Presentation is loading. Please wait.

Presentation is loading. Please wait.

Caltech collaboration for DNA-organized Nanoelectronics The Caltech DNA- nanoelectronics team.

Published byClaud Wells Modified over 8 years ago

Similar presentations

Presentation on theme: "Caltech collaboration for DNA-organized Nanoelectronics The Caltech DNA- nanoelectronics team."— Presentation transcript:

1 Caltech collaboration for DNA-organized Nanoelectronics The Caltech DNA- nanoelectronics team

2 State of the art, DNA self- assembly 1, DNA origami

3 State of the art DNA self- assembly 2, DNA tiles, tubes and crystals

4 State of the art DNA self- assembly 3, algorithmic + combination

5 Challenges for DNA organized nanoelectronics 1A Si/ SiO 2 Pd + +

6 Challenges for DNA organized nanoelectronics 1B To make nanostructures more rigid and to avoid aggregation origami-ribbon hybrids are used. crossbar red tubeblue tubes 50 nm MOSFET geometry ChannelGate red and blue hooks

7 Challenges for DNA organized nanoelectronics 1C Over 30% of tubes are within 10 degrees of the desired orientation Characterization of DNA self-assembled CNT FET I SD V SD VgVg ab I SD Orientation of SWNT 0 5 10 15 20 25 30 35 40 0-2020-4040-6060-8080-100100-120120-140140-160160-180 22% 2% 76% Red side (-1) Unknown (0) Blue side (1) Frequency Angle

8 Challenges for DNA organized nanoelectronics 2

9 Challenges for DNA organized nanoelectronics 3,4

10 Challenges for DNA organized nanoelectronics 4,5

11 Rothemund’s Aims

12 Bridging nano and micro

13 Divergent wires

14 Winfree’s Aims

15 From counters to demultiplexers and squares

16 Self-assembled memory circuit

17 Bockrath'sAims: To self-assemble and characterize circuits of more than one carbon-nanotube based device to create elementary logic gates and memory elements. To use short length-sorted carbon nanotubes to increase the yield of existing devices. (Many problems arise from very long tubes acting as bridges between multiple origami). To self-assemble novel devices to explore transport physics in nanostructures. Bockrath’s Aims

18 Rationally Engineered Logic gates and Memory Elements Utilizing Multiple Nanotubes VsVs V in V out VsVs VsVs VsVs V in1 V out V in2 Inverter SRAM NOR Nanotube assemblySchematic circuit diagram

19 B V I Novel Devices Probing Transport Physics in Nanostructures: Phase Coherence in Strongly-Interacting Electron Systems Nanotubes act as a “which path?” interferometer enabling the study of phase coherent transport in Nanotube-based Luttinger liquids via a transport experiment. The setup is analogous to a double slit experiment in optics. The magnetic field B tunes the phase by the Ahoronov-Bohm effect. Tubes must be closer together than the phase coherence length in the electrodes, which is readily obtainable using DNA based self-assembly. Tunable separation with desired values ~5-20 nm DNA origami template for parallel nanotubes Interferometer device source drain Many possibilities exist for making novel devices. Novel Devices Probing Transport physics

20 Goddard’s Aims

21 Size of molecules quantum descriptions necessary. Quantum chemistry of molecule(s) + nanotube -> charge flow & bonding -> geometry & energy spectrum of the entire system. Organo-metallic interface mechanics and transport. Need to treat molecule as finite and nanotubes as semi-infinite electrodes. Escape currents (through organic insulator layer). Conformation effects on electronic transport. Effect of finite bias. IV characteristic of self-assembled CNT-based transistor junctions. HOMO LUMO I CNT DNA Organic molecule CNT V DNA-origami CNT-based Transistor Junctions Theory and Modeling to Describe…

22 Multiscale Methodology: 1 st -principles I-V validated by rotaxane modeling Density-functional theory (Hohenberg-Kohn-Sham) Ballistic transport theory (Landauer, Buttiker) T(E,V) contact widening self-energy Green’s ftn. Formalism (Fisher-Lee) transmission electro-chemical potential conductance current Molecular Mechanics Dynamics Molecular Mechanics Dynamics geometry dI/dV e.g. Rotaxane switch   1 m 2

23 Further validation: bi-phenyl-dithiol modeling Au (111) T(E) I(V) molecule contact

24 Relevance to ONR

25 Budget Budget for 4 years, $2.6 million including: PI: Paul Rothemund: $200K/yr for Senior Research Associate salary and materials Co-PI: Mark Bockrath $100K/yr for 1 graduate student and materials Co-PI: Bill Goddard $100K/yr for 1 graduate student and materials Co-PI: Erik Winfree $100K/yr for 1 graduate student and materials Equipment $150K/yr including plasma etcher/cleaner ($20K), wafer-scale Atomic Force Microscope ($200K) temperature-controlled dynamic light scattering ($50K).

Download ppt "Caltech collaboration for DNA-organized Nanoelectronics The Caltech DNA- nanoelectronics team."

Similar presentations

Computational Nanoelectronics A. A. Farajian Institute for Materials Research, Tohoku University, Sendai 980-8577, Japan In collaboration with K. Esfarjani,

Computational Nanoelectronics A. A. Farajian Institute for Materials Research, Tohoku University, Sendai , Japan In collaboration with K. Esfarjani,
Nanotechnology. Research and technology development at the atomic, molecular or macromolecular levels, in the length scale of approximately 1 - 100 nanometer.

Nanotechnology. Research and technology development at the atomic, molecular or macromolecular levels, in the length scale of approximately nanometer.
Carbon nanotube field effect transistors (CNT-FETs) have displayed exceptional electrical properties superior to the traditional MOSFET. Most of these.

Carbon nanotube field effect transistors (CNT-FETs) have displayed exceptional electrical properties superior to the traditional MOSFET. Most of these.
Interfacing Molecules to Electronic Materials.

Interfacing Molecules to Electronic Materials.
Huckel I-V 3.0: A Self-consistent Model for Molecular Transport with Improved Electrostatics Ferdows Zahid School of Electrical and Computer Engineering.

Huckel I-V 3.0: A Self-consistent Model for Molecular Transport with Improved Electrostatics Ferdows Zahid School of Electrical and Computer Engineering.
Electrical Techniques MSN506 notes. Electrical characterization Electronic properties of materials are closely related to the structure of the material.

Electrical Techniques MSN506 notes. Electrical characterization Electronic properties of materials are closely related to the structure of the material.
Roadmap of Microelectronic Industry. Scaling of MOSFET Reduction of channel length L  L/α Integration density  α 2 Speed  α; Power/device  1/α 2 Power.

Roadmap of Microelectronic Industry. Scaling of MOSFET Reduction of channel length L  L/α Integration density  α 2 Speed  α; Power/device  1/α 2 Power.
Multi-terminal spin dependent transport in carbon nanotubes Chéryl FEUILLET-PALMA Laboratoire Pierre Aigrain Ecole Normale Supérieure, Paris France Co-workers.

Multi-terminal spin dependent transport in carbon nanotubes Chéryl FEUILLET-PALMA Laboratoire Pierre Aigrain Ecole Normale Supérieure, Paris France Co-workers.
DNA Computing by Self Assembly  Erik Winfree, Caltech.

DNA Computing by Self Assembly  Erik Winfree, Caltech.
1 Systems Technology Lab, Intel Research Berkeley 2 Mechanical Engineering, Stanford University Dissipation and Entropy Flow in Logic Fundamental Limits.

1 Systems Technology Lab, Intel Research Berkeley 2 Mechanical Engineering, Stanford University Dissipation and Entropy Flow in Logic Fundamental Limits.
© 2010 Eric Pop, UIUCECE 598EP: Hot Chips Conductance Quantization One-dimensional ballistic/coherent transport Landauer theory The role of contacts Quantum.

© 2010 Eric Pop, UIUCECE 598EP: Hot Chips Conductance Quantization One-dimensional ballistic/coherent transport Landauer theory The role of contacts Quantum.
Ashish Goel Stanford University Joint work with Len Adleman, Holin Chen, Qi Cheng, Ming-Deh Huang, Pablo Moisset, Paul.

Ashish Goel Stanford University Joint work with Len Adleman, Holin Chen, Qi Cheng, Ming-Deh Huang, Pablo Moisset, Paul.
A DNA-Templated Carbon Nanotube Field Effect Transistor Erez BraunUri Sivan Rotem BermanEvgeny Buchstab Gidi Ben-Yoseph Kinneret Keren Physics Department.

A DNA-Templated Carbon Nanotube Field Effect Transistor Erez BraunUri Sivan Rotem BermanEvgeny Buchstab Gidi Ben-Yoseph Kinneret Keren Physics Department.
Nanoscale Self-Assembly A Computational View Philip Kuekes Quantum Science Research HP Labs.

Nanoscale Self-Assembly A Computational View Philip Kuekes Quantum Science Research HP Labs.
Hybrid Nano Structure Research Lab. in Physics, Electronic Materials Research Lab in Physics,

Hybrid Nano Structure Research Lab. in Physics, Electronic Materials Research Lab in Physics,
Emerging Nanotechnology Devices

Emerging Nanotechnology Devices
Quantum Dots Arindam Ghosh. Organization of large number of nanostructures – scalability Utilize natural forces Organic, inorganic and biological systems.

Quantum Dots Arindam Ghosh. Organization of large number of nanostructures – scalability Utilize natural forces Organic, inorganic and biological systems.
Ballistic and quantum transports in carbon nanotubes.

Ballistic and quantum transports in carbon nanotubes.
Lecture 19 OUTLINE The MOSFET: Structure and operation

Lecture 19 OUTLINE The MOSFET: Structure and operation
INAC The NASA Institute for Nanoelectronics and Computing Purdue University Circuit Modeling of Carbon Nanotubes and Their Performance Estimation in VLSI.

INAC The NASA Institute for Nanoelectronics and Computing Purdue University Circuit Modeling of Carbon Nanotubes and Their Performance Estimation in VLSI.

Similar presentations

Ads by Google