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Quantum Design OptiCool® Optical Cryostat
7 Tesla Magneto Optical Cryostat
The OptiCool by Quantum Design is a new magneto-optical cryostat using an innovative design that puts the sample volume in the heart of your optical environment. A custom 3.8 inch bore, split-coil, conical magnet offers fields perpendicular to the optical table up to ±7 tesla. The highly integrated design means, even with a magnet, your sample isn’t buried inside a large cryostat, far away from the optics. Seven side optical ports and one top optical port allow for optical access to your sample from a wide array of directions.
The OptiCool optical cryostat is a cryogen-free system with automated software to control temperature and magnetic field. At the push of a button you can change your sample temperature from 1.7 K to 350 K, with or without an applied magnetic field. A generous 89 mm diameter by 84 mm tall sample volume provides exciting possibilities in experiment design.
Possible Applications
- MOKE / CryoMOKE
- Raman / FTIR Spectroscopy
- Photoluminescence
- UV / VIS Reflectivity & Absorption
- AFM / Microscopy
- NV / Colour Defect / Vacancy Centres
- Nanomagnetism
- Time Resolved Magnetic Spectroscopy
- Quantum Optics
- Spintronics
FEATURES
- 8 Optical Access Ports: 7 Side Ports (NA > 0.11) – 1 Top Port (NA > 0.7)
- Temperature Range: 1.7 K to 350 K
- 7 T Split-Coil Conical Magnet
- Low Vibration: <10 nm peak-to-peak
- 89 mm x 84 mm Sample Volume
- Automated Temperature & Magnet Control
- Cryogen Free
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Sample Pods
The OptiCool’s Sample Pod provides a place to build and customise your experiment on the bench. When you are ready to make a measurement, the Sample Pod easily plugs into the pre-wired temperature control column. Having multiple experiments arranged on multiple pods allows you to switch experimental hardware quickly. Sample Pods are available in both a standard configuration and a large-volume configuration depending on the experimental needs. Each type of pod can be further configured by changing the riser pieces (available in three lengths; included with the system) to adjust the height of the mounting plate.
Standard Sample Pod – Allows for mounting plate positions at 56.4 mm, 32.8 mm and 12.4 mm below the magnet centre.
Large-Volume Sample Pod – Allows for mounting plate positions at 131.3 mm, 111.0 mm and 87.4 mm below the magnet centre.
Sample Positioning
Many optical applications require precise positioning of the sample to the optical path for focusing or examination of an area of interest. The ability to scan the sample is also required for 2D imaging of sample properties. To meet these needs the OptiCool cryostat can be configured with a piezo-based nanopositioning stack to move your sample in situ. The nanopositioner option comes with all the adapters needed to mount the nanopositioners onto a pod, specialised cryostat wiring, cabling that can connect to the piezo controller, and a thermal link specifically designed for use in the OptiCool. The nanopositioner stack can be mounted on the standard pod or on the large-volume pod depending on experimental needs.
OptiCool nanopositioner on standard pod
OptiCool nanopositioner on large-volume pod
OptiCool nanopositioner with thermal link
Windows and Objectives
Optical experiments can require a variety of windows and microscope objectives. To address these needs Quantum Design offers window and objective configuration options, including a low working-distance top window option, vacuum objective mounting hardware, and a bottom access window. The low working-distance top window reduces the minimum working distance from 15 mm to about 3 mm between the top of the outer window and the underside of the inner shield window. The hardware allows you to directly mount a wide variety of objectives at close spacing using the included window clamp and standard off-the-shelf adaptor rings. This means you can make adjustments or swap out objectives while the sample remains cold. Quantum Design also offers a Zeiss 100x LD EC Epiplan-Neofluar, infinity-corrected objective mounted inside the cryostat. This objective offers a 0.75 NA and a working distance of 4 mm. A kit is also available to mount your own objectives in vacuum if desired. A bottom access window is available for the cryostat, allowing transmission measurements along the magnet axis, perpendicular to the surface of the optical table.
OptiCool room temperature objective
OptiCool low working-distance window
Testimonials
“Integrating the OptiCool® into my research program will allow for accessing experimental phase space in complex materials that simply wasn’t available to my group in the past. Innovative products advance science and the OptiCool certainly meets this standard.”
Prof. Richard Averitt of the Physics Department at the University of California San Diego
“A lot of my research over the years has been in the far infrared or terahertz. And so I think that the OptiCool® provides a really exciting opportunity to do novel far infrared spectroscopy on materials in a magnetic field environment.”
Prof. Richard Averitt, UC San Diego
Read the Physics World article on the OptiCool
VIDEOS
Downloads
Supplier Info
Publications
High-Mobility Compensated Semimetals, Orbital Magnetization, and Umklapp Scattering in Bilayer Graphene Moiré Superlattices.
Shilov, A., Kashchenko, M., Peralta, P., Wang Y., Kravtsov, M., Kudriashov, A., Zhan, Z., Taniguchi, T., Watanabe, K., Slizovskiy, S., Novoselov, K., Fal’ko, V., Guinea, F., and Bandurin, D. ACS Nano (2024)
Infrared nano-imaging of Dirac magnetoexcitons in graphene.
Dapolito, M., Tsuneto, M., Zheng, W. et al., Nature Nanotechnology (2023)
Correlated Insulator of Excitons in WSe2/WS2 Moiré Superlattices.
R. Xiong, J. H. Nie, S. L. Brantly, P. Hays, R. Sailus, K. Watanabe, T. Taniguchi, S. Tongay, and C. Jin, Science 380, 860 (2023)
Magnetoelectric Coupling in Multiferroics Probed by Optical Second Harmonic Generation.
S. Xu et al., Nat Commun 14, (2023)
Axion Optical Induction of Antiferromagnetic Order.
J.-X. Qiu et al. Nat. Mater. (2023)
