SVS Labs
SVS Labs
Precision Laboratory Electromagnet Systems

Precision LaboratoryElectromagnet Systems

Research-grade DC electromagnets for Hall-effect measurements, magnetic characterization, magnetoresistance studies, semiconductor testing, and advanced laboratory research.

Why Researchers ChooseSVS Labs

SVS electromagnets are engineered for modern research laboratories. Delivering high performance with simplified installation, lower costs, and minimal infrastructure.

Annotated SVS Labs EMU-75 electromagnet feature diagram

No External CoolingRequired

Eliminating additional infrastructure, maintenance, and operating expenses.

Up to 67% Lower Acquisition Cost

Compared with many comparable electromagnet systems available in North America.

SVS Labs electromagnet with airflow cooling visualization

For more than 40 years, SVS Labs electromagnets have supported universities, government laboratories, industrial R&D facilities, and advanced research programs worldwide.

Lower Installation
Cost

Simplified setup with no auxiliary cooling systems reduces initial investment.

Lower Operating
Cost

Energy-efficient design and no water-cooling overhead result in lower operating expenses.

Reduced Infrastructure
Needs

No need for chiller units, cooling towers, or complex plumbing infrastructure.

Easier Lab
Integration

Compact, self-contained systems integrate easily into new or existing laboratory setups.

Lower Maintenance
Requirements

Fewer components and no water system mean less maintenance and higher system uptime.

Faster Research
Deployment

Energy-efficient design and no water-cooling overhead result in lower operating expenses.

Laboratory background

Choose theRight Electromagnetfor Your Research

Compare field strength, air-gap flexibility, automation options, and application suitability.

EMU-50

Compact Precision Electromagnet

Features

  • 50 mm Poles
  • Up to 7.5 kG Magnetic Field
  • 0—45 mm Air Gap
  • Compact Precision Laboratory Electromagnet
  • Ideal for Teaching Labs and Compact R&D

Best For

Teaching LabsTeaching Labs
Compact R&DCompact R&D
University ResearchUniversity Research
View DetailsView EMU-50 Details
EMU-50 Compact Precision Electromagnet

EMU-75

High Field Electromagnet

Features

  • 75 mm Pole
  • 1.5 T Field
  • Air-Cooled Design
  • Perfect for mid-scale research

Best For

Teaching LabsTeaching Labs
Compact R&DCompact R&D
University ResearchUniversity Research
View DetailsView EMU-75 Details
EMU-75 High Field Electromagnet

EMU-50 vs EMU-75Comparison

FeaturesEMU-50EMU-75
Pole Diameter50 mm75 mm
Max Field (Standard)Up to 7.5 kGUp to 2.5 Tesla
Max Field (Tapered)Up to 2.5 Tesla
Air Gap0 — 45 mm0 — 75 mm
Ideal ForTeaching Labs, Compact R&D SetupsAdvanced Research, R&D, Materials Science
AutomationDPS-50 / DPS-175-C2 AvailableDPS-175-C2 Advanced Automation

Lower Total Cost Of Ownership

SVS Labs electromagnets eliminate the need for external water cooling systems, reducing installation complexity, operating expenses, maintenance requirements, and long-term ownership costs.

Cost FactorTypical AlternativeSVS Labs EMU Series
Initial Equipment CostHigherSignificantly Lower
External CoolingOften RequiredNot Required
Cooling MaintenanceRequiredNone
Energy ConsumptionHigherLower
Long-Term ReliabilityVariesProven Over 40 Years
Field Return HistoryVariesVirtually Zero Returns

Magnetic FieldPerformance vs. Pole Gap

EMU-50 and EMU-75 magnetic field strength across common pole gap configurations.

EMU-50 Air Gap vs Field
EMU-75 Air Gap vs Field
EMU-50 Tapered Pole Performance
EMU-75 Tapered Pole Performance

Need DetailedEngineering Data?

Download field mappings, uniformity measurements, calibration reports, and technical specifications.

See All Graphs
Engineering Data Documents

Tailoring the Magnetic Field toYour Experiment

From high-field tapered poles to optical-access pole pieces, SVS Labs electromagnets can be configured for specialized research applications.

High-field tapered pole design

High-Field Tapered Poles

Increase magnetic flux density by concentrating the magnetic field into a smaller working area for higher localized field strengths.

  • Standard poles: ~1T at 10 mm gap
  • Tapered poles: >2.5T at 5 mm gap
  • Ideal for Hall Effect, materials science, and high-field measurements
  • Optimized for Advanced Research

Optical-Access Pole Designs

Machined apertures through the pole pieces allow light, laser beams, or optical probes to pass directly through the magnetic field region.

  • Magneto-optic experiments
  • Optical spectroscopy
  • Laser-based measurements
  • Photonics research
  • Biological tissue studies
Optical-access pole design
Custom research configuration

Custom Research Configurations

SVSLabs routinely provides custom pole geometries and experimental fixtures to support specialized research requirements.

  • Custom pole diameters
  • Pole apertures
  • Extended pole pieces
  • Specialized sample access
  • Application-specific configurations
Custom pole configuration background

Need a Custom Pole Configuration?

Our engineering team can design custom pole geometries and experimental features tailored to your research requirements.

Proven ScientificResearch Operation

Trusted by universities, government laboratories, and industrial R&D organizations worldwide. Our electromagnets have supported advanced magnetic field research for more than four decades with virtually zero product returns.

40+
Years
Virtually Zero
Returns
No External
Cooling
Up To 2.5
Tesla

Trusted By ResearchersWorldwide

Supporting universities, government laboratories, and advanced research facilities for more than 40 years.

Ben Ko - Researcher
Ben Ko
Researcher and a Doctoral Candidate
StarStarStarStarStar
4.9
UCI Logo
Quote

We have been using the Electromagnet and Constant Current Power Supply from SVSLabs for the past few months, and we couldn't be happier with our choice.

Applications AcrossScientific Research

SVS Labs electromagnets enable precise, reliable results across a wide range of research applications.

Hall Effect Research Setup

Hall Effect Research

Measure carrier concentration, mobility, and semiconductor properties with high precision magnetic fields.

Magneto-Optic Experiments

Enable Faraday rotation measurements and advanced optical characterization studies in controlled magnetic field environments.

Magneto-Optic Experiments Setup
Semiconductor research setup

Semiconductors

Support device development and materials investigation.

Materials Research

Study magnetic behavior and material response under controlled conditions.

Materials research setup
Sensor calibration setup

Sensor Calibration

Generate stable and uniform magnetic fields for sensor testing and calibration.

Thin film characterization setup

Thin Film Characterization

Evaluate the magnetic and electrical properties of thin-film materials for advanced materials science and semiconductor research.

University Teaching Labs

Ideal for advanced laboratory education, hands-on training, and scientific demonstrations in academic research environments.

University teaching laboratory

Download TechnicalResource Package

Get everything you need in one place. The EMU-50 & EMU-75 Technical Resource Package includes datasheets, engineering curves, drawings, and supporting documentation.

Download Resources Package
Technical resource package documents

Related ResearchExperiments

Explore common experiments and measurement systems supported by SVS Labs electromagnets.

Hall effect experiment setup

Hall Effect Experiment

Determine Hall coefficient and carrier concentration of semiconductor samples.

Magnetoresistance experiment setup

Magnetoresistance Experiment

Analyze changes in electrical resistance of materials under varying magnetic field strengths.

Faraday rotation experiment setup

Faraday Rotation Experiment

Study polarization rotation and magneto-optic interactions in various materials.

Let's Buildthe Right Solution for
Your Research

Our engineering team can help you select the optimal electromagnet configuration for your application.