Transcript of Nanotechnology for Electronics and Sensors BIOE298dp (09-10-2014)
- Slide 1
- Nanotechnology for Electronics and Sensors BIOE298dp
(09-10-2014)
- Slide 2
- Why Nano for Electronics New designed materials offer new and
unique properties
- Slide 3
- Enables the development and cost efficient production of
state-of-the-art components operate faster has higher sensitivity
consume less power can be packed at much higher densities It can
become stronger, conduct heat better, and show extraordinary
electrical properties What Properties?
- Slide 4
- Example: at the nanoscale, the resistance dependence of a
material on an external magnetic field is significantly amplified,
which has led to the fabrication of hard disks with a data storage
density in the gigabyte and terabyte ranges. Nanotechnology has
also enabled the development of sensors suitable for measurements
at the molecular level with an unprecedented sensitivity and
response time, mainly due to their high surface to volume
ratio.
- Slide 5
- Slide 6
- Video on Soft, Microfluidic Systems of Circuits, Sensors and
Radios for the Skin: Mounting and Mechanics John Rogers group,
UIUC
- Slide 7
- A layer of graphene acts as the conducting channel in a field
effect transistor Robust Superior electronic properties Superior
mechanical properties High surface -to-volume ratio Graphene
Transistor
- Slide 8
- Integrated circuit based on individual carbon nanotube Carbon
Nanotube Electronics
- Slide 9
- Carbon Based Nanosensors
- Slide 10
- Molecular Electronics: Single Molecule Memory Device
- Slide 11
- Organic Transistor Odor Sensor
- Slide 12
- Quantum Dots
- Slide 13
- Quantum Dots with gradually stepping emission from violet to
deep red
- Slide 14
- Slide 15
- Slide 16
- Semiconductor Energy Levels
- Slide 17
- Excitons
- Slide 18
- Slide 19
- Slide 20
- Slide 21
- Single Electron Transistor Quantum Dots?
- Slide 22
- Nano-Electro-Mechanical-System
- Slide 23
- Slide 24
- Spintronics
- Slide 25
- Rechargeable Batteries
- Slide 26
- Quantum Computing
- Slide 27
- BIOMEMS
- Slide 28
- Video of Thin, Flexible Devices that Produce Electrical Power
When Mounted on the Surface of the Heart
- Slide 29
- Video of the Mechanics of Stretchable, 'Wavy'
Nanomembranes
- Slide 30
- Instrumented, Artificial Pericardium, Constructed Using a 3D
Printer and the Techniques of Stretchable Electronics John Rogers
Group, UIUC
- Slide 31
- Slide 32
- Slide 33
- Conclusion Nanotechnology helps to develop cost efficient
production of state-of-the-art components, which can operate faster
with higher sensitivity, consume less power and can be packed at
much higher densities It can become stronger, conduct heat better,
and show extraordinary electrical properties Can be made completely
biodegradable Tremendous potential