• DocumentCode
    1092268
  • Title

    Scanning force microscopic investigations of the femtosecond laser pulse irradiation of indium phosphide in air

  • Author

    Bonse, Jörn ; Munz, Martin ; Sturm, Heinz

  • Author_Institution
    Inst. de Opt., Madrid, Spain
  • Volume
    3
  • Issue
    3
  • fYear
    2004
  • Firstpage
    358
  • Lastpage
    367
  • Abstract
    Laser ablation of single-crystalline indium phosphide (InP) was performed in air by means of linearly polarized Ti : sapphire femtosecond pulses (800 nm, 130 fs, 10 Hz). As a result of the irradiation with a variable number of laser pulses per spot (N ≤ 5), several morphological changes (crater formation, rim formation, ripple structures, and cones) were observed. These effects were explored using force modulation microscopy (FMM), a technique based on scanning force microscopy, allowing the simultaneous imaging of both topography and local stiffness at a high lateral resolution. The first laser pulse induces the formation of a protruding rim (height < 20 nm, width ≈ 300 nm) bordering the ablated crater. A Fourier analysis of the multipulse generated topographies reveals the formation of wavelength-sized periodic ripples (modulation depth < 100 nm) with an orientation perpendicular to that of the electric field vector of the laser radiation. Besides these morphological alterations, material modifications were also observed in the irradiated regions by means of the FMM technique. Within the ablated craters, local stiffness variations were found revealing an inhomogeneous material composition/structure as a consequence of the femtosecond pulse laser treatment.
  • Keywords
    III-V semiconductors; atomic force microscopy; high-speed optical techniques; indium compounds; laser ablation; surface structure; surface treatment; 10 Hz; 130 fs; Fourier analysis; InP; SEM; ablated craters; crater formation; electric field vector; femtosecond laser pulse irradiation; femtosecond pulse laser treatment; force modulation microscopy; high lateral resolution; homogeneous material composition; laser ablation; laser radiation; modulation; rim formation; ripple structures; sapphire femtosecond pulses; scanning force microscopy; single crystalline indium phosphide; stiffness; High-resolution imaging; Image resolution; Indium phosphide; Laser ablation; Laser transitions; Microscopy; Optical materials; Optical pulses; Polarization; Surfaces; Laser materials-processing applications; laser radiation effects; microscopy; semiconductor materials; ultrafast optics;
  • fLanguage
    English
  • Journal_Title
    Nanotechnology, IEEE Transactions on
  • Publisher
    ieee
  • ISSN
    1536-125X
  • Type

    jour

  • DOI
    10.1109/TNANO.2004.828574
  • Filename
    1331325