Precision Kerr Microscope Cryo MOKE System For Magnetization Imaging Of Spintronic Materials

Product Description:

The Cryogenic High-Magnetic-Field Laser Kerr Microimaging System is a cutting-edge instrument designed for researchers and scientists working with low temperature Kerr microscopy applications. This advanced system offers exceptional temperature stability with a range of ±50 mK, ensuring precise and reliable measurements even in demanding experimental conditions.

Featuring a high Kerr angle resolution of 0.5 mdeg (RMS), the system enables researchers to accurately analyze weak magnetic materials and perform detailed magnetization measurements with unparalleled precision. The included objectives provide flexibility and versatility, with magnification options of 5*, 20*, 50*, and 100*, as well as a non-magnetic objective for specialized applications.

One of the key highlights of this system is its magnetic field resolution capability, which is achieved through PID closed-loop feedback regulation with a resolution of 0.05 mT. This precise control over magnetic fields allows researchers to study magnetic properties of materials with exceptional control and accuracy, opening up new possibilities for groundbreaking research in the field of magnetism.

Moreover, the Cryogenic High-Magnetic-Field Laser Kerr Microimaging System offers a variable temperature range from 4.2 K to 420 K, catering to a wide range of experimental requirements and allowing researchers to study material behavior across different temperature regimes. This temperature versatility is essential for investigating the thermal properties of materials and understanding how they respond to temperature changes.

In summary, the Cryogenic High-Magnetic-Field Laser Kerr Microimaging System is a sophisticated instrument that excels in the analysis of low temperature Kerr microscopy applications. With its exceptional temperature stability, high Kerr angle resolution, versatile objectives, precise magnetic field regulation, and variable temperature range, this system is a valuable tool for researchers seeking to explore the magnetic properties of materials and conduct detailed magnetization measurements in a controlled laboratory setting.

Features:

• Product Name: Cryogenic High-Magnetic-Field Laser Kerr Microimaging System
• Electrical Source Meter:
  • SR830
  • Keithley 6221
  • Keithley 2182 A
• Kerr Angle Resolution: 0.5 Mdeg (RMS)
• Optical Resolution: 450 Nm
• In-Plane Magnetic Field:
  • Water-cooled Magnet
  • 1 T @ air Gap 18 mm at Room Temperature
  • 0.75 T @ air Gap 28 mm at Low Temperature
• Variable Temperature Range: 4.2 K - 420 K

Technical Parameters:

Applications:

Product Application Occasions and Scenarios for the Truth Instruments Cryogenic High-Magnetic-Field Laser Kerr Microimaging System (Model: KMPL-L) :

Brand Name: Truth Instruments

Model Number: KMPL-L

Place Of Origin: CHINA

In-Plane Magnetic Field: Water-cooled Magnet, 1 T@air Gap 18 Mm At Room Temperature; 0.75 T@air Gap 28 Mm At Low Temperature

Objectives: 5*, 20*, 50*, 100*, Non-magnetic

Kerr Angle Resolution: 0.5 Mdeg (RMS)

Temperature Stability: ±50 MK

Optical Resolution: 450 Nm

Product Application Scenarios:

- Magnetization measurement in various materials

- Low temperature magnetic characterization studies

- High-resolution imaging in low temperature environments

- Kerr microimaging analysis at cryogenic temperatures

- Research and development of materials with specific magnetic properties

This Cryogenic High-Magnetic-Field Laser Kerr Microimaging System by Truth Instruments (Model: KMPL-L) is designed for precise magnetization measurement and low temperature magnetic characterization. With its in-plane magnetic field capabilities and high Kerr angle resolution of 0.5 Mdeg (RMS), this system is ideal for studying materials at different magnetic field strengths and temperatures.

Researchers and scientists can utilize this system for in-depth analysis of materials in low temperature environments, exploring magnetic properties with non-magnetic objectives and achieving optical resolution of 450 Nm. The ±50 MK temperature stability ensures reliable and accurate results in various research scenarios.