood. He will debauch himself with ideas, he will reduce himself to a shadow if for only one second of his life he can close his eyes to the hideousness of reality. Everything is endured -- disgrace, humiliation, poverty, war, crime, ennui -- in the belief that overnight something will occur, a miracle, which will render life tolerable.

— Henry Miller, in Tropic of Cancer

Tag: quotes

Molecular Manufacturing, NASA-Style

ABOVE: The computer-controlled desktop nanofactory (top figure) uses nanoscale machinery (lower right) to manufacture a molecularly precise 3-D product — a high performance water filter — out of nanoblocks made using bottom-up techniques, in this case synthesized from 2-layer silsesquioxane deriviatives (lower left). This near-future image envisions someone working on the surface of the moon.
CLICK IMAGE TO ENLARGE

In May, 2005, Chris Phoenix, CRN's Director of Research, working in cooperation with Tihamer Toth-Fejel, an engineer employed by General Dynamics, presented a commissioned report to NASA's Institute for Advanced Concepts, titled "Large-Product General-Purpose Design and Manufacturing Using Nanoscale Modules."

The goal of molecular manufacturing is to build engineerable high-performance products of all sizes, rapidly and inexpensively, with nanoscale features and atomic precision. Molecular manufacturing is the only branch of nanotechnology that intends to combine kilogram-scale products, atomic precision, and engineered programmable structure at all scales. It is no coincidence that molecular manufacturing has gone far beyond other branches of nanotechnology in investigating productive nanosystems, because high-performance nanoscale manufacturing systems are the only way that these goals can be achieved. Building such a product appears to require direct computer control of very small operations. In other words, it needs programmable manufacturing systems capable of acting at the nanoscale.

The core of this project is planar assembly: the construction of products by deposition of functional blocks one layer at a time. Planar assembly is a new development in molecular manufacturing theory. It is based on the realization that sub-micron nano-featured blocks are quite convenient for product design as well as manipulation within the nanofactory construction components, and can be deposited quite quickly due to favorable scaling laws. The development of planar assembly theory, combined with recent advances in molecular fabrication and synthesis, indicate that it may be time to start a targeted program to develop molecular manufacturing.

You can download a free PDF of this paper from CRN's website.

Tags: nanotechnology nanotech nano science technology ethics weblog blog

What is a human?

So, in addition to getting your nanotech biomed implants, which we discussed yesterday, you may want to consider additional enhancements to extend your sensory perception. Wired has an fascinating article called "Mixed Feelings":

See with your tongue. Navigate with your skin. Fly by the seat of your pants (literally). How researchers can tap the plasticity of the brain to hack our 5 senses — and build a few new ones.

Direction isn't something humans can detect innately. Some birds can, of course, and for them it's no less important than taste or smell are for us. In fact, lots of animals have cool, "extra" senses. Sunfish see polarized light. Loggerhead turtles feel Earth's magnetic field. Bonnethead sharks detect subtle changes (less than a nanovolt) in small electrical fields. And other critters have heightened versions of familiar senses — bats hear frequencies outside our auditory range, and some insects see ultraviolet light.

We humans get just the five. But why? Can our senses be modified? Expanded? Given the right prosthetics, could we feel electromagnetic fields or hear ultrasound? The answers to these questions, according to researchers at a handful of labs around the world, appear to be yes...

READ THE REST.

If you're interested in a book-length treatment of these ideas and many others, Richard Clarke's new novel, Breakpoint, looks like a must-read:

Former counterterrorism czar Richard Clarke's BREAKPOINT novel, set in the year 2012, is based on emerging technologies. "Globegrid," a high-speed global network, links supercomputers worldwide. Combined with advanced AI software, it promises to reverse-engineer the brain, revolutionize genomics, enable medical breakthroughs, develop advanced human-machine interfaces, and allow for genetic alterations and even uploading consciousness. But it spurs a terrorist-fundamentalist Luddite backlash against transhumanists, as hackers take down the power grid, and destroy vital international data and telecom links, communications satellites, and biotech firms.

Here is what Clarke says about his book:

Breakpoint, set in 2012, is meant to be predictive, at least about technology. It may read to some like science fiction, but it is based on emerging technologies that are the subject of research today. Scientists and engineers differ in their views about when the research will result in deployed technology, but their differences are most often a discussion of “when,” not “if.”

This novel is intended to project you a few years ahead, to start readers thinking now about the political, social, and economic changes that technology is about to create. Those changes could be wrenching, creating tensions in our society. A woman’s right to choose, the teaching of evolution, and stem-cell research have already created social and political discord in the United States. The coming technological events may make these current controversies seem like a practice round, a warm-up. For the next debate may be about “what is a human”: Should humans change the species with human-machine interfaces and genetic alterations?

Future studies expert Alvin Toffler said something similar a few years ago:

The biggest question facing the 21st century can be stated in a few words: What does it mean to be 'human?' The answer to that question will affect our most basic values and moral codes. And it may lead to an intensification of religious and moral conflict across the planet.

Mike Treder

Tags: nanotechnology nanotech nano science technology ethics weblog blog

Implanted Medical Computers

Not in a flying car, but in biomedical implants, the future is racing toward us. It looks less like The Jetsons and more like Holy Fire -- but it's a near-future that could only be viewed as science fiction just a few years ago.

Researchers at Harvard University and Princeton University have made a crucial step toward building biological computers, tiny implantable devices that can monitor the activities and characteristics of human cells. The information provided by these "molecular doctors," constructed entirely of DNA, RNA, and proteins, could eventually revolutionize medicine by directing therapies only to diseased cells or tissues.

The results will be published this week in the journal Nature Biotechnology.

"Each human cell already has all of the tools required to build these biocomputers on its own," says Harvard's Yaakov (Kobi) Benenson, a Bauer Fellow in the Faculty of Arts and Sciences' Center for Systems Biology. "All that must be provided is a genetic blueprint of the machine and our own biology will do the rest. Your cells will literally build these biocomputers for you."

And taking those ideas up a level or two, with a little help from molecular manufacturing, we have the nanotech dermal display:

In his book Nanomedicine, Volume I: Basic Capabilities, Robert A. Freitas Jr. describes (on page 204) a "programmable dermal display" in which a population of about 3 billion display pixel robots would be permanently implanted a fraction of a mm under the surface of the skin, covering a rectangle 6 cm x 5 cm on the back of the hand. Photons emitted by these pixel bots would produce an image on the surface of the skin. This pixelbot array could be programmed to form any of many thousands of displays. Each display would be capable of two functions: (1) presenting to the user data received from the large population of medical bots that roam the user's body; (2) conveying instructions from the user to that same large population of bots. The display could be activated or deactivated by finger tapping on the skin.

That's Seattle-based designer Gina Miller (aka Nanogirl) who worked with Freitas to develop an animation of the nanotech dermal display, which you can see here.

Mike Treder

Tags: nanotechnology nanotech nano science technology ethics weblog blog

Geoengineering Reconsidered

We all know that the Earth's climate is heating up:

Now that most scientists agree human activity is causing Earth to warm, the central debate has shifted to whether climate change is progressing so rapidly that, within decades, humans may be helpless to slow or reverse the trend. . . The debate has been intensifying because Earth is warming much faster than some researchers had predicted.

Yes, it seems our planet is warming faster now than had been predicted:

Carbon dioxide emissions from fossil fuels – the principal driver of climate change – have accelerated globally at a far greater rate than expected over recent years, according to a paper published this week in the Proceedings of the National Academy of Sciences.

Scientific American says:

Global warming is occurring faster than predicted because rapid economic growth has resulted in higher than expected greenhouse gas emissions since 2000. . . Emissions from burning fossil fuels have increased about 3 percent a year since 2000, up from 1 percent a year during the 1990s, said Australia's peak scientific body, the Commonwealth Scientific and Industrial Research Organization (CSIRO).

"It means that climate change is occurring faster than has been predicted by most of the studies done through the 1990s and into the early 2000s," said CSIRO scientist Mike Raupach.

So, what can be done about it? Some scientists are proposing that geoengineering, or re-terraforming, if you will, should be considered seriously:

Much of the climate community still views the idea with deep suspicion or outright hostility. Geoengineering, many say, is a way to feed society's addiction to fossil fuels. "It's like a junkie figuring out new ways of stealing from his children," says Meinrat Andreae, an atmospheric scientist at the Max Planck Institute for Chemistry in Mainz, Germany.

But in the past year the idea has begun to re-emerge, and it now seems to be making up for lost time. In particular, the idea of blocking some of the Sun's light before it gets to the Earth — sometimes euphemistically referred to as 'radiation management' — is receiving more attention now than ever before, with new ideas about how, why and when such an approach might be taken. The most recent IPCC report, released last week, scoffs at such notions — but underlines the need for drastic approaches to stave off the effects of rising planetary temperatures. And in the context of the drastic, curiosity about geoengineering looks likely to grow.

"It's a natural question to ask," says Michael MacCracken, chief scientist for the Climate Institute in Washington DC. "If we can do something inadvertently, can we do something deliberate to counter it?"

One reason such grandiose ideas are being reevaluated now is because climate change appears to be accelerating (as noted above) and because negative impacts, some catastrophic, could start occurring sooner and more frequently than anyone anticipated.

Another reason is because science itself is accelerating, which means new technological tools for planetary engineering soon may become available. One of those tools, of course, is molecular manufacturing:

If the technological capabilities of molecular manufacturing are used effectively, disastrous climate change could be stopped in its tracks and reversed. A combination of global sensor arrays, massive computational resources, and large-area sunlight deflectors could allow climate to be understood and manipulated.

But if unstable climate, and/or unstable global economy, and/or unstable fossil fuel supplies, and/or institutional resistance to molecular manufacturing, conspire to halt its development before general-purpose exponential manufacturing is achieved, we may lose our best hope to solve the problem.

Or, if the technology is developed but is administered poorly (perhaps because of government-imposed failures of scientific accountability), then the problem is unlikely to be solved effectively.

It's not just a matter, then, of having powerful tools available. Understanding the impacts of our efforts to control a dynamic, complex system may be exceedingly difficult:

The environment could be saved or destroyed; we'll have a lot more of a choice than we do today, and a lot more information on which to base our choices. The phrase "planet-scale engineering" is not an exaggeration. Today we do planet-scale engineering in decades, except it's not really planned; we will be able to do it deliberately, in months.

We agree with CRN Global Futures Strategist Jamais Cascio, when he says:

Should geoengineering be required, it should be done as carefully and as reversibly as possible. More research into geoengineering is especially important in order to know what not to do.

If climate disaster hits faster and harder than anticipated, desperate people will try desperate measures, including geoengineering. We need to be able to identify the choices that won't just make things worse.

Mike Treder

Tags: nanotechnology nanotech nano science technology ethics weblog blog

Saving Human Knowledge

Let's say you want to pass along some really important information to future generations. What's the best way to insure that your message will survive for, say, 500 or 1000 years? CRN blog reader Tom Mazanec has an idea for something he calls "Permapaper."

Permapaper is a matrix of fullerene fibers, integral with the binding of the book of which they are a part. The fibers are cladded with a tightly coiled sheath of sapphire in various colors to give the printing and illustrations. The fullerene provides the tensile strength to make permapaper virtually tearproof, and the sapphire sheath is fireproof at chemical combustion temperatures, requiring at least an electric arc furnace to destroy. It is also resistant to most corrosive chemicals. The permapaper does not absorb fluids, so it is quite waterproof and stainproof. The hollow fullerene fibers lower the density to the point that a book of permapaper will float on water and not sink to the bottom.

Tom says this approach might be used, post-nanofactory, by bibliophiles or survivalists who wish their books to "last the ages" and want something that will survive the vicissitudes of time and chance better than paper or plastic.

So bring on your famines, fires, floods, wars, and plagues -- we've got permapaper!

Mike Treder

Tags: nanotechnology nanotech nano science technology ethics weblog blog