LabRAM Soleil Nano for Real-time and Direct Correlative Nanoscopy

LabRAM Soleil Nano for Real-time and Direct Correlative Nanoscopy from Horiba is a completely combined system based on the OmegaScope scanning probe microscope and LabRAM Soleil Raman microscope. LabRAM Soleil Nano provides unparalleled abilities for photoluminescence and direct co-localized AFM-Raman measurements.

AFM imaging modes (electrical, topographic, mechanical, etc.) and Raman acquisition could be executed sequentially or concurrently at the same location of the sample surface. Optical nano-resolution is achievable with Photoluminescence (TERS/TEPL) and Tip-Enhanced Raman Spectroscopy.

LabRAM Soleil Nano is consistent with the environmental chamber for AFM and Raman measurements in a controlled atmosphere and at low temperatures.

Characteristics

Multi-Sample Analysis Platform

Macro, micro, and nanoscale measurements can be conducted on the same AFM-Raman platform.

Multi-Technique/Multi-Environment

Several SPM (scanning probe microscopy) modes, such as AFM, force curves measurements, conductive and electrical modes (KPFM, cAFM,), STM, liquid cell and electrochemical environment, collectively with chemical mapping via TERS/TEPL.

Complete control of the acquisition via one workstation and strong software control. SPM and Raman or PL microscope could be made in an independent or simultaneous manner.

Compatible with the AFM chamber available for humidity control, environmental control, and cooling sample holder.

Robustness/Stability

High resonance frequency AFM scanners. High performance is achieved without active vibration isolation.

Ease-of-Use

Completely automated operation, start quantifying within a matter of minutes.

High Collection Efficiency

Top-down and oblique Raman/PL detection are available with high numerical aperture objectives for utmost resolution and throughput in both co-localized and tip-enhanced measurements (Photoluminescence and Raman).

High Throughput Multimodal UV-VIS-NIR Achromatic Platform

Developed for Photoluminescence, Raman, Electroluminescence, and more.

Up to four internal lasers and six different filters are available; four-grating turret.

High Spatial Resolution

Nanoscale spectroscopic resolution (down to 10 nm) via Tip-Enhanced Optical Spectroscopies (TERS: Tip-Enhanced Raman Spectroscopy, and TEP: Tip-Enhanced Photoluminescence).

Super-Low Cut-Off Frequency

Down to 30 cm^-1 with high throughput.

Ultrafast Raman Imaging

SmartSampling^™-100 times faster Raman maps - hours of work are converted into minutes

3D Raman lightsheet confocal imaging with patented Q-Scan^™

Specifications

SmartSPM Scanner and Base

Scanning type by sample: XY non-linearity 0.05 %; Z non-linearity 0.05 %

Sample scanning range: 100 µm × 100 µm × 15 µm (±10 %)

Noise: 0.1 nm RMS in XY dimension in 200 Hz bandwidth with capacitance sensors on; 0.02 nm RMS in XY dimension in 100 Hz bandwidth with capacitance sensors off; < 0.04 nm RMS Z capacitance sensor in 1000 Hz bandwidth

X, Y, Z movement: Digital closed loop control for X, Y, Z axes; Motorized Z approach range is to around 18 mm

Resonance frequency: XY: 7 kHz (unloaded); Z: 15 kHz (unloaded)

Sample positioning: Tracked sample positioning range 5 × 5 mm

Sample size: Maximum 40 × 50 mm, thickness of 15 mm

Positioning resolution: 1 µm

AFM Head

Registration system noise: Down to < 0.1 nm

Alignment: Completely automated cantilever and photodiode alignment available

Laser wavelength: 1300 nm, non-interfering with spectroscopic detector

Probe access: Free access to the probe for additional external manipulators and probes

SPM Measuring Modes

Contact AFM in air/(liquid optional); Semicontact AFM in air/(liquid optional); Non-contact AFM; Lateral Force Microscopy (LFM); Phase imaging; Conductive AFM (optional); Force Modulation; Magnetic Force Microscopy (MFM); Capacitance and Electric Force Microscopy (EFM); Nanomanipulation; STM (optional); Volt-ampere characteristic measurements (optional); Kelvin Probe (Surface Potential Microscopy, SKM, KPFM); Force curve measurement; Piezo Response Photocurrent Mapping (optional); Force Microscopy (PFM); Nanolithography.

Spectroscopy Modes