Quantum Design, Inc. VersaLab™ 3 Tesla Cryogen Free Vibrating Sample Magnetometer

3 Tesla, Cryogen-free Physical Property Measurement System

Quantum Design, Inc. VersaLab™ 3 Tesla Cryogen Free Vibrating Sample Magnetometer

VersaLab Optix

VersaLab Optix Breadbord

Quantum Design introduces its first portable, cryogen-free cryocooler-based material characterization platform – VersaLab. With a temperature range of 50 – 400K, this 3 tesla platform is perfect for accomplishing many types of materials characterization in a limited space.

As with all Quantum Design instruments, VersaLab is a fully automated turnkey system with a user-friendly interface, and utilizes technology developed for Quantum Design’s popular Physical Property Measurement System (PPMS®). VersaLab is specifically designed for material characterization up to 3 tesla and over a wide temperature range without the need of liquid cryogens. Utilizing a new approach to cryocooler equipment design, VersaLab employs a new 4He-based temperature control system and gas flow technology that eliminates the need for liquid cryogens.

VersaLab gives the user:



VersaLab Optix is a flexible, modular optical platform that provides "turn-key" measurements and custom built experiments. It is the ideal platform for combining photonics, quantum electronics, optics with electro-transport, and magneto-optic materials characterization measurements at cryogenic temperatures and in magnetic fields of ± 3 T. The optical breadboard allows a wide range of configurable experimental space seamlessly integrated onto the VersaLab. Various light sources, opto-mechanical and imaging components can be easily mounted and coupled to the cryogenic and magnetic field environment of the sample space. By integrating the Optix option onto a VersaLab system, users can perform multiple measurements in a single sweep by combining Quantum Design's existing measurement options with new optical possibilities.

Optional laser light sources (such as Raman or a Xenon Arc lamp) are available for providing the necessary source for excitation beams for optical and spectroscopy experiments. An integrated compact imaging spectrograph and CCD camera controlled directly from the MultiVu system software are also available to automatically collect spectra and sample images as a function of temperature and magnetic field.

Optical Breadboard

PPMS Optix Brochure


PPMS VersaLab and Education

Quantum Design Education is a website dedicated to the use of the PPMS VersaLab for education and research. This site offers free experimental modules highlighting the measurement options available on this platform.


Integrated VersaLab Measurement Applications

PPMS Family Options Compatibility Table

  • Thermal Measurements
  • Magnetometry
  • Electro-Transport
  • High Pressure
  • Spectroscopy
  • Optics

Heat Capacity Option

  • Completely automated relaxation technique from 50 - 400 K
  • Integrated data acquisition electronics and analysis software

Thermal Transport Option

AC Resistivity ρ

  • Measured by using precision DSP current source and phase-sensitive voltage detection.

Thermal Conductivity κ

  • Measured by applying heat from the heater shoe in order to create a user-specified temperature differential between the two thermometer shoes.

Seebeck Coefficient α

  • Measured by creating a specified temperature drop between the two thermometer shoes - just as it does to measure thermal conductivity. However, for Seebeck coefficient the voltage drop created between the thermometer shoes is also monitored.

Thermoelectric Figure of Merit ZT

  • Determined here simply as the algebraic combination α2T /(κρ) of the three measured quantities - thermal conductivity, Seebeck coefficient, and AC electrical resistivity.

Vibrating Sample Magnetometer Option (VSM)

  • RMS Sensitivity: < 10-6 emu with 1 sec averaging
  • Optional VSM Oven up to 1000 K

First Order Reversal Curve (FORC) Measurements Option

  • Provides a quantitative fingerprint of the magnetic reversal mechanisms
  • Fully automated FORC acquisition using MultiVu
  • Preformatted output file for easy import into post-processing software

FORC Measurement Brochure

Torque Magnetometry Option

  • Measures the magnetic torque = mBsinθ
  • Designed to measure moments of very small anisotropic samples
  • Moment Sensitivity: 3 x 10-7 emu at 3T

AC Susceptibility Option (ACMS II)

  • AC Susceptibility
    • Sensitivity: 1 x 10-8 emu
    • Amplitude: 0.005 Oe – 15 Oe (peak)
    • Frequency Range: 10 Hz – 10 KHz
    • Direct phase nulling technique measures and cancels background AC phase shifts at every measurement
  • DC Magnetization
    • Sensitivity: 5 x 10-6 emu

Magneto-Optic Option

Sample Rods:

  • Choice of UV or IR Rod
    • UV >90% transmittance 325 nm - 900 nm
    • IR >90% transmittance 375 nm - 2250 nm
  • Sample holder volume 2.68 mm3
  • Moment Sensitivity <10-4 emu

Light Source:

  • Choice of 150 W or 300 W light source
  • Xenon Arc  Lamp
  • 10 position filter wheel
  • 9 bandpass filters (436 nm, 470 nm, 500 nm, 530 nm, 555 nm, 585 nm, 640 nm, 740 nm, 850 nm)

DC Resistivity Option

  • Four independent channels for performing DC resistivity
  • Temperature Range: 50-400 K
  • Current Range: 2 nA to 8 mA
  • Sample Resistance Range: Up to 5 MOhm

Electrical Transport Option (ETO)

  • For performing AC Resistance, Hall Effect, I-V, and Differential Resistance (dV/dI vs. I) measurements.
  • 1nV sensitivity, 10 nΩ resolution at 100 mA
  • AC and DC drive amplitude 10 nA to 100 mA
  • Resistance ranges from 10 µΩ to 5 GΩ

Horizontal Sample Rotator

  • Thermometer located on rotator platform
  • Precision, stepper controlled rotator
  • Step Size: 0.013 degrees (standard); 0.0011 degrees (high resolution)
  • Angle Range: -10 degrees to 370 degrees

Multi-Function Probe

  • Direct axial ports to the sample stage are provided to install light pipes, fiber optic cables, microwave guides and/or extra electrical leads.

High Pressure Cell for Magnetometry

High Pressure Cell Main KitVSM Cell

Introducing a novel, high pressure cell for magnetometry that allows easier sample insertion and removal without the need of an hydraulic press. This pressure cell, manufactured by HMD, comes in a complete kit that contains all the accessories you will need to aid in the characterization of your samples.

Benefits of the HMD Pressure Cell:

  • All BeCu design for more uniform magnetic background
  • No copper ring seal ensures easy sample removal
  • All necessary accessories conveniently packaged
  • Compatible with VSM transport
  • No hydraulic press necessary


  • Maximum Applied Pressure – 1.3 GPa
  • Sample Space Diameter – 1.7 or 2.2 mm
  • Sample Space Length – 7 mm max
  • Cell Diameter – 8.5 mm
  • Temperature Range – 50 to 400K


** Please Note: Requires VSM and Large Bore Coil Set **

High Pressure Cell for Magnetometry Brochure



Hydrostatic Pressure Cell for Electrical Measurements

Assembled Cell

Introducing a hydrostatic pressure cell for electrical measurements designed for use in all PPMS platform instruments (PPMS, DynaCool, VersaLab) . This pressure cell, manufactured by ElectroLab, is compatible with Quantum Design’s DC Resistivity, ACT and ETO measurement options.

Benefits of the ElectroLab Pressure Cell:

  • Based on BeCu pressure cell technology
  • Integrated external thermometer
  • 10 sample leads (5 twisted pairs)
  • Compatible with all QD PPMS platforms
  • Manufactured by the leading supplier of hydrostatic pressure cells in Japan
  • Several press sets also available


  • Maximum Applied Load – 3.0 GPa
  • Maximum Sample Pressure – 2.7 GPa
  • Sample Space Diameter – 4.0 mm
  • Sample Space Length – 6.0 mm max
  • Temperature Range – 50 to 400K

Hydrostatic Pressure Cell Brochure

Raman & Luminescence Spectroscopy System

Raman and Luminescence Spectroscopy System

Quantum Design's new Spectroscopy System combines Raman and Photo-Luminescence spectroscopy with optical sample imaging in the variable temperature and magnetic field environment of the PPMS. Using this "turn-key" system, gaseous, liquid and solid materials, in bulk or thin film form, may be investigated. Raman spectroscopy is a non-destructive spectroscopic technique used to identify and explore vibrational, rotational, and other excitation modes in a sample. Raman spectroscopy is commonly used to identify crystalline materials by measuring their specific Raman "fingerprint." This is done by measuring the inelastic scattering of light. In crystalline samples, the inelastic gain or loss of energy produces narrow discrete peaks known as Stokes and Anti-Stokes peaks, respectively. Glasses, in contrast, have broad vibrational spectra that in turn give rise to broad Raman spectra. When using the versatile PPMS Spectroscopy System, the study of spin-lattice coupling in strongly correlated oxides as a function of temperature and magnetic field is made easy through the highly automated MultiVu interface.

  • Various Wavelengths (532, 785, and 850 nm)
  • Tilt and Tip control
  • Volume Holographic Grating
  • Ultra-Narrow-Band Notch Filter
  • Compact Footprint


  • Structural Identification
  • Impurity Detection
  • Crystallization Analysis
  • Bulk and Thin Film
  • Stokes and Anti-Stokes Signal

Raman & Luminescence Spectroscopy System Brochure


NanOsc FMR Spectrometers

Quantum Design Taiwan - Products - NanOsc FMR Spectrometers

The CryoFMR spectrometer is a plug and play system that allows broadband CPW-FMR characterization with lock-in capability. It includes its own RF frequency source as well as lock-in detection module, so that the only parts required to conduct an experiment are a computer for software control and a PPMS platform. Temperature range: 50 K to 400 K. Frequency Range 2 to 17 GHz.


Broadband FMR Spectrometers Brochure


Compact Imaging Spectrograph
(Andor Shamrock 193i Spectrograph with iVac 316 CCD)

Compact Imaging Spectrograph

Quantum Design now adds in-situ structural and chemical spectra analysis to PPMS materials characterization measurements at low temperature and high magnetic fields. This ability answers a growing demand in the research community. Offering a wide range of modular interfaces that feature cage system couplers, Quantum Design offers endlessly configurable connections between the Compact Imaging Spectrograph and the PPMS Optical Multi-Function Probe (OMFP). The spectrograph's "wide aperture" slit opens the door to a single set up with the OMFP to image the sample, while also allowing spectral information collection through the same optical path from the microscope.


  • Integrated control and data acquisition through PPMS MultiVu software
  • Dual grating turret with RFID
  • Dual Detector Output
  • Adaptive Focus
  • Pre-aligned and calibrated
  • Compact and rugged design


  • Absorption, Transmission, and Reflection
  • Raman (532, 785, and 850 nm)
  • Fluorescence and Luminescence

Compact Imaging Spectrograph Brochure


Optical Multi-Function Probe (OMFP)

The newly designed Optical Multi-Function Probe (OMFP) offers unprecedented versatility that allows you to conduct photonic, quantum optics and correlative microscopy experiments within the variable temperature and magnetic field environments of the PPMS, DynaCool and VersaLab. The OMFP features a room temperature wired access port with integrated optical breadboard for mounting optical components such as lenses, turning mirrors, filters, diffusers, beam splitters, prisms, waveplates, fiber bundles and electrical wiring. The open modular design of the probe provides easy access to the axial ports and connectors which can be configured to route electrical, single fibers, fiber bundles and miniature waveguides to the sample space. In addition, a central optical access port allows free-beam optics experiments in the cryostat. A 0.5 inch standard optical thread mount makes aligning and focusing lens assemblies fast and easy.

Optical Multi-Function Probe (OMFP)


  • Available for VersaLab, DynaCool and PPMS
  • 1 inch (SM1) free-beam access port and internal 1/2 inch (SM05) optical mounts along optical path
  • Direct axial electrical, SMA and other ports to sample stage provided to install light pipes, fiber optics cables, and/or electrical leads
  • 2 sets of 4 electrical leads on sample PCB interface for electrical transport experiments
  • Multiple measurement capability (e.g., electrical resistivity, Hall effect, Van der Pauw, magnetometry and other optical measurements)
  • Integrated wiring for optional motorized Cartesian positioning system (3 x 3 x 3 mm movement capability)
  • Sample stage with integrated thermometer
  • Multi-Position filter and lens mounts for cold region of probe
  • 300 K to 50 K, ± 3 T (VersaLab); 300 K to 1.8 K, ± 14 T (DynaCool); 300 K to 1.9 K, ± 16 T (PPMS)


Figure 1: Optical positioner capsule with sample boards and extraction tool

Figure 1: Optical positioner capsule with sample boards
and extraction tool.

Figure 2: XYZ cartesian positioning controller

Figure 2: XYZ cartesian positioning controller.


  • Free Optics Studies
  • Fiber Optics Measurements
  • Thermal-Optical Properties
  • Magneto-Optical Properties

Optical Multi-Function Probe and Positioning System Brochure


Cartesian Positioning System

A fully motorized Cartesian sample positioning system can be used with our Optical Multi-Function Probe (OMFP) to focus a laser beam or other excitation source on a particular region of the sample. The Cartesian positioning system provides for an XYZ movement capability of 3 x 3 x 3 mm.

Figure 3: 1951 US Air Force Target mounted on a sample board and image of target taken using optical positioner software integrated into MultiVu
Figure 3: 1951 US Air Force Target mounted on a sample board and image of target taken using optical positioner software integrated into MultiVu

Figure 3: 1951 US Air Force Target mounted on
a sample board and image of target taken
using optical positioner software integrated into MultiVu.

Optical Multi-Function Probe and Positioning System Brochure


Xenon Light Source

OMFP Xenon Light Source
  • Choice of 150 W or 300 W light source
  • Xenon Arc  Lamp
  • 10 position filter wheel
  • 9 bandpass filters (436 nm, 470 nm, 500 nm, 530 nm, 555 nm, 585 nm, 640 nm, 740 nm, 850 nm)


VersaLab Brochure

PPMS Platform Measurement Options (Short) Brochure

VersaLab Service and Application Notes