Information Technology and Materials Science Merger of nanophase with microstructures Information is acquired through sensors The hottest topic in materials science is NANOeverything The future: Merge nanomaterials with microdevices - cross-disciplinary (bio, chem, phys, eng, med) - fundamentally interesting science (quantum!) - huge commercial potential - instant appeal - to students and the public
What is “Merger of Nano and Micro?” “I don’t know - but I know it when I see it.” A recent National Academy of Sciences Sackler Colloquim focused on the topic The next few slides give examples of NANO science “Shaping the world atom by atom” Quantum corral of 48 Fe atoms on Cu. The Cu surface state scatters and produces an oscillation in charge density (IBM)
Molecular Electronics - Non-volatile Nanotube RAM Flexible nanotube ropes Contact made when addressed by 2 electrodes Switchable between 2 states High density /cm 2 C.M. Lieber, Science
Directed Assembly - Networks of Nanostructures Fluid flow to align 1-D nanostructures Chemical patterning to give preferred bonding: NH 2 -termination attracts Si, InP, and GaP nanowires - CH 3 repels Crossed structures can be made: junctions C.M. Lieber, Science
Nanotube Nanotweezers Electrically operated Nano-scale manipulation Used to pick up micron particles C.M. Lieber, Science Size bar 1 micron
Crossed Si nanowire transistor nm dia Si nanowires Self assembly into transistor Much smaller junction than current chip technology C.M. Lieber, Science
Nanotubes as Transistors Multiwalled nanotube “ropes” have varying electrical properties Electrical breakdown can be used to select the tube with correct properties Transistor “tuning” Ph. Avouris, Science
Detection of Biological and Chemical Species Chemical functionalization of Si nanowire pH Sensor Protein detection: biotin functionalization allows detection of streptavidin C.M. Lieber, Science
Biologically mediated crystal growth Unknown protein selectively determines crystal phase formed Isolate protein+desired crystal phase PCR Refine Result gives highly selective bio-mediated crystal growth Large number of crystals can now be grown A. Belcher, Nature
Lab on a Chip Microfabrication Microfluidics Biomedical applications S. Soper, M Murphy, LSU
Biomolecular Motor F1-ATPase motor Rotates in response to the synthesis/hydrolysis of ATP F > 100 pN - big for such a little guy! Integration into a cell C.D. Montemagno, Cornell
Polarized Luminescence InP nanowires exhibit highly polarized luminescence Applications in optical communication Photonic circuitry C.M. Lieber, Science
Nanowire Nanolasers ZnO nanowire arrays grown on sapphire Each individual wire is a laser Room temperature operation Optical computing, information storage, microanalysis P. Yang, Science
Hierarchically-ordered Oxides Micromolding and latex-sphere templating Structural ordering at multiple discrete length scales (in this case, 10, 100, and 1000 nm) various compositions, silica, niobia, and titania, G. Whitesides, Science
Magnetic nanospheres and rods: Co Solution phase synthesis Highly controlled tight size distribution Size-tunable magnetic properties (quantum effects) Spheres in spintronic devices - hard disk sensors Rods for vertical magnetic data recording A.P. Alivisatos, Science Scale bar 100 nm
Colloidal Crystals: Templates for New Materials Almost a “lost wax” technique Make “crystals” of solid, hollow or coated spheres Many materials possible V.L. Colvin, Science
Nanomaterials for Information Technology New Materials and Devices to Sense the World Current efforts: –Synthesis of nano –Characterization –Assembly of nano –Integration into devices Sensors to provide info Actuators / Motors Analytical applications Leverage LSU’s Materials Science Capabilities –see Recommendation: Nanotechnology especially in bio / device-related