Material Analysis for Electronics & Semiconductors
Precise characterization of semiconductors, thin films, and electronic components for research, development, and manufacturing
Semiconductors and electronic components form the foundation of modern technologies—from microprocessors and power electronics to sensors, LEDs, and photovoltaic systems. As power density increases and miniaturization advances, so do the demands on material quality, heat dissipation, and reliability.
The development of modern electronics requires a deep understanding of the thermal, electrical, and structural properties of materials. Modern analytical methods provide important information about thermal conductivity, thermal stability, electrical properties, layer structures, and aging processes.
With over 69 years of experience, LINSEIS offers solutions for the characterization of semiconductor materials, thin films, and electronic components in research, development, and industrial quality control.
Typical Applications for Electronics & Semiconductors
Select your specific application and gain detailed insights into material characterization, measurement methods, and innovative solutions for modern electronic systems
Measurement Methods for Electronics & Semiconductors
Laser Flash Analysis (LFA)
Determination of thermal conductivity, temperature conductivity, and thermal diffusion for efficient thermal management in semiconductors and electronic components.
Thin Film Laser Frequency Analyzer (TF-LFA)
Characterization of the thermal properties of thin films and interfaces for modern microelectronics and semiconductor technologies.
Thin Film Analyzer (TFA)
Analysis of the thermal conductivity of ultrathin layers, coatings, and electronic materials for research and process optimization.
Hall Effect Analysis (HCS)
Determination of charge carrier concentration, mobility, and electrical resistance for the development of modern semiconductor materials.
Dynamic Differential Scanning Calorimetry (DSC)
Analysis of phase transitions, heat capacity, and curing reactions in packaging materials, adhesives, and electronic materials.
Simultaneous Thermal Analysis (STA)
Simultaneous analysis of mass changes and thermal effects to investigate the thermal stability and aging processes of electronic materials.
Recommended Equipment for Polymer Applications
Top Devices
Other Devices
CAL L92 - Micro-
calorimeter
DSC L63
IBC L91 - Iso-
thermal
Battery Calorimeter
TEG-Tester (TEG L34)
LSR-3 (LSR L31)
PLH L53 - Periodic Laser Heating
Selected Real-World Measurement Examples
Real-world measurements demonstrate how modern analytical methods are used to solve real-world problems involving polymers.
Optimization of p-GaN Using Hall Effect Measurements
Hall effect measurements allow for the precise determination of charge carrier concentration, mobility, and electrical resistance in semiconductor materials. In this practical example, Mg-doped GaN layers are measured using the LINSEIS HCS L36 to evaluate the influence of doping on the electrical transport properties and performance of modern wide-bandgap semiconductors.
Electrical Transport Properties of Sb₂Te₃ Thin Films
The electrical transport properties of thin films are crucial for the development of modern semiconductor and thermoelectric applications. With the LINSEIS TFA L59 allows for the precise determination of temperature-dependent resistance and charge carrier properties. This practical example demonstrates the characterization of ALD-deposited Sb₂Te₃ thin films and provides important insights into the electrical transport behavior in functional thin-film materials.