Second harmonic generation in the near field and far field: A sensitive tool to probe crystalline homogeneity

Mahieu-Williame, Laurent; Grésillon, S.; Cuniot-Ponsard, Mireille; Boccara, Claude

doi:10.1063/1.2719278

Cited by 14 publications

(12 citation statements)

References 42 publications

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“…A second approach is akin to the apertureless NSOM (ANSOM) technique, the difference being that the setup is modified to collect the near‐field SHG signal, rather than the evanescent wave of the fundamental. In short, the fundamental light is focused on the sample, where the near‐field evanescent waves (both fundamental and second harmonic [SH]) are scattered by an oscillating metallic tip operating in tapping mode . The scattered near‐field and far‐field waves are then collected for both the fundamental and SH wave, and the near‐field contributions can be separated out by filtering the signals at the oscillation frequency of the tip [Fig.…”

Section: Techniques and Instrumentation For Measuring Optical Shgmentioning

confidence: 99%

Probing Ferroelectrics Using Optical Second Harmonic Generation

Denev

Lummen

Barnes

et al. 2011

Journal of the American Ceramic Society

272

307

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Nonlinear optics is an essential component of modern laser systems and optoelectronic devices. It has also emerged as an important tool in probing the electronic, vibrational, magnetic, and crystallographic structure of materials ranging from oxides and metals, to polymers and biological samples. This review focuses on the specific technique of optical second harmonic generation (SHG), and its application in probing ferroelectric complex oxide crystals and thin films. As the dominant SHG interaction mechanism exists only in materials that lack inversion symmetry, SHG is a sensitive probe of broken inversion symmetry, and thus also of bulk polar phenomena in materials. By performing in-situ SHG polarimetry experiments in different experimental conditions such as sample orientation, applied electric field, and temperature, one can probe ferroelectric hysteresis loops and phase transitions. Careful modeling of the polarimetry data allows for the determination of the point group symmetry of the crystal. In epitaxial thin films with a two-dimensional arrangement of well-defined domain orientations, one can extract information about intrinsic material properties such as nonlinear coefficients, as well as microstructural information such as the local statistics of the different domain variants being probed. This review presents several detailed examples of ferroelectric systems where such measurements and modeling are performed. The use of SHG microscopic imaging is discussed, and its ability to reveal domain structures and phases not normally visible with linear optics is illustrated.

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Section: Techniques and Instrumentation For Measuring Optical Shgmentioning

confidence: 99%

Probing Ferroelectrics Using Optical Second Harmonic Generation

Denev

Lummen

Barnes

et al. 2011

Journal of the American Ceramic Society

272

307

View full text Add to dashboard Cite

show abstract

“…1 Additionally, tips have been employed that locally distort or enhance the electric fields generated by the excitation source near the object under study (apertureless NSOM). [2][3][4] NSOM is well adapted for various gaseous and liquid environments, allowing in situ studies of chemical processes.…”

Section: Introductionmentioning

confidence: 99%

Combined Apertureless Near-Field Optical Second-Harmonic Generation/Atomic Force Microscopy Imaging and Nanoscale Limit of Detection

Meyer

et al. 2010

Appl Spectrosc

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A dual function atomic force/near-field scanning optical microscope (AFM/NSOM) with an ultrafast laser excitation source was used to investigate apertureless, tip enhanced second-harmonic generation (SHG) of ZnO nanowires with spatial resolution below the optical diffraction limit. Single-wire SHG spectra show little to no contribution from bandgap or other emission. Polarization data established values for chi(33)/chi(31) close to previous estimates and confirm the SHG process. Experimental results indicate that the SHG signal was reduced for nanowires after exposure to an atmosphere of carbon dioxide and water vapor. An equation was derived for estimating the minimum chi(2) detectable using apertureless SHG NSOM.

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“…These limitations can be overcome by using scanning near‐field optical microscopy (SNOM) (Pohl et al , 1984) that allows a resolution in the hundreds (Dunn, 1999) or tens of nanometre scale (Kim et al , 2004; Mahieu‐Williame et al , 2007). Moreover, when an SNOM probe is used as a nanosource of light, it reduces the dimension of the illumination zone and the time of exposure and, as a consequence, photobleaching of fluorescent labels also is decreased.…”

Section: Introductionmentioning

confidence: 99%

Near‐field microscopy and fluorescence spectroscopy: application to chromosomes labelled with different fluorophores

Mahieu-Williame

Falgayrettes

Nativel

et al. 2010

Journal of Microscopy

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Summary We have coupled a spectrophotometer with a scanning near‐field optical microscope to obtain, with a single scan, simultaneously scanning near‐field optical microscope fluorescence images at different wavelengths as well as topography and transmission images. Extraction of the fluorescence spectra enabled us to decompose the different wavelengths of the fluorescence signals which normally overlap. We thus obtained images of the different fluorescence emissions of acridine orange bound to single or double stranded nucleic acids in human metaphase chromosomes before and after DNAse I or RNAse A treatment. The analysis of these images allowed us to visualize some specific chromatin areas where RNA is associated with DNA showing that such a technique could be used to identify multiple components within a cell.

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Second harmonic generation in the near field and far field: A sensitive tool to probe crystalline homogeneity

Cited by 14 publications

References 42 publications

Probing Ferroelectrics Using Optical Second Harmonic Generation

Probing Ferroelectrics Using Optical Second Harmonic Generation

Combined Apertureless Near-Field Optical Second-Harmonic Generation/Atomic Force Microscopy Imaging and Nanoscale Limit of Detection

Near‐field microscopy and fluorescence spectroscopy: application to chromosomes labelled with different fluorophores

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