1. ESE 111 – Nanofabrication and Technology
ENIAC
DEC PDP-8
IBM PC
Pentium 4 PC
Microelectronics ==> Nanoelectronics
Make this transition happen
… and the other applications that are enabled by nanoscale science and technology

2. Evolution of Electronics
Vacuum tube
ENIAC = Electronic Numerical Integrator and Computer
First Transistor, 1947 Bell Labs
Discrete Transistor

3. Intel Core i7 Processor with 45 nm Transistors

4. The Fabrication Facility of Today
300 mm wafer Fabrication
Intel

5. Moore’s Law

6. Other Electronic Applications = “More than Moore” Silicon and New Materials
carbon nanotubes
Rogers, UIUC
Organic and nanocrystalline semiconductors
Rogers, UIUC
Kagan, Penn Si
nanowires
nanocrystals
graphene
organic materials
carbon nanotubes

7. Alternative, Low-Cost Fabrication
Printable Electronics – Spin, Dip, Spray, Print, Imprint …. From Solution
Spin-coating
Printing
Krebs, Denmark
Dip-coating
Imprinting
Example: nanocrystals
In general for solutions
Mesopotamian Templates 600 AD
25 nm holes

8. Examples of Some Electronic and Optoelectronic Applications
Printed Electronics
Samsung
Konarka
Solar Cells
RFID Tags Poly IC
Sony OLED TV
E-textiles
Poly IC
E-Paper
Plastic Logic
Flexible Display

9. Flexible Electronics Analog Electronics
Scaling to allow faster operation
Digital Electronics
Kagan group

10. BioElectronics Litt, Penn and Rogers, UIUC Utah Electrode Array
10 x 10 array of electrodes
¼” x ¼” in size
Litt, Penn and Rogers, UIUC

11. Light at the Nanoscale

12. Nanophotonics and Plasmonics

13. Description using Maxwells equation
Metal Nanoparticle Assemblies as Building Blocks for Optical Metamaterials
Designing composite materials with electromagnetic properties not found in nature and not observed in the constituent materials
cloaking
superlenses
sensors
lithography
a<<l
Effective medium
Description using Maxwells equation
metatronics =
optical nanocircuits
Engheta, Penn

14. Designer Metamaterials
Au NC
dispersion
substrate
PDMS template
Ligand exchange
Wavelength (µm)
Transmittance (a.u.) d
Scale bar = 1µm
Kagan group

15. Nanodevices and Nanosystems Curriculum
New ESE curriculum
New curriculum (class of 2018):
ESE 218
Electronic, Photonic, and Electromechanical Devices (Prof. Kagan, Fall)
Sophomore
ESE 321
Physics and Models of Semiconductor Devices
(Prof. Bassett, Fall)
ESE 310
Electric and Magnetic Fields I
(Prof. Engheta, Spring)
Junior
ESE 521
Physics of Solid State Energy Devices
ESE 460/574
Semiconductor micro-fabrication
ESE 525
Nanoscale Science and Engineering
ESE 509
Waves, Fibers and Antennas for Communications
ESE 510
Electromagnetic and Optical Theory
Senior

16. ESE 218 Electronic, Photonic, and Electromechanical Devices
Intel
IBM
Electronics
Photonics
Electromechanics

17. Samsung Galaxy