EMC2T: 2 Tesla Variable Info

EMC2T : 2 Tesla Variable Gap C‑Frame Electromagnet

The CRYONANO EMC2T is a compact 2 Tesla variable-gap C‑frame dipole electromagnet engineered for laboratory-scale magnetic field experiments. Featuring water‑cooled coils and a wide, adjustable pole gap, it enables stable, high-field operation while accommodating cryostats and auxiliary experimental hardware.

Designed for low‑temperature research and precision magneto‑electronic studies, the EMC2T delivers reliable field generation for a broad range of condensed‑matter and spin‑based experiments.

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Features

The system features a precision-machined U-frame that provides a stable magnetic circuit, paired with high-quality coils engineered for efficient field generation and thermal reliability. Interchangeable pole caps shape and optimize the magnetic field at the sample region, while the integrated pole adjuster allows smooth and accurate control of the pole gap to suit different experimental setups. Clearly defined electrical and sensor connections enable safe power delivery and field monitoring for repeatable operation. Mounted on a mobile base for easy positioning, the EMC2T combines structural rigidity, precise adjustability, and user-friendly integration ; making it a dependable platform for advanced magnetic, low-temperature, and magneto-optical research applications.

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This schematic highlights the robust mechanical and functional design of the EMC2T C-frame electromagnet.

The compact, EMC2T is ideal for small scale laboratory-based, wide range of experiments.

Some possible applications of the Electromagnets are:

Hall/ Spin Hall Effect Measurements
Magnetic susceptibility & Hysteresis Studies
Magneto-transport - Magneto caloric effect, Magneto Resistance Measurements etc.
Magneto-dielectric Studies
Magneto Optical Measurements
Magnetic Resonance Experiments

The electromagnet is powered by a state-of-the-art bipolar, 4-quadrant power supply. This advanced unit, based on IGBT technology, can seamlessly source or sink power, making it ideal for driving large inductive loads. It allows for smooth polarity reversal and precise control down to zero output. Optimized for low ripple and noise even in switch mode operation, its regenerative design feeds energy back to the mains instead of dissipating it as heat, significantly increasing efficiency. This versatile supply can also function as either a constant voltage or a constant current electronic load.

General Specifications

Applications

Designed for precision cryogenic and quantum mesurements

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2 Tesla Field Strength

Generates stable magnetic fields up to 2 T for demanding laboratory experiments.

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Variable Pole Gap

Adjustable gap accommodates samples, cryostats, and optical access requirements.

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C‑Frame Dipole Geometry

Open mechanical design allows easy sample access and integration of ancillary equipment.

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Water-Cooled Coils

Efficient thermal management enables continuous operation at high fields.

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Compact Footprint

Optimized for small‑scale laboratory environments without compromising performance.

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USB Control & Automation

Supports electrical, optical, and transport measurements under applied magnetic fields..

Electromagnet Field Excitation Plot

This field uniformity profile highlights the EMC2T electromagnet’s ability to maintain a highly stable magnetic field across the usable pole region. The graph shows that the field remains nearly constant around the center of the gap, with only minor variation as the measurement position moves away from the midpoint. This high degree of uniformity ensures that samples experience a consistent magnetic environment, which is critical for accurate and repeatable results in precision experiments.

By minimizing spatial field variations, the EMC2T supports reliable Hall measurements, magnetic susceptibility studies, magneto-transport, magneto-optical experiments, and other applications where field homogeneity directly impacts data quality. The result is greater experimental confidence, improved reproducibility, and more dependable research outcomes.

This performance curve illustrates how the EMC2T electromagnet’s magnetic field strength varies with pole gap distance. As the pole distance increases, the magnetic field gradually decreases, reflecting the natural trade-off between available working space and achievable field strength. Even at larger gaps, the system maintains strong and usable magnetic fields, enabling researchers to accommodate bulky samples, cryostats, or probe assemblies without sacrificing experimental capability. This predictable and well-characterized behavior allows users to confidently select the optimal gap setting for their application, whether prioritizing maximum field intensity or greater physical access.

The result is a highly versatile electromagnet platform suited for Hall measurements, magneto-transport, susceptibility studies, and a wide range of low-temperature and magneto-optical experiments.

The EMC2T variable-gap C-frame dipole electromagnet delivers precise and reliable magnetic field control for advanced laboratory and industrial research. As illustrated by its field-vs-current performance, the system provides a smooth, predictable increase in magnetic field with current, enabling accurate tuning for sensitive experiments. Multiple operating curves reflect its flexible pole-gap configurations, allowing users to balance maximum field strength with the larger gaps needed to accommodate cryostats, probes, and ancillary equipment.

The magnet is engineered to maintain strong fields across a wide operating range while managing magnetic saturation effectively at higher currents. This combination of high performance, gap flexibility, and field stability makes EMC2T ideal for Hall and Spin Hall measurements, magnetic susceptibility and hysteresis studies, magneto-transport, magneto-optical research, EPR, MOKE, and other precision applications.

Benefits

Enables high-field experiments in space-constrained laboratories
Delivers up to 2 Tesla in a compact footprint, allowing advanced magnetic research without requiring large dedicated facilities.

Simplifies integration with cryostats and low-temperature setups
Adjustable pole gaps and optical access make it easy to couple with cryostat tails and specialized low-temperature measurement systems.

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Provides stable, repeatable magnetic fields for precision measurements
The four quadrant power supply ensures smooth polarity reversal and low ripple, enabling highly accurate and reproducible data.

Supports a wide range of magneto-electrical and magneto-optical techniques
Suitable for Hall effect, magneto-resistance, magneto-optical, and magnetic resonance experiments across research domains.

Reduces thermal limitations through efficient water cooling
Water-cooled copper coils allow continuous high-current operation while maintaining safe operating temperatures.

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