Lake Shore Cryotronics

Ready to take your high resistance measurements to the next level? Join our informative webinar led by experts at Lake Shore Cryotronics. This comprehensive webinar is designed for beginners and those with an intermediate knowledge of measuring high resistance. In this webinar, we will: ?? Show a demonstration of measuring high resistance ?? Discuss techniques and best practices for high resistance measurements ?? Talk about parasitic capacitance and leakage From demonstrations to discussions on best practices, we've got you covered! See you there on March 13, at 10 a.m. EDT! https://hubs.li/Q036LHdQ0 ?????? #HighResistance #MeasurementTechniques #AdvancingResearch

Here is a Lake Shore fun fact. Did you know that in this research article published by Advanced Science from the Wiley Online Library is about highly efficient room-temperature spin-orbit-torque switching in a van der Waals heterostructure of topological insulator and ferromagnet. Researchers used The M81-SSM synchronous source measure system to measure sheet resistance and hall resistance precisely of heterostructure devices. Their research provided insights into efficient spin-orbit torque devices and the advancement of spintronic functionalities. Read the full research article: https://lnkd.in/ei54ujXC #M81SSM #ElectricalCharacterization #HeterostructureDevices

At Lake Shore Cryotronics, we are more than just a workplace; we are a community! With a strong focus on giving back. Our commitment to social responsibility is woven into the fabric of our culture. And we are dedicated to making a difference for the betterment of our community and science! #AdvancingScience #Careers

Need guidance on how to install a sensor in a cryogenic application and to avoid common installation errors? Then be sure to watch this webinar recording: https://hubs.li/Q02bg4dz0 #MaterialsScience #LakeShoreCryo

The M91 MeasureReady FastHall? controller is truly a game-changer in precision measurement. With its advanced speed and accuracy, it’s perfect for those looking to elevate their experimental setups.

Introducing Infinite Helium—an automated solution that makes your LHe cryostat cryogen?free. Infinite Helium innovatively circulates helium in a closed loop, enabling your continuous flow cryostat to operate without constant helium replenishment. Designed with adaptability in mind, Infinite Helium seamlessly integrates with your existing or new continuous flow cryostats to enable cryogen-free operation. Infinite Helium features: ?? Fully automated—no manual valve adjustments ?? <2.2 K base temperature ?? Low thermal drift ?? Low-vibration ?? 6 months+ continuous run time ?? Automated safety alerts ?? User-intuitive touchscreen interface Learn more about Infinite Helium: https://hubs.li/Q02-WCPV0 #AdvancingScience #CryogenFreeCooling #InfiniteHelium #Lhe

Choose the right cryostat for your application. Our decision tree can help you decide. Download now: https://hubs.li/Q024QlDC0 #Cryostats #LakeShoreCryo

We are having great discussions at TWST Events 2025 Motor, Drive Systems & Magnetics (MDSM) Conference & Exhibition. Join us at Booth #600 to see a demo of our award-winning multi-axis F71 teslameter and our Model 480 fluxmeter with a 2.5-inch Helmholtz coil featuring a field strength of ≈30 G/A.fluxmeter. #MDSM2025

Lake Shore Cryotronics will be at next week’s TWST Events 2025 Motor, Drive Systems & Magnetics (MDSM) Conference & Exhibition in Tallahassee, FL, showcasing the company’s teslameter and fluxmeter instruments. Representatives will have on hand the award-winning multi-axis F71 teslameter with a 3-axis FP Series Hall probe and the Model 480 fluxmeter with a 2.5-inch Helmholtz coil featuring a field strength of ≈30 G/A. Learn more about our presence at MDSM: https://hubs.li/Q036M6Hb0

When studying 2D materials, researchers typically fabricate them into Hall bar structures to characterize their electronic and magnetic properties. For such applications, a four-probe longitudinal resistance measurement is effective at removing resistive contributions from contact or lead resistance, which is particularly important for low?resistance devices. But the situation changes when measuring 2D samples with large contact resistance. Even with a four-probe resistance configuration, common-mode to differential-mode conversion can occur, and this spurious signal conversion can lead to measurement error when performing transport experiments on such materials. Learn more about how to prevent the spurious signal generation from contact resistances, read our new application brief on “Common-mode Artifacts in 2D Materials with Significant Contact Resistance.” In it, we discuss conditions under which common-mode to differential-mode signal conversion becomes problematic and then show ways to mitigate this issue using a balanced current source. Access the application brief: https://hubs.li/Q02RJ7vj0 #AdvancingScience #2DMaterials #DeviceResearch