Nanotechnology
For
the materials science journal, see Nanotechnology
Part
of a series of articles on
|
Nanotechnology
|
·
History
·
Organizations
·
Popular culture
·
Outline
|
Impact and applications
|
·
Nanomedicine
·
Green
nanotechnology
·
Regulation
|
Nanomaterials
|
·
Fullerenes
·
Carbon nanotubes
·
Nanoparticles
|
Molecular
self-assembly
|
·
Self-assembled monolayer
·
Supramolecular
assembly
·
DNA
nanotechnology
|
Nanoelectronics
|
·
Molecular scale electronics
·
Nanolithography
|
Scanning probe microscopy
|
·
Atomic
force microscopy
·
Scanning tunneling microscope
|
Molecular nanotechnology
|
·
Molecular
assembler
·
Nanorobotics
·
Mechanosynthesis
|
·
v
·
t
·
e
|
Nanotechnology (sometimes
shortened to "nanotech") is the manipulation of matter on
an atomicand molecular scale. The
earliest, widespread description of nanotechnology[1][2] referred to
the particular technological goal of precisely manipulating atoms and molecules
for fabrication of macroscale products, also now referred to as molecular
nanotechnology. A more generalized description of nanotechnology was
subsequently established by the National Nanotechnology Initiative, which defines
nanotechnology as the manipulation of matter with at least one dimension sized
from 1 to 100 nanometers.
This definition reflects the fact that quantum mechanical effects
are important at this quantum-realm scale,
and so the definition shifted from a particular technological goal to a
research category inclusive of all types of research and technologies that deal
with the special properties of matter that occur below the given size
threshold. It is therefore common to see the plural form "nanotechnologies"
as well as "nanoscale technologies" to refer to the broad range of
research and applications whose common trait is size. Because of the variety of
potential applications (including industrial and military), governments have
invested billions of dollars in nanotechnology research. Through its National
Nanotechnology Initiative, the USA has invested 3.7 billion dollars. The
European Union has invested 1.2 billion and Japan 750 million dollars.
[3]
[3]
Nanotechnology as
defined by size is naturally very broad, including fields of science as diverse
assurface science, organic chemistry, molecular biology, semiconductor
physics, microfabrication,
etc.[4] The
associated research and applications are equally diverse, ranging from
extensions of conventional device
physics to completely new approaches based upon molecular
self-assembly, from developing new materials with
dimensions on the nanoscale to direct
control of matter on the atomic scale.
Scientists currently
debate the future implications of nanotechnology. Nanotechnology may be able to
create many new materials and devices with a vast range of applications, such as in medicine,electronics, biomaterials and
energy production. On the other hand, nanotechnology raises many of the same
issues as any new technology, including concerns about the toxicity and
environmental impact of nanomaterials,[5] and their
potential effects on global economics, as well as speculation about
various doomsday scenarios. These
concerns have led to a debate among advocacy groups and governments on whether
special regulation of nanotechnology is warranted.
Contents
[hide]
·
1 Origins
·
2 Fundamental concepts
o 2.1 Larger to smaller: a materials perspective
o 2.2 Simple to complex: a molecular perspective
o 2.3 Molecular nanotechnology: a long-term view
·
3 Current research
o 3.1 Nanomaterials
o 3.2 Bottom-up approaches
o 3.3 Top-down approaches
o 3.4 Functional approaches
o 3.5 Biomimetic approaches
o 3.6 Speculative
·
4 Tools and techniques
·
5 Applications
·
6 Implications
o 6.1 Health and environmental concerns
·
7 Regulation
·
8 See also
·
9 References
·
10 External links
|
Origins
Main
article: History
of nanotechnology
The concepts that seeded
nanotechnology were first discussed in 1959 by renowned physicist Richard Feynman in his
talk There's Plenty of Room at the Bottom, in
which he described the possibility of synthesis via direct manipulation of
atoms. The term "nano-technology" was first used by Norio Taniguchi in
1974, though it was not widely known.
Inspired by Feynman's
concepts, K. Eric
Drexler independently used the term "nanotechnology"
in his 1986 book Engines
of Creation: The Coming Era of Nanotechnology, which proposed
the idea of a nanoscale "assembler" which would be able to build a
copy of itself and of other items of arbitrary complexity with atomic control.
Also in 1986, Drexler co-founded The
Foresight Institute (with which he is no longer affiliated) to
help increase public awareness and understanding of nanotechnology concepts and
implications.
For example, the
invention of the scanning tunneling microscope in 1981 provided
unprecedented visualization of individual atoms and bonds, and was successfully
used to manipulate individual atoms in 1989. The microscope's developers Gerd Binnig and Heinrich Rohrerat IBM Zurich Research Laboratory received a Nobel
Prize in Physics in 1986.[6][7] Binnig, Quate and Gerber also
invented the analogousatomic
force microscope that year.

Buckminsterfullerene
C60, also known as the buckyball, is a
representative member of thecarbon
structures known asfullerenes. Members of the
fullerene family are a major subject of research falling under the
nanotechnology umbrella.
Fullerenes were
discovered in 1985 by Harry Kroto, Richard Smalley, and Robert Curl, who together
won the 1996 Nobel
Prize in Chemistry.[8][9] C60 was
not initially described as nanotechnology; the term was used regarding
subsequent work with related graphene tubes
(called carbon
nanotubes and sometimes called Bucky tubes) which suggested potential
applications for nanoscale electronics and devices.
In the early 2000s, the
field garnered increased scientific, political, and commercial attention that
led to both controversy and progress. Controversies emerged regarding the
definitions and potential implications of nanotechnologies, exemplified by
the Royal
Society's report on nanotechnology.[10]Challenges were
raised regarding the feasibility of applications envisioned by advocates of
molecular nanotechnology, which culminated in a public debate between Drexler
and Smalley in 2001 and 2003.[11]
Meanwhile,
commercialization of products based on advancements in nanoscale technologies
began emerging. These products are limited to bulk applications of nanomaterials and do
not involve atomic control of matter. Some examples include the Silver Nano platform
for using silver
nanoparticles as an antibacterial agent, nanoparticle-based
transparent sunscreens, and carbon nanotubes for
stain-resistant textiles.[12][13]
Governments moved to
promote and fund
research into nanotechnology, beginning in the U.S. with theNational Nanotechnology Initiative, which formalized a
size-based definition of nanotechnology and established funding for research on
the nanoscale.
By the mid-2000’s new
and serious scientific attention began to flourish. Projects emerged to produce
nanotechnology roadmaps[14][15]which center on
atomically precise manipulation of matter and discuss existing and projected
capabilities, goals, and applications.
Fundamental concepts
Nanotechnology is the
engineering of functional systems at the molecular scale. This covers both
current work and concepts that are more advanced. In its original sense,
nanotechnology refers to the projected ability to construct items from the
bottom up, using techniques and tools being developed today to make complete,
high performance products.
One nanometer (nm) is one
billionth, or 10−9, of a meter. By comparison, typical
carbon-carbon bond lengths,
or the spacing between these atoms in
a molecule, are in the
range 0.12–0.15 nm, and a DNA double-helix
has a diameter around 2 nm. On the other hand, the smallest cellular life-forms,
the bacteria of the genus Mycoplasma,
are around 200 nm in length. By convention, nanotechnology is taken as the
scale range 1 to 100 nm following the definition used by the National
Nanotechnology Initiative in the US. The lower limit is set by the size of
atoms (hydrogen has the smallest atoms, which are approximately a quarter of a
nm diameter) since nanotechnology must build its devices from atoms and
molecules. The upper limit is more or less arbitrary but is around the size
that phenomena not observed in larger structures start to become apparent and
can be made use of in the nano device.[16] These new
phenomena make nanotechnology distinct from devices which are merely
miniaturised versions of an equivalent macroscopic device;
such devices are on a larger scale and come under the description of microtechnology.[17]
To put that scale in
another context, the comparative size of a nanometer to a meter is the same as
that of a marble to the size of the earth.[18] Or another
way of putting it: a nanometer is the amount an average man's beard grows in
the time it takes him to raise the razor to his face.[18]
Two main approaches are
used in nanotechnology. In the "bottom-up" approach, materials and
devices are built from molecular components which assemble themselves chemically
by principles of molecular
recognition. In the "top-down" approach, nano-objects are
constructed from larger entities without atomic-level control.[19]
Areas of physics such
as nanoelectronics, nanomechanics, nanophotonics and nanoionics have
evolved during the last few decades to provide a basic scientific foundation of
nanotechnology.
Larger to smaller: a materials perspective

Image
of reconstruction on
a cleanGold(100) surface, as visualized
usingscanning tunneling microscopy. The positions of the
individual atoms composing the surface are visible.
Main
article: Nanomaterials
Several phenomena become
pronounced as the size of the system decreases. These includestatistical
mechanical effects, as well as quantum mechanical effects,
for example the “quantum size effect”
where the electronic properties of solids are altered with great reductions in
particle size. This effect does not come into play by going from macro to micro
dimensions. However, quantum effects can become significant when the nanometer
size range is reached, typically at distances of 100 nanometers or less, the
so-called quantum
realm. Additionally, a number of physical (mechanical, electrical,
optical, etc.) properties change when compared to macroscopic systems. One
example is the increase in surface area to volume ratio altering mechanical,
thermal and catalytic properties of materials. Diffusion and reactions at
nanoscale, nanostructures materials and nanodevices with fast ion transport are
generally referred to nanoionics. Mechanical properties of
nanosystems are of interest in the nanomechanics research. The catalytic
activity of nanomaterials also opens potential risks in their interaction
with biomaterials.
Materials reduced to the
nanoscale can show different properties compared to what they exhibit on a
macroscale, enabling unique applications. For instance, opaque substances can
become transparent (copper); stable materials can turn combustible (aluminum);
insoluble materials may become soluble (gold). A material such as gold, which
is chemically inert at normal scales, can serve as a potent chemical catalyst at
nanoscales. Much of the fascination with nanotechnology stems from these
quantum and surface phenomena that matter exhibits at the nanoscale.[20]
Simple to complex: a molecular perspective
Main
article: Molecular
self-assembly
Modern synthetic
chemistry has reached the point where it is possible to prepare
small molecules to almost any structure. These methods are used today to
manufacture a wide variety of useful chemicals such as pharmaceuticals or commercial polymers. This ability
raises the question of extending this kind of control to the next-larger level,
seeking methods to assemble these single molecules intosupramolecular
assemblies consisting of many molecules arranged in a well
defined manner.
These approaches utilize
the concepts of molecular self-assembly and/or supramolecular
chemistry to automatically arrange themselves into some useful
conformation through a bottom-up approach.
The concept of molecular recognition is especially important: molecules can be
designed so that a specific configuration or arrangement is favored due
to non-covalent intermolecular
forces. The Watson–Crickbasepairing rules are
a direct result of this, as is the specificity of an enzyme being targeted to a
single substrate,
or the specific folding
of the protein itself. Thus, two or more components can be
designed to be complementary and mutually attractive so that they make a more
complex and useful whole.
Such bottom-up
approaches should be capable of producing devices in parallel and be much
cheaper than top-down methods, but could potentially be overwhelmed as the size
and complexity of the desired assembly increases. Most useful structures
require complex and thermodynamically unlikely arrangements of atoms.
Nevertheless, there are many examples of self-assembly based on molecular recognition
in biology, most notably
Watson–Crick basepairing and enzyme-substrate interactions. The challenge for
nanotechnology is whether these principles can be used to engineer new constructs
in addition to natural ones.
Molecular nanotechnology: a long-term view
Main
article: Molecular
nanotechnology
Molecular
nanotechnology, sometimes called molecular manufacturing, describes engineered
nanosystems (nanoscale machines) operating on the molecular scale. Molecular
nanotechnology is especially associated with the molecular
assembler, a machine that can produce a desired structure or device
atom-by-atom using the principles of mechanosynthesis.
Manufacturing in the context of productive
nanosystems is not related to, and should be clearly
distinguished from, the conventional technologies used to manufacture
nanomaterials such as carbon nanotubes and nanoparticles.
When the term
"nanotechnology" was independently coined and popularized by Eric Drexler (who at
the time was unaware of an earlier
usage by Norio Taniguchi) it referred to a future manufacturing
technology based on molecular machine systems.
The premise was that molecular scale biological analogies of traditional
machine components demonstrated molecular machines were possible: by the
countless examples found in biology, it is known that sophisticated, stochastically optimised
biological machines can be produced.
It is hoped that
developments in nanotechnology will make possible their construction by some other
means, perhaps using biomimeticprinciples.
However, Drexler and other researchers[21] have
proposed that advanced nanotechnology, although perhaps initially implemented
by biomimetic means, ultimately could be based on mechanical engineering
principles, namely, a manufacturing technology based on the mechanical
functionality of these components (such as gears, bearings, motors, and
structural members) that would enable programmable, positional assembly to
atomic specification.[22] The physics
and engineering performance of exemplar designs were analyzed in Drexler's
book Nanosystems.
In general it is very
difficult to assemble devices on the atomic scale, as all one has to position
atoms on other atoms of comparable size and stickiness. Another view, put forth
by Carlo Montemagno,[23] is that
future nanosystems will be hybrids of silicon technology and biological
molecular machines. Yet another view, put forward by the late Richard Smalley,
is that mechanosynthesis is impossible due to the difficulties in mechanically
manipulating individual molecules.
This led to an exchange
of letters in the ACS publication Chemical & Engineering News in 2003.[24] Though biology
clearly demonstrates that molecular machine systems are possible,
non-biological molecular machines are today only in their infancy. Leaders in
research on non-biological molecular machines are Dr. Alex Zettl and his
colleagues at Lawrence Berkeley Laboratories and UC Berkeley. They have
constructed at least three distinct molecular devices whose motion is
controlled from the desktop with changing voltage: a nanotubenanomotor, a molecular
actuator,[25] and a
nanoelectromechanical relaxation oscillator.[26] See nanotube
nanomotor for more examples.
An experiment indicating
that positional molecular assembly is possible was performed by Ho and Lee
at Cornell
University in 1999. They used a scanning tunneling microscope
to move an individual carbon monoxide molecule (CO) to an individual iron atom
(Fe) sitting on a flat silver crystal, and chemically bound the CO to the Fe by
applying a voltage.
Current research

Graphical
representation of a rotaxane,
useful as a molecular switch.

This
DNA tetrahedron[27] is an
artificiallydesigned nanostructure
of the type made in the field of DNA
nanotechnology. Each edge of the tetrahedron is a 20 base pair DNAdouble
helix, and each vertex is a three-arm junction.

This
device transfers energy from nano-thin layers of quantum wells to nanocrystalsabove them,
causing the nanocrystals to emit visible light.[28]
Nanomaterials
The nanomaterials field
includes subfields which develop or study materials having unique properties
arising from their nanoscale dimensions.[29]
·
Interface and colloid science has given rise to many
materials which may be useful in nanotechnology, such as carbon nanotubes and
other fullerenes, and various nanoparticles and nanorods. Nanomaterials
with fast ion transport are related also to nanoionics and nanoelectronics.
·
Nanoscale materials can also be used
for bulk applications; most present commercial applications of nanotechnology
are of this flavor.
·
Progress has been made in using these
materials for medical applications; seeNanomedicine.
·
Nanoscale materials are sometimes
used in solar cells which
combats the cost of traditional Silicon solar cells.
·
Development of applications
incorporating semiconductor nanoparticles to be
used in the next generation of products, such as display technology, lighting,
solar cells and biological imaging; see quantum dots.
Bottom-up approaches
These seek to arrange
smaller components into more complex assemblies.
·
DNA nanotechnology utilizes the
specificity of Watson–Crick basepairing to construct well-defined structures
out of DNA and other nucleic
acids.
·
Approaches from the field of
"classical" chemical synthesis (inorganic and organic synthesis) also aim
at designing molecules with well-defined shape (e.g. bis-peptides[30]).
·
More generally, molecular
self-assembly seeks to use concepts of supramolecular chemistry, and molecular
recognition in particular, to cause single-molecule components to automatically
arrange themselves into some useful conformation.
·
Atomic
force microscope tips can be used as a nanoscale "write
head" to deposit a chemical upon a surface in a desired pattern in a
process called dip
pen nanolithography. This technique fits into the larger subfield
of nanolithography.
Top-down approaches
These seek to create
smaller devices by using larger ones to direct their assembly.
·
Many technologies that descended
from conventional solid-state
silicon methods for fabricating microprocessors are
now capable of creating features smaller than 100 nm, falling under the
definition of nanotechnology. Giant
magnetoresistance-based hard drives already on the market fit this
description,[31] as do atomic
layer deposition (ALD) techniques. Peter Grünberg and Albert Fert received
the Nobel Prize in Physics in 2007 for their discovery of Giant
magnetoresistance and contributions to the field of spintronics.[32]
·
Solid-state techniques can also be
used to create devices known asnanoelectromechanical systems or NEMS, which are related
to microelectromechanical systems or MEMS.
·
Focused ion beams can
directly remove material, or even deposit material when suitable pre-cursor
gasses are applied at the same time. For example, this technique is used
routinely to create sub-100 nm sections of material for analysis in Transmission electron microscopy.
·
Atomic force microscope tips can be
used as a nanoscale "write head" to deposit a resist, which is then
followed by an etching process to remove material in a top-down method.
Functional approaches
These seek to develop
components of a desired functionality without regard to how they might be
assembled.
·
Molecular scale electronics seeks to develop molecules
with useful electronic properties. These could then be used as single-molecule
components in a nanoelectronic device.[33] For an
example see rotaxane.
·
Synthetic chemical methods can also
be used to create synthetic molecular motors, such as in a so-called nanocar.
Biomimetic approaches
·
Bionics or biomimicry seeks to
apply biological methods and systems found in nature, to the study and design
of engineering systems and modern technology. Biomineralization is
one example of the systems studied.
·
Bionanotechnology is
the use of biomolecules for
applications in nanotechnology, including use of viruses and lipid assemblies.[34][35]Nanocellulose is a
potential bulk-scale application.
Speculative
These subfields seek
to anticipate what
inventions nanotechnology might yield, or attempt to propose an agenda along
which inquiry might progress. These often take a big-picture view of
nanotechnology, with more emphasis on its societal implications than the
details of how such inventions could actually be created.
·
Molecular nanotechnology is a
proposed approach which involves manipulating single molecules in finely
controlled, deterministic ways. This is more theoretical than the other
subfields, and many of its proposed techniques are beyond current capabilities.
·
Nanorobotics centers
on self-sufficient machines of some functionality operating at the nanoscale.
There are hopes for applying nanorobots in medicine,[36][37][38] but it may
not be easy to do such a thing because of several drawbacks of such devices.[39]Nevertheless,
progress on innovative materials and methodologies has been demonstrated with
some patents granted about new nanomanufacturing devices for future commercial
applications, which also progressively helps in the development towards
nanorobots with the use of embedded nanobioelectronics concepts.[40][41]
·
Productive nanosystems are
"systems of nanosystems" which will be complex nanosystems that
produce atomically precise parts for other nanosystems, not necessarily using
novel nanoscale-emergent properties, but well-understood fundamentals of
manufacturing. Because of the discrete (i.e. atomic) nature of matter and the
possibility of exponential growth, this stage is seen as the basis of another
industrial revolution. Mihail Roco,
one of the architects of the USA's National Nanotechnology Initiative, has
proposed four states of nanotechnology that seem to parallel the technical
progress of the Industrial Revolution, progressing from passive nanostructures
to active nanodevices to complex nanomachines and
ultimately to productive nanosystems.[42]
·
Programmable
matter seeks to design materials whose properties can be
easily, reversibly and externally controlled though a fusion of information
science and materials science.
·
Due to the popularity and media
exposure of the term nanotechnology, the words picotechnology and femtotechnology have
been coined in analogy to it, although these are only used rarely and
informally.
Tools and techniques

Typical AFM setup.
A microfabricated cantilever with
a sharp tip is deflected by features on a sample surface, much like in a phonograph but on a
much smaller scale. Alaser beam reflects
off the backside of the cantilever into a set of photodetectors, allowing
the deflection to be measured and assembled into an image of the surface.
There are several
important modern developments. The atomic force microscope (AFM) and the Scanning Tunneling Microscope (STM) are two early
versions of scanning probes that launched nanotechnology. There are other types
ofscanning
probe microscopy. Although conceptually similar to the scanningconfocal
microscope developed by Marvin Minsky in 1961
and the scanning acoustic microscope (SAM) developed by Calvin Quate and
coworkers in the 1970s, newer scanning probe microscopes have much higher
resolution, since they are not limited by the wavelength of sound or light.
The tip of a scanning
probe can also be used to manipulate nanostructures (a process called positional
assembly). Feature-oriented
scanning methodology suggested by Rostislav Lapshin appears to
be a promising way to implement these nanomanipulations in automatic mode.[43][44] However,
this is still a slow process because of low scanning velocity of the
microscope.
Various techniques of
nanolithography such as optical
lithography, X-ray lithography dip
pen nanolithography, electron
beam lithography or nanoimprint
lithography were also developed. Lithography is a top-down
fabrication technique where a bulk material is reduced in size to nanoscale
pattern.
Another group of
nanotechnological techniques include those used for fabrication of nanotubes and nanowires, those used in semiconductor
fabrication such as deep ultraviolet lithography, electron beam lithography,
focused ion beam machining, nanoimprint lithography, atomic layer deposition,
and molecular vapor deposition, and further including molecular self-assembly
techniques such as those employing di-block copolymers. The precursors of these
techniques preceded the nanotech era, and are extensions in the development of
scientific advancements rather than techniques which were devised with the sole
purpose of creating nanotechnology and which were results of nanotechnology
research.
The top-down approach
anticipates nanodevices that must be built piece by piece in stages, much as
manufactured items are made. Scanning probe microscopy is an important
technique both for characterization and synthesis of nanomaterials. Atomic
force microscopes and scanning tunneling microscopes can be used to look at
surfaces and to move atoms around. By designing different tips for these
microscopes, they can be used for carving out structures on surfaces and to
help guide self-assembling structures. By using, for example, feature-oriented
scanning approach, atoms or molecules can be moved around on a surface with
scanning probe microscopy techniques.[43][44] At present,
it is expensive and time-consuming for mass production but very suitable for
laboratory experimentation.
In contrast, bottom-up
techniques build or grow larger structures atom by atom or molecule by
molecule. These techniques include chemical synthesis, self-assembly and
positional assembly. Dual polarisation interferometry is one tool suitable
for characterisation of self assembled thin films. Another variation of the
bottom-up approach is molecular
beam epitaxy or MBE. Researchers at Bell Telephone Laboratories like John R. Arthur. Alfred
Y. Cho, and Art C. Gossard developed and implemented MBE as a research tool in
the late 1960s and 1970s. Samples made by MBE were key to the discovery of the
fractional quantum Hall effect for which the 1998 Nobel Prize in Physics was
awarded. MBE allows scientists to lay down atomically precise layers of atoms
and, in the process, build up complex structures. Important for research on
semiconductors, MBE is also widely used to make samples and devices for the
newly emerging field of spintronics.
However, new therapeutic
products, based on responsive nanomaterials, such as the ultradeformable, stress-sensitive Transfersomevesicles, are
under development and already approved for human use in some countries.[citation
needed]
Applications

One of
the major applications of nanotechnology is in the area of nanoelectronics
with MOSFET's being made of
small nanowires ~10 nm in
length. Here is a simulation of such a nanowire.
Nanostructures
provide this surface withsuperhydrophobicity,
which lets water
droplets roll down the inclined plane.
Main
article: List of nanotechnology applications
As of August 21, 2008,
the Project on Emerging Nanotechnologies estimates
that over 800 manufacturer-identified nanotech products are publicly available,
with new ones hitting the market at a pace of 3–4 per week.[13] The project
lists all of the products in a publicly accessible online database. Most
applications are limited to the use of "first generation" passive
nanomaterials which includes titanium dioxide in sunscreen, cosmetics, surface
coatings,[45] and some
food products; Carbon allotropes used to produce gecko tape; silver in food
packaging, clothing, disinfectants and household appliances; zinc oxide in
sunscreens and cosmetics, surface coatings, paints and outdoor furniture
varnishes; and cerium oxide as a fuel catalyst.[12]
Further applications
allow tennis balls to
last longer, golf balls to
fly straighter, and evenbowling
balls to become more durable and have a harder surface. Trousers and socks have been infused with
nanotechnology so that they will last longer and keep people cool in the
summer. Bandages are being
infused with silver nanoparticles to heal cuts faster.[46] Cars are
being manufactured with nanomaterials so
they may need fewer metals and
less fuel to operate in the
future.[47] Video
game consoles and personal computers may
become cheaper, faster, and contain more memory thanks to nanotechnology.[48] Nanotechnology
may have the ability to make existing medical applications cheaper and easier
to use in places like thegeneral
practitioner's office and at home.[49]
The National Science Foundation (a major distributor for
nanotechnology research in the United States) funded researcher David Berube to
study the field of nanotechnology. His findings are published in the monograph
Nano-Hype: The Truth Behind the Nanotechnology Buzz. This study concludes that
much of what is sold as “nanotechnology” is in fact a recasting of
straightforward materials science, which is leading to a “nanotech industry
built solely on selling nanotubes, nanowires, and the like” which will “end up
with a few suppliers selling low margin products in huge volumes." Further
applications which require actual manipulation or arrangement of nanoscale
components await further research. Though technologies branded with the term
'nano' are sometimes little related to and fall far short of the most ambitious
and transformative technological goals of the sort in molecular manufacturing
proposals, the term still connotes such ideas. According to Berube, there may
be a danger that a "nano bubble" will form, or is forming already,
from the use of the term by scientists and entrepreneurs to garner funding,
regardless of interest in the transformative possibilities of more ambitious and
far-sighted work.[50]
Implications
Main
article: Implications of nanotechnology
An area of concern is
the effect that industrial-scale manufacturing and use of nanomaterials would
have on human health and the environment, as suggested by nanotoxicology research.
For these reasons, some groups advocate that nanotechnology be regulated by
governments. Others counter that overregulation would stifle scientific
research and the development of beneficial innovations. Public health research
agencies, such as the National Institute for Occupational
Safety and Health are actively conducting research on potential
health effects stemming from exposures to nanoparticles.[51][52]
Some nanoparticle
products may have unintended
consequences. Researchers have discovered that bacteriostatic silver
nanoparticles used in socks to reduce foot odor are being released in the wash.[53] These
particles are then flushed into the waste water stream and may destroy bacteria
which are critical components of natural ecosystems, farms, and waste treatment
processes.[54]
Public deliberations
on risk
perception in the US and UK carried out by the Center for
Nanotechnology in Society found that participants were more positive about
nanotechnologies for energy applications than for health applications, with
health applications raising moral and ethical dilemmas such as cost and
availability.[55]
Experts, including
director of the Woodrow Wilson Center's Project on Emerging Nanotechnologies
David Rejeski, have testified[56] that
successful commercialization depends on adequate oversight, risk research
strategy, and public engagement. Berkeley,
California is currently the only city in the United States to
regulate nanotechnology;[57] Cambridge,
Massachusetts in 2008 considered enacting a similar law,[58] but
ultimately rejected it.[59] Relevant
for both research on and application of nanotechnologies, the insurability of
nanotechnology is contested.[60] Without
state regulation of nanotechnology, the availability of private
insurance for potential damages is seen as necessary to ensure that burdens are
not socialised implicitly.
Health and environmental concerns
Main
articles: Health implications of nanotechnology and Environmental implications of nanotechnology
Researchers have found
that when rats breathed in nanoparticles, the particles settled in the brain
and lungs, which led to significant increases in biomarkers for inflammation
and stress response[61] and that
nanoparticles induce skin aging through oxidative stress in hairless mice.[62][63]
A two-year study at
UCLA's School of Public Health found lab mice consuming nano-titanium dioxide
showed DNA and chromosome damage to a degree "linked to all the big
killers of man, namely cancer, heart disease, neurological disease and
aging".[64]
A major study published
more recently in Nature
Nanotechnology suggests some forms of carbon nanotubes – a
poster child for the “nanotechnology revolution” – could be as harmful as asbestos if inhaled in
sufficient quantities. Anthony Seaton of the Institute of Occupational Medicine
in Edinburgh, Scotland, who contributed to the article on carbon nanotubes said
"We know that some of them probably have the potential to cause
mesothelioma. So those sorts of materials need to be handled very
carefully."[65] In the
absence of specific regulation forthcoming from governments, Paull and Lyons
(2008) have called for an exclusion of engineered nanoparticles in food.[66] A newspaper
article reports that workers in a paint factory developed serious lung disease
and nanoparticles were found in their lungs.[67]
Extremely small fibers,
so called nanofibers, can be as harmful for the lungs as asbestos is. This
scientists warn for in the publication "Toxicology Sciences"
after experiments with mice. Nanofibers are used in several areas and in
different products, in everything from aircraft wings to tennis rackets. In
experiments the scientists have seen how mice breathed nanofibers of silver. Fibers larger than5 micrometer were
capsuled in the lungs where they caused inflammations[68][69] (a
precursor for cancer[70] like mesothelioma).[68]
Regulation
Main
article: Regulation of nanotechnology
Calls for tighter
regulation of nanotechnology have occurred alongside a growing debate related
to the human health and safety risks of nanotechnology.[71] There is
significant debate about who is responsible for the regulation of
nanotechnology. Some regulatory agencies currently cover some nanotechnology
products and processes (to varying degrees) – by “bolting on” nanotechnology to
existing regulations – there are clear gaps in these regimes.[72] Davies
(2008) has proposed a regulatory road map describing steps to deal with these
shortcomings.[73]
Stakeholders concerned
by the lack of a regulatory framework to assess and control risks associated
with the release of nanoparticles and nanotubes have drawn parallels
with bovine spongiform encephalopathy ("mad cow"
disease), thalidomide, genetically modified food,[74] nuclear
energy, reproductive technologies, biotechnology, and asbestosis. Dr.
Andrew Maynard, chief science advisor to the Woodrow Wilson Center’s Project on
Emerging Nanotechnologies, concludes that there is insufficient funding for
human health and safety research, and as a result there is currently limited
understanding of the human health and safety risks associated with
nanotechnology.[75] As a
result, some academics have called for stricter application of
the precautionary principle, with delayed marketing approval, enhanced
labelling and additional safety data development requirements in relation to
certain forms of nanotechnology.[76]
The Royal Society report[10] identified
a risk of nanoparticles or nanotubes being released during disposal,
destruction and recycling, and recommended that “manufacturers of products that
fall under extended producer responsibility regimes such as end-of-life
regulations publish procedures outlining how these materials will be managed to
minimize possible human and environmental exposure” (p. xiii). Reflecting the
challenges for ensuring responsible life cycle regulation, the Institute
for Food and Agricultural Standards has proposed that standards for
nanotechnology research and development should be integrated across consumer,
worker and environmental standards. They also propose that NGOs and
other citizen groups play a meaningful role in the development of these standards.
The Center for
Nanotechnology in Society has found that people respond differently to
nanotechnologies based upon application – with participants in public
deliberations more positive about nanotechnologies for energy than health
applications – suggesting that any public calls for nano regulations may differ
by technology sector.[55]

No comments:
Post a Comment