Towards Single Molecule Electronics

1. Towards Single Molecule Electronics Can a single molecule behave like a diode, transistor (switch), memory? If that’s possible, how long will the molecule last? First, let’s look at many molecules acting in parallel. Nitzan and Ratner, Science 300, 1384 (2003); Heath and Ratner, Physics Today, May 2003, p. 43

2. HP Molecular Memory 40 nm line width, 40 Gbit/inch2

3. Input: Address Crossbar Memory Architecture Output: Stored Data 1 0 Molecular Memory DRAM MRAM (Magnetic Random Access Memory)

4. HP Molecular Memory Rotaxane molecules switch between high and low resis- tance by receiving a voltage pulse. The blue ring can shuttle back and forth along the axis of the rotaxane molecule, between the greenand red groups.

5. (Many Molecules) HP Molecular Memory Change the resistance between low and high by voltage pulses. Is the resistance change really due to the rotaxane ring shuttling back and forth? Other molecules exhibit the same kind of switching. One possible model is the creation and dissolution of metal filaments which create a short between the top and bottom electrodes. (Some-thing like that happens in batteries). Collier et al., Science 289, 1172 (2000).

6. Other Molecular Switches Large On-Off Ratios Chen et al., Science 286, 1550 (1999)

7. Robert F. Service, Science 302, 556 (2003).

8. Synthesis of a Rotaxane Molecule Amabilino and Stoddart, Chemical Reviews 95, 2725 (1995).

9. Some Fancy Molecules Rotaxane Catenane Pretzelane Handcuffcatenane

10. Data Storage via the Oxidation State of a Molecule Electrochemistry

11. Quantum Dot Molecular Switch Self-Organizing Memory + Data Processor People have been thinking about how to combine memory with logic (= a microprocessor) in a molecular device. Self-assembly is the preferred method. It generates errors, though. They need to be absorbed by a fault-tolerant architecture (e.g. in the HP Teramac) Heath et al., Science 280, 1716 (1998)

12. Local Hotspots Appear after Switching The latest from HP on how molecules switch. Miao et al., Phys. Rev. Lett. 101, 016802 (2008)

13. “Conductivity” of DNA Tunneling at short distances (independent of temperature) Hopping at large distances (thermally activated) Berlin et al., Chem. Phys. 275, 61 (2002)

14. Using a Single Molecule

15. Using a Single Molecule Coulomb Blockade Magnetic (Kondo) Resonance at the Fermi level (zero voltage) Park et al., Nature 417, 722 (2002)

16. Using a Few Molecules Observe tunneling through 1, 2, 3, 4, 5 alkanethiol molecules Cui et al., Science 294, 571 (2001)

17. A Molecular Transistor (a) Structures of the long and short linked cobalt coordinated terpyridine thiols used as gate molecules. (b) A topographic AFM image of the gold electrodes with a gap. (c) A schematic representation of the assembled single atom transistor.

18. Break Junctions At the beginning of single molecule electronics, break junctions were very popular: Just crack a thin Au wire open in a vice and adjust the width of the crack with piezos (as in STM). Then pour a solution of molecules over it. Alternatively, one can burn out the thinnest spot of a thin Au wire by running a high current density through it (using the effect of electromigration). These days, many try to achieve a well-defined geometry using a STM or AFM, with a well-defined atom at the end of the tip and another well-defined atom at the surface as con-tacts to a single molecule. A schematic representation of Reed and Tour’s molecular junction containing a benzene-1,4-dithiolate SAM that bridges two proximal gold electrodes.

19. Conductance through a C60 Molecule Distance dependence tells whether it is tunneling (exponential decay) or quantum conductance through a single or multiple orbitals (G0). Kröger et al., J. Phys. Condend. Matter 20, 223001 (2008)

20. Many Ideas for Single Molecule Devices Heath and Ratner, Physics Today, May 2003, p. 43