“Feynman’s 1959 talk, entitled ‘There’s Plenty of Room at the Bottom’”, was delivered 50 years ago today, and the words I’ve quoted above are the first words in the first sentence of the first paper I wrote, almost 30 years ago, on what later became known as “nanotechnology”. Feynman read and discussed the paper with me before its publication, because it extended his ideas.
Richard Feynman’s work in quantum field theory forms part of the foundation of modern concepts of physics, at its deepest levels. “There’s Plenty of Room at the Bottom” was a comparatively casual effort — an after-dinner speech at a conference — yet in it he presented a bold and enduring vision of a technological journey leading toward the atomic scale and toward the ultimate boundaries set by physical law. The world has traveled far toward what Feynman saw, and has far still to go.
I’ll start here by saying more about the talk, then about the evolution of the concepts, and finally show how the talk and the concepts have been woven into the history of the rise of nanotechnology.
The road already traveled: Nanoscale miniaturization
Feynman proposed shrinking computing devices toward their physical limits, where “wires should be 10 or 100 atoms in diameter”. Samsung this month announced large-scale production of devices built with 30 nanometer technology, which is to say, with wires at Feynman’s 100-atom scale. When Feynman spoke, a single computer could fill a room.
The talk held much more than that: Feynman suggested that focused electron beams could write nanoscale features on a surface; this is now called “e-beam lithography”. He suggested that electron microscopes with less symmetric lenses could image atoms; this is the idea behind the new generation of aberration-corrected microscopes, and they do image atoms. He pointed to complex, active, nanoscale biological mechanisms as an inspiration for nanoscale technology; these have become the basis of what is called “biotechnology”, which has delivered what are in some ways the most advanced nanotechnologies developed to date.
The road ahead: Large-scale atomic precision
Beyond this, Feynman was the first to outline a world of technologies that would work and build at the ultimate, atomic scale. He viewed this world from a top-down perspective, as the ultimate frontier for miniaturization; I later described a bottom-up path to the same world, as the ultimate frontier for molecular assembly. The approach I suggested was rooted in the biological mechanisms that had inspired Feynman.
What had changed was the state of knowledge: Feynman saw an entry to the atomically precise world from the top down, by building smaller and smaller machines, and ultimately using these to build machines the smallest possible scale by “maneuvering things atom by atom”.
When I wrote, over 20 years later, machines had been found that were already at that scale, in biology — machines that already built structures with atomic precision, and that scientists were learning to program. I saw another entry to the world he had foreseen, a path from the bottom up that would harness molecular-scale machines to build new atomically precise components, and with them, atomically precise machines of increasing size, capability, and complexity.
I took the concepts much further of course, and in greater analytical depth. Feynman had given the famous talk, then (with an occasional revisit) turned to other concerns. I wrote a paper, a dissertation, and both a popular and a highly technical book, then turned to other things, and later got pulled back in again when I found that I had to explain the basics again [pdf].
A lot happened in that time.
The promise that launched the field of nanotechnology
There has been some controversy about the history of nanotechology, and a tendency to downplay, or even disparage, the idea that nanotechnology is deeply and legitimately linked to the idea of using nanoscale machines to build things by, as Feynman put it, “maneuvering things atom by atom”. I’d like to outline some of the history that shows the connections.
The initial excitement about nanotechnology was centered on large-scale atomically precise fabrication and the advanced technologies it could bring. As I discussed in a recent post, the term and this concept emerged together, in my 1986 book, and launched a wave of media coverage, scientific discussion, and general excitement. This wave merged with others, mixed with politics, and grew to support what became a multi-billion-dollar research initiative. The concept that created the excitement — identified with the idea of atom-by-atom control — was part of the package, all the way through.
Feynman’s vision of atomically precise fabrication was cited in a presidential address in January, 2000, at the inception of the program:
My budget supports a major new National Nanotechnology Initiative, worth $500 million. Caltech is no stranger to the idea of nanotechnology — the ability to manipulate matter at the atomic and molecular level. Over 40 years ago, Caltech’s own Richard Feynman asked, “What would happen if we could arrange the atoms one by one the way we want them?”
While Congress deliberated that summer, the soon-to-be-funded NNI published a document (“National Nanotechnology Initiative: The Initiative and Its Implementation Plan” [pdf]) describing what it aimed to do. The language in this document was very compatible with what Congress, the President, and the public had been promised: building things at the smallest possible scale by “maneuvering things atom by atom”. Here’s the beginning of the second section:
2. Definition of Nanotechnology
The essence of nanotechnology is the ability to work at the molecular level, atom by atom, to create large structures with fundamentally new molecular organization. [...] [but see later changes]
Section 3 reinforced this message by citing “There’s Plenty of Room at the Bottom” and Feynman’s “vision of exciting new discoveries if one could fabricate materials and devices at the atomic/molecular scale”
At that time, Richard Smalley was the most prominent scientific spokesman for the movement to create the NNI, and in congressional testimony that summer, he stated:
We are about to be able to build things that work on the smallest possible length scales, atom by atom, with the ultimate level of finesse. These little nano things and the technology that assembles and manipulates them, what we call nanotechnology, will, I am certain, revolutionize our industries and our lives….
[The] technology of our 20th century is fantastic, but it pales when compared to what will be possible when we learn to build things at the ultimate level of finesse, one atom at a time.
There is a clear connection between this and the concepts that Feynman and I had proposed. I an open letter to me, Smalley later wrote:
I was fascinated by your book “Engines of Creation” when I first read it in 1991. Reading it was the trigger event that started my own journey in nanotechnology
Readers exposed to science politics in the 2000–2005 time frame may find the above surprising, but I think it helps validates the strong claims that have been made for a direct conceptual and historical link between Feynman’s concepts and the growth and funding — though only small part of the scientific content — of the modern field of nanotechnology.
Looking forwardUnderstanding this background of ideas, and the institutional dynamics that have gone with them, can help us to understand where we are today — and what is more important, how to move forward to realize the promise that launched the field of nanotechnology.
The objectives that launched the field are powerful, yet in many ways quite different from the vast mythology that has grown up around them. I am persuaded that accomplishing these objectives, in their realistic and demythologized form, will provide solutions to problems on the largest scale, including climate change. Greater clarity and more effective pursuit of these objectives will reinvigorate the diverse field that nanotechnology has become, drawing ideas, enthusiasm, and support from new sources.
[updated 30 Dec]
See also:
- Part 1 — The promise that launched the field of nanotechnology
- Part 2 — Molecular Manufacturing: Where’s the progress?
- Part 3 — The Molecular Machine Path to Molecular Manufacturing (1)
- Part 4 — The Molecular Machine Path to Molecular Manufacturing (2)
Studies of advanced atomically precise fabrication:
- Roadmap for Atomically Precise Nanofabrication and Productive Nanosystems
- U.S. National Academies report on molecular manufacturing
- Nanosystems: Molecular Machinery, Manufacturing, and Computation,
and its precursor, my MIT dissertation:
“Molecular Machinery and Manufacturing with Applications to Computation” [pdf, 30 MB]