Nanotechnology involves manipulating matter at the atomic and molecular scales. Key tools in nanoscience include scanning probe microscopes like the scanning tunneling microscope and atomic force microscope, which can image surfaces at the atomic level. Potential applications of nanotechnology include improving medicine through more targeted drug delivery, enhancing energy storage and conversion, treating diseases, and addressing environmental problems like pollution. While nanotechnology holds promise, its health and environmental risks require further research and regulation to ensure its safe development and use.
2. Nano World
• the global market
leader for tips for
Scanning Probe
Microscopy and
Atomic Force
Microscopy.
• sphere of influence
of nanotechnology
3. Scanning probe microscopy (SPM)
• a branch of microscopy
that forms images of
surfaces using a
physical probe that
scans the specimen.
• founded in 1981, with
the invention of the
scanning tunneling
microscope, an
instrument for imaging
surfaces at the atomic
level.
4. Atomic Force Microscopy.
• is a type of scanning
probe microscopy
(SPM), with
demonstrated resolution
on the order of fractions
of a nanometer, more
than 1000 times better
than the optical
diffraction limit. The
information is gathered
by "feeling" or "touching"
the surface with a
mechanical probe.
5. Origin of Nanoscience
• in 1959 it was discussed by the 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.
• in 1960, Egyptian engineer Mohamed Atalla and
Korean engineer Dawon Kahng at Bell Labs fabricated
the first MOSFET (metal-oxide-semiconductor field-
effect transistor) with a gate oxide thickness of 100
nm, along with a gate length of 20 µm.
• in 1962, Atalla and Kahng fabricated a nanolayer-
base metal–semiconductor junction (M–S junction)
transistor that used gold (Au) thin films with a
thickness of 10 nm.
6. Origin of nanotechnology
• the term "nano-technology" was first used by Norio
Taniguchi in 1974.
• In 1986, K. Eric Drexler used the term "nanotechnology"
in his 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.
• In 1980, the emergence of nanotechnology as a field in
occurred through convergence of Drexler's theoretical
and public work
• in 1986, Drexler co-founded The Foresight Institute to
help increase public awareness and understanding of
nanotechnology concepts and implications.
7. Nanoscience and technology
• branch of science that studies systems
and manipulates matter on atomic,
molecular and supramolecular
scales/ultra-small scale (the nanometre
scale).
8. Nanotechnology
• study of what happens when
things get very, very small – only
a few atoms in size.
• refers to the science,
engineering, and technology
conducted at the nanoscale,
which is about 1 to 100
nanometers.
• employs the study and
application of exceptionally small
things in materials science,
engineering, physics, biology
and chemistry.
9. Nanotechnology is a very diverse field that is
having bigger and bigger impacts on the world.
• has applications in medicine, cars, spacecrafts,
food, electronics, and materials science just to
name a few.
• refers broadly to a field of applied science and
technology whose unifying theme is the control
of matter on the molecular level in scales
smaller than 1 micrometer, normally 1 to 100
nanometers, and the fabrication of devices
within that size range.
https://www.youtube.com/watch?v=uUDWK4MGcr0
10. nanometer
• a unit of spatial measurement that is 10-9
meter, or one billionth of a meter.
• commonly used in nanotechnology, the
building of extremely small machines.
13. Electron microscope
• a microscope that
uses a beam of
accelerated electrons
as a source of
illumination.
• In 1930, German
engineers Ernst
Ruska and Max Knoll
built the first electron
microscope.
14. Atomic Force Microscope
• a type of high resolution
scanning probe
microscope that has a
resolution that you can
measure in fractions of a
nanometer.
• was pioneered in 1986
by Nobel Prize Winner
Gerd Binnig along with
Calvin Quate and
Christoph Gerber.
15. Scanning Tunneling Microscope
• an instrument for
imaging surfaces at
the atomic level.
• its development in
1981 earned its
inventors, Gerd
Binnig and Heinrich
Rohrer (at IBM
Zürich), the Nobel
Prize in Physics in
1986.
16. Possible Applications of
Nanotechnology in the Philippines:
• Information and Communication
Technologies and semiconductors
• Health and medicine
• Energy
• Food and agriculture
• Environment
17. Nanotech Roadmap for the Philippines
• Information and Communication
Technologies and semiconductors
• Health and biomedical
• Energy
• Agriculture and food
• Environment
• Health and environmental risk
• Nano-metrology
• Education and public awareness
18. Advantages and Disadvantages of
Nanotechnology
Advantages
• offers the
potential for new
and faster kinds
of computers
• more efficient
power sources:
• and life-saving
medical
treatments.
Disadvantages
• economic
disruption
• possible threats to
security, privacy,
health and the
environment.
19. Nanotechnology and Environment
Benefits
• improved
detection and
removal of
contaminants
• development of
benign industrial
processes and
materials
Concerns
• High reactivity and
toxicity
• Pervasive distribution
in the environment
• No nano-specific EPA
regulation
20. Nanotechnology and Health
Benefits
• improved medicine
• could save lives by
making diagnosis
and treatment far
more effective.
Concerns
• ability to cross cell
membranes and
translocate in the body.
• No FDA approval needed
for cosmetics and
supplements
21. Nanotechnology and Economy
Benefits
• better products
• new jobs
Concerns
• redistribution of
wealth
• potential costs of
clean-ups anf health
care
• accessibility to all
income levels
22. On 22 November 2018, ten eminent scientists and scientific
institutions received the UNESCO Medals for contributions to
the development of nanoscience and nanotechnologies during
a ceremony held at UNESCO headquarters, Paris. The medal
is awarded each year by the Director-General of UNESCO to
prominent scientists, public figures and organizations that
contributed to the development of nanoscience and
nanotechnologies in the spirit of UNESCO’s priorities.
• https://en.unesco.org/news/eighth-
unesco-medals-contributions-
development-nanoscience-and-
nanotechnologies
23. TOP TEN USES AND APPLICATIONS
OF NANOTECHNOLOGY by UNESCO
1. Energy storage, productions and conversion.
2. Agricultural productivity enhancement.
3. Water treatment and remediation.
4. Disease diagnosis and screening.
5. Drug delivery systems.
6. Food processing and storage.
7. Air pollution and remediation.
8. Construction.
9. Health monitoring
10. Vector and pest detector and control.
24. Assignment
1. What are other examples of nanostructures?
2. What tools can manipulate nanostructures?
3. How can nanotechnology address problems in
the environment?
4. How can nanotechnology be used in the
prevention and treatment of illnesses?
5. What is another example of nanotechnology
and how does it works?