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NTEGRA SPECTRA

Interdisciplinary research at the nanometer scale: AFM + Confocal Raman + SNOM + TERS

Integration of SPM and confocal microscopy/Raman scattering spectroscopy. Owing to Tip Enhances Raman Scattering it allows carrying out spectroscopy/microscopy with up to 10 nm resolution

Specifications

NTEGRA Spectra - AFM / CONFOCAL RAMAN & FLUORESCENCE / SNOM / TERS (Nano-Raman)Integration: The key to the new sciences

Change happens at interfaces and today’s most exciting changes in microscopy are happening where multiple technologies are interfaced together. NTEGRA Spectra is a prime example, uniting the full power of atomic force microscopy (AFM), confocal Raman and fluorescence microscopy and scanning near-field optical microscopy (SNOM) in one platform.Different configuration of AFM with confocal Raman/Fluorescence microscope


UprightA unique configuration for simultaneous AFM - Raman - TERS* and SNOM imaging of opaque samples*TERS: Tip Enhanced Raman Scattering, Tip Enhanced Fluorescence etc.

InvertedOptimized for simultaneous AFM - Raman - TERS* and SNOM imaging of samples on transparent substrates (living cells, nanoparticles etc.)

Side illumination optionUsed to facilitate TERS* measurements on opaque samples

Fiber Scanning Near-field Optical Microscopy (SNOM)SNOM techniques based on on quartz fiber.

Cantilever Scanning Near-field Optical Microscopy (SNOM)SNOM techniques based on cantilevers with aperture.
  • Atomic Force Microscopy ( 30 modes )
  • Confocal Raman / Fluorescence / Rayleigh Microscopy
  • Scanning Near-Field Optical Microscopy ( SNOM / NSOM )
  • Optimized for Tip Enhanced Raman and Fluorescence (TERS, TEFS, TERFS) and scattering SNOM (s-SNOM)

SOLUTION FOR ALL POSSIBLE EXCITATION/DETECTION AND TERS GEOMETRIES

 

WORKING PRINCIPLEModes:


Modes
  • AFM (mechanical, electrical, magnetic properties, nanomanipulation etc.)
  • White Light Microscopy and Confocal Laser (Rayleigh) Imaging
  • Confocal Raman Imaging and Spectroscopy
  • Confocal Fluorescence Imaging and Spectroscopy
  • Scanning Near-Field Optical Microscopy (SNOM)
  • Tip Enhanced Raman and Fluorescence Microscopy (TERS, TEFS, TERFS)
Controlled environment:
  • Temperature
  • Humidity
  • Gases
  • Liquid
  • Electrochemical environment
  • External magnetic field

SPECIFICATIONS

  • Confocal Raman/Fluorescence microscopy
  • AFM/STM: Integration with spectroscopy
  • Software
  • Spectroscopy
  • Scanning Near Field Optical Microscopy (SNOM)
  • Optimized for Tip Enhanced Raman Scattering (TERS) and other tip-related optical techniques
  • (S-SNOM, SNIM, TEFS, STM-LE etc.)

Confocal Raman/Fluorescence microscopy

  • Confocal Raman/Fluorescence/Rayleigh imaging runs simultaneously with AFM (during one sample scan)
  • Diffraction limited spatial resolution: 200 nm in XY, 500 nm in Z (with immersion objective)
  • True confocality; push button from software to control the motorized confocal pinhole for optimal signal and confocality
  • Motorized variable beam expander/collimator: adjusts diameter and collimation of the laser beam individually for each laser and each objective used
  • Full 3D (XYZ) confocal imaging with powerful image analysis
  • Hyperspectral imaging (recording complete Raman spectrum in every point of 1D, 2D or 3D confocal scan) with further software analysis
  • Optical lithography (vector, raster)

AFM/STM: Integration with spectroscopy

  • Upright and Inverted optical AFM configurations (optimized for opaque and transparent samples correspondingly);
  • side illumination option
  • Highest possible resolution (numerical aperture) optics is used simultaneously with AFM: 0.7 NA for Upright, 1.3–1.4 NA for Inverted
  • AFM/STM and confocal Raman/Fluorescence images are obtained simultaneously (during one scan)
  • All standard SPM imaging modes are supported (30 modes) — combined with confocal Raman/Fluorescence
  • Low noise AFM/STM (atomic resolution)
  • Vibrations and thermal drifts originating from optical microscope body are minimized due to special design of optical AFM heads
  • Focus track feature: sample always stays in focus due to AFM Z-feedback; high quality confocal images of very rough or inclined samples can be obtained

Software

  • Seamless integration of AFM and Raman; all AFM/ Raman/SNOM experiment and further data analysis is performed in one and the same software
  • Powerful analysis of 1D, 2D and 3D hyperspectral images
  • Powerful export to other software (Excel, MatLab, Cytospec etc.)

Spectroscopy*

  • Extremely high efficiency 520 mm length spectrometer with 4 motorized gratings
  • Visible, UV and IR spectral ranges available
  • Echelle grating with ultrahigh dispersion; spectral resolution: 0.007 nm (< 0.1 1/cm)**
  • Up to 3 different detectors can be installed
  • TE cooled (down to -100 ºC) CCD camera. EMCCD camera is optional — for ultrafast imaging
  • Photon multiplier (PMT) or avalanche photodiode in photon counting mode
  • Photon multiplier for fast confocal laser (Rayleigh) imaging
  • Flexible motorized polarization optics in excitation and detection channels, cross-polarized Raman measurements
  • Fully automated switch between different lasers — with a few mouse clicks

Scanning Near Field Optical Microscopy (SNOM)*

  • Two major SNOM techniques supported: (i) based on quartz fiber probes, (ii) based on silicon cantilever probes
  • All modes supported: Transmission, Collection, Reflection
  • All SNOM signals detected: laser intensity, fluorescence intensity, spectroscopy
  • SNOM lithography (vector, raster)

Optimized for Tip Enhanced Raman Scattering (TERS) and other tip-related optical techniques (S-SNOM, SNIM, TEFS, STM-LE etc.)

  • All existing TERS geometries are available: illumination / collection from bottom, from top or from side
  • Different SPM techniques and TERS probes can be used: STM, AFM cantilever, quartz tuning fork in tapping and shear force modes
  • Dual scan (for Hot Point Mapping in TERS): scan by sample AND scan by tip / by laser spot
  • Motorized polarization optics to produce optimal polarization for TERS

AFM-Raman measurements can run in air, in controlled atmosphere or in liquid — all with variable temperature (for Inverted configuration)

  • Some features listed are optional — not included into basic system configuration