• DocumentCode
    937074
  • Title

    Optical sensors for vapors, liquids, and biological molecules based on porous silicon technology

  • Author

    De Stefano, Luca ; Moretti, Luigi ; Lamberti, Annalisa ; Longo, Olimpia ; Rocchia, Massimiliano ; Rossi, Andrea M. ; Arcari, Paolo ; Rendina, Ivo

  • Author_Institution
    Inst. per la Microelettronica e Microsistemi, Napoli, Italy
  • Volume
    3
  • Issue
    1
  • fYear
    2004
  • fDate
    3/1/2004 12:00:00 AM
  • Firstpage
    49
  • Lastpage
    54
  • Abstract
    The sensing of chemicals and biochemical molecules using several porous silicon optical microsensors, based both on single-layer interferometers and resonant-cavity-enhanced microstructures, is reported. The operation of both families of sensors is based on the variation of the average refractive index of the porous silicon region, due to the interaction with chemical substances either in vapor or liquid state, which results in marked shifts of the device reflectivity spectra. The well established single-layer configuration has been used to test a new chemical approach based on Si-C bonds for covalent immobilization of biological molecules, as probe, in a stable way on the porous silicon surface. Preliminary results on complementary oligonucleotide recognition, based on this technique, are also presented and discussed. Porous silicon optical microcavities, based on multilayered resonating structures, have been used to detect chemical substances and, in particular, flammable and toxic organic solvents, and some hydrocarbons. The results put in evidence the high sensitivity, the reusability, and the low response time of the resonant-cavity-enhanced sensing technique. The possibility of operating at room temperature, of remote interrogation, and the absence of electrical contacts are further advantages characterizing the sensing technique.
  • Keywords
    DNA; biosensors; cavity resonators; chemical sensors; crystal microstructure; electrical contacts; elemental semiconductors; light interferometers; microcavities; microsensors; molecular biophysics; optical multilayers; optical sensors; porous semiconductors; reflectivity; refractive index; sensitivity; silicon; 293 to 298 K; Si; Si-C bonds; biological molecules; chemical substances; chemicals sensing; covalent immobilization; electrical contacts; hydrocarbons; liquid state; liquids; multilayered resonating structures; oligonucleotide recognition; optical sensors; porous silicon optical microcavities; porous silicon optical microsensors; porous silicon surface; porous silicon technology; reflectivity; refractive index; remote interrogation; resonant-cavity-enhanced microstructures; resonant-cavity-enhanced sensing technique; reusability; room temperature; sensitivity; single-layer interferometers; toxic organic solvents; vapors; Biomedical optical imaging; Chemical technology; Liquids; Microsensors; Optical interferometry; Optical refraction; Optical sensors; Optical variables control; Resonance; Silicon;
  • fLanguage
    English
  • Journal_Title
    Nanotechnology, IEEE Transactions on
  • Publisher
    ieee
  • ISSN
    1536-125X
  • Type

    jour

  • DOI
    10.1109/TNANO.2004.824019
  • Filename
    1278268