1 / 20

Fabrication of Suspended Nanowire Structures Jason Mast & Xuan Gao

Fabrication of Suspended Nanowire Structures Jason Mast & Xuan Gao. Summer 2009 REU Program at Case Western Reserve University. Nano == 1 / billion Nanometer == 1 meter / billion Nanowire == wire with diameter between 1-100 nm Suspended Nanowire == A nanowire suspended over a gap.

lilia
Download Presentation

Fabrication of Suspended Nanowire Structures Jason Mast & Xuan Gao

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. Fabrication of Suspended Nanowire StructuresJason Mast & Xuan Gao Summer 2009 REU Program at Case Western Reserve University

  2. Nano == 1 / billion Nanometer == 1 meter / billion Nanowire == wire with diameter between 1-100 nm Suspended Nanowire == A nanowire suspended over a gap. Introduction Top – Nanowire on substrate Bottom – Nanowire suspended over gap Black == Metal Green == Nanowire Gray == Si/SiO2 substrate

  3. Applications Electrical Circuits Biology & Medicine Cell Device Sensors ω' ω Cell Cell

  4. 1. Fabricate suspended nanowire devices - Simple but not easy. 2. Test the devices and look at the I-V curves. - Should be different because the substrate (read heat sink) is not in contact with the wire. Goals

  5. Basic Idea 1. Carve trenches out of top SiO2 layer. 2. Drop nanowires over the trenches. 3. Evaporate metallic contact pads. Method I Step 1 - Start Blue == 100 nm SiO2 Gray == Silicon

  6. Photoresist layers act like sacrificial layers. We use them to mold our devices. Step 2 – Spin Coat Photoresist Purple == LOR-3A Yellow == S 1805

  7. Step 3 – Carve out Trenches i. Place wafer under photomask, and expose the sample to UV light. Top View ii. Submerge in CD-26. Iiii. Submerge in HF for 60 sec. Rate ~ 1 nm / sec

  8. Step 4 – Drop nanowires This can be done using either wet or dry transfer.

  9. Step 5 – Contact Pads i. Expose 2nd pattern to UV light. ii. Submerge in CD-26 for 60 sec.

  10. Step 5 - cont. Iiii. Evaporate metal (5 nm Ti & then 50 nm Al). Different shades of gray represent different elevations of metal. iv. Let the wafer sit in Remover PG overnight.

  11. Basic Ideas 1. Embed nanowires between layers of photoresist. 2. Create metallic contacts. Method II Step 1 – Get Started Blue == 100 nm SiO2 Gray == Silicon

  12. Step 2 – Spin coat photoresist Yellow == Photoresist Step 3 – Drop nanowires Green == Nanowires

  13. Step 4 – Spin coat photoresist Nanowires are now embedded between two layers of photoresist.

  14. Step 5 – Contact Pads i. Place under photomask, and expose to UV light. ii. Submerge in CD-26 for 60 sec.

  15. Step 5 - cont Iiii. Evaporate metal (5 nm Ti & 300 nm Al). vi. Submerge in Remover PG overnight.

  16. I was able to perform alignment. However, alignment was far too complicated to implement. Results – Method I

  17. I was able to get suspended nanowire structures. I was able to get a few I-V curves, and a resistance measurement. Results – Method II

  18. Special Thanks To: Case Western Reserve University Physics Department National Science Foundation Bob Mike McDonald Professor Kash Reza Sharghi-Moshtaghin Acknowledgments NSF REU grant DMR-0850037

More Related