Covalent grafting on hydrogenated silicon: towards a molecular RTD diode
Covalent grafting on hydrogenated silicon: towards a molecular RTD diode

Fig. 1 : Spontaneous re-oxidation of the Si-H (111) surface by IRRAS.

As CMOS goes towards 65nm technology node, the integration of traditional memory cells such as DRAMs and non-volatile Flash gets limited. The solutions proposed for their replacement (FeRAM, MRAM, PCM) show a large energy consumption. Therefore there is still a need for a high-density and ultra low-power memory devices suited to respond to the growing market of wireless Systems On a Chip (SOC). For this purpose, the concept of Negative Differential Resistance memory (NDR) based on Resonant Tunneling molecular Diode (RTD) appears very promising. Indeed, with one of the electrodes a semi-conductor, one can take benefit of the localized density of states.

The "heart" of the device is indeed the interface linkage between the electrode and the molecule, together with the order within the monolayer. Molecules with a σ−π−σ sequence have already been derived from molecular orbital calculations in order to allow significant electron transfer from silicon at moderate voltage (below 3V). Those tri-block molecules were chemically grafted onto hydrogenated silicon surfaces (Si-H) and the resulting monolayers were fully characterized by IRRAS, XPS and ellipsometry. [1-2]

It was thus shown that :

  • SiH surfaces are spontaneously re-oxidized in ambient conditions with a half-life period close to 4 hours
  • Acid-terminated chains and activated-ester-terminated chains can be grafted either thermally or electrochemically on SiH without any re-oxidation of the silicon surface, provided strictly anhydrous and oxygen-free conditions are used. The thermal route gives monolayers of higher density and quality, as shown by AFM
  • The σ−π−σ sequence can be built directly on the SiH surface by a sequential method from an acid-terminated monolayer and aromatic amines. Limited re-oxidation of the silicon surface was observed after the amide formation.

The next part of the project, which belongs to the ANR project "MEMO" (2005-2009), will be devoted to the integration of the SAM within a functional device in order to study the electrical characteristics. Carbon nanotubes will be used as top electrodes, in order to (i) avoid any degradation that might result from direct metal evaporation on the SAM; (ii) limit the actual number of molecules concerned by the electrical measurements. The expected geometry of the final device is given in Fig. 2. Engineered Silicon-On-Insulator (SOI) substrates will be used to generate, by classical lithography, isolated silicon nanowires that will be functionnalized with the σ−π−σ monolayer. Single-wall carbon nanotubes will be selectively deposited on top of the grafted nanowires in a cross-bar architecture, thanks to localized modification of the silica surface with amine-rich molecules.

In parallel, the folowing new grafting methods will be tested for the σ−π−σ monolayer, in order to totally avoid re-oxidation:

  • Photochemical grafting with visible light, as described recently by Sudhölter et al.
  • Low-temperature thermal grafting assisted by stable radicals, as described by Bowden et al.
  • Cathodic electrochemical grafting from Grignard reagents


[1] L Baraton, Ph.D. thesis, Paris XI University, 2004

[2] Electron Transport through Rectifying Self-Assembled Monolayer Diodes on Silicon: Fermi-Level Pinning at the Molecule-Metal Interface,
S. Lenfant, D. Guerin, F. Tran Van, C. Chevrot, S. Palacin, J. P. Bourgoin,, O. Bouloussa, F. Rondelez, and D. Vuillaume, J. Phys. Chem. B 110, 13947 (2006)

Covalent grafting on hydrogenated silicon: towards a molecular RTD diode

Fig 2: Scheme of the RTD device

#798 - Last update : 10/28 2009

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