Direct deposition of continuous metal nanostructures by thermal dip-pen nanolithography Applied Physics Letter, January 2006 B.A. Nelson and W.P. King,

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Direct deposition of continuous metal nanostructures by thermal dip-pen nanolithography Applied Physics Letter, January 2006 B.A. Nelson and W.P. King, Georgia Tech A.R. Laracuente, P.E. Sheehan, and L.J. Whitman, Naval Research Lab

Dip-Pen Nanolithography Scanning probe-based lithography technique using probe tip like a pen Tip is dipped in chemical “ink” and transfers nanoparticles, biomolecules, etc. to substrate through contact “writing” Resolution: 15 nm or better

Dip-Pen Nanolithography Conventional DPN requires inks that are mobile at ambient conditions Deposition rate controlled by changing ambient conditions (temperature, humidity) or heating/cooling substrate; dynamic control difficult Unable to ‘turn-off’ deposition, causing contamination and smearing Metrology not possible without unintended deposition or prior cleaning of probe tip Emphasis on organics and biomolecules, not conductive metals

Thermal DPN Heating element integrated into cantilever Allows use of “inks” that are solid in ambient conditions Deposition easily turned on/off by modulating heating element Surface imaging possible without smearing/contamination

Experiments Silicon AFM cantilever with embedded microscale heater Estimated ~20 nm radius of curvature Thermal time constant of µs Temperature sensitive resistance (2 - 7 kΩ for °C) used for calibration Indium as deposition metal (melting point = °C) Loading: Indium substrate scanned with 500 nN contact force at 6 µm/s with tip temperature of ~1030 °C

Experiments Continuous lines deposited by reheating cantilever while contacting substrate Dimensions depend on tip loading, temperature, speed, and repetitions Successful deposition for: °C µm/s raster scans Borosilicate glass, quartz, silicon substrates nm thick, nm high Imaging with cooled, coated tip had no effect on deposited lines

Testing Gold electrodes with 500 nm gap fabricated using EBL on 100 nm thick silicon oxide film on silicon substrate Indium-coated tip used to image electrodes before deposition Indium deposition at 425 °C, 4 µm/s Resulting line 5 nm tall, nm wide Auger electron nanoprobe spectra shows structure is indium oxide I-V measurements show deposition is continuous and ohmic (R = 2.5 x 10 4 Ω- cm)

Conclusions Traditional DPN capabilities expanded by tDPN tDPN adds dynamic control of deposition, ability to scan with loaded tip, use of solid metal “inks” Technique could be used to perform in situ inspection and repair of nanoelectronics Parallel deposition/metrology possible with cantilever arrays