We provide access to ICP-MS technology, a highly sensitive, robust, and versatile method for quantifying trace element impurities in a wide range of sample types. This technology is essential for chemistry laboratories as it is often the preferred or mandatory choice in most official standard methods.

ICP-OES (Inductively Coupled Plasma – Optical Emission Spectroscopy) is a simple, accurate, and robust analytical technique for determining the elemental composition of various sample types. This solution is considered the optimal choice for quick and accurate analysis with efficient gas consumption.

Flame Atomic Absorption (Flame AA) is a simple, accurate, and fast atomic spectroscopy technique. This technology has been widely used for decades and is the ideal choice for samples requiring a Limit of Quantitation (LOQ) of approximately 0.5 ppm and above.

Advanced, cost-effective solutions for inorganic elemental analysis. Our featured technologies include commercial analysis techniques that utilize innovative plasma stabilization methods, consuming common compressed gases instead of expensive noble gases like argon. This approach ensures an economical solution for trace element detection.

High-performance spectroscopic systems for fluorescence analysis. These analytical tools are routinely utilized across academic and industrial R&D sectors to characterize materials, coatings, and thin films. They deliver precise measurements essential for in-depth understanding of sample composition and behavior.

Powerful analytical instrumentation for chemical identification and molecular structure determination, specifically utilizing Fourier Transform Infrared (FTIR) Spectroscopy. This highly effective, user-friendly technique offers customers a rapid method to analyze material composition, delivering accurate results based on comprehensive and dedicated spectral databases.

Analytical instruments for UV-Vis Spectrophotometry, a key technique used to measure how substances absorb or transmit light in the ultraviolet and visible spectrums. This methodology is essential in research for comparing the composition and light reactivity of unknown samples against known references.

Solutions based on Raman spectroscopy – a vibrational spectroscopic technique employed for the analysis of the chemical structure and composition of materials. As a non-destructive method, this technology is widely utilized for the identification of raw materials and finished products across various industries worldwide. These instruments are particularly valued for their unique ability to detect and analyze substances directly through transparent and opaque containers.

We provide access to ICP-MS technology, a highly sensitive, robust, and versatile method for quantifying trace element impurities in a wide range of sample types. This technology is essential for chemistry laboratories as it is often the preferred or mandatory choice in most official standard methods.

ICP-OES (Inductively Coupled Plasma – Optical Emission Spectroscopy) is a simple, accurate, and robust analytical technique for determining the elemental composition of various sample types. This solution is considered the optimal choice for quick and accurate analysis with efficient gas consumption.

Flame Atomic Absorption (Flame AA) is a simple, accurate, and fast atomic spectroscopy technique. This technology has been widely used for decades and is the ideal choice for samples requiring a Limit of Quantitation (LOQ) of approximately 0.5 ppm and above.

Furnace Atomic Absorption (FAA), also known as Graphite Furnace Atomic Absorption Spectrometry (GFAAS), is a highly sensitive analytical technique used to measure the concentration of trace elements in various sample types, and is vital for applications in hospitals, research and complex matrices.

Advanced, cost-effective solutions for inorganic elemental analysis. Our featured technologies include commercial analysis techniques that utilize innovative plasma stabilization methods, consuming common compressed gases instead of expensive noble gases like argon. This approach ensures an economical solution for trace element detection.

High-performance spectroscopic systems for fluorescence analysis. These analytical tools are routinely utilized across academic and industrial R&D sectors to characterize materials, coatings, and thin films. They deliver precise measurements essential for in-depth understanding of sample composition and behavior.

Powerful analytical instrumentation for chemical identification and molecular structure determination, specifically utilizing Fourier Transform Infrared (FTIR) Spectroscopy. This highly effective, user-friendly technique offers customers a rapid method to analyze material composition, delivering accurate results based on comprehensive and dedicated spectral databases.

Analytical instruments for UV-Vis Spectrophotometry, a key technique used to measure how substances absorb or transmit light in the ultraviolet and visible spectrums. This methodology is essential in research for comparing the composition and light reactivity of unknown samples against known references.

Solutions based on Raman spectroscopy – a vibrational spectroscopic technique employed for the analysis of the chemical structure and composition of materials. As a non-destructive method, this technology is widely utilized for the identification of raw materials and finished products across various industries worldwide. These instruments are particularly valued for their unique ability to detect and analyze substances directly through transparent and opaque containers.

We provide access to ICP-MS technology, a highly sensitive, robust, and versatile method for quantifying trace element impurities in a wide range of sample types. This technology is essential for chemistry laboratories as it is often the preferred or mandatory choice in most official standard methods.

ICP-OES (Inductively Coupled Plasma – Optical Emission Spectroscopy) is a simple, accurate, and robust analytical technique for determining the elemental composition of various sample types. This solution is considered the optimal choice for quick and accurate analysis with efficient gas consumption.

Flame Atomic Absorption (Flame AA) is a simple, accurate, and fast atomic spectroscopy technique. This technology has been widely used for decades and is the ideal choice for samples requiring a Limit of Quantitation (LOQ) of approximately 0.5 ppm and above.

Furnace Atomic Absorption (FAA), also known as Graphite Furnace Atomic Absorption Spectrometry (GFAAS), is a highly sensitive analytical technique used to measure the concentration of trace elements in various sample types, and is vital for applications in hospitals, research and complex matrices.

Advanced, cost-effective solutions for inorganic elemental analysis. Our featured technologies include commercial analysis techniques that utilize innovative plasma stabilization methods, consuming common compressed gases instead of expensive noble gases like argon. This approach ensures an economical solution for trace element detection.

High-performance spectroscopic systems for fluorescence analysis. These analytical tools are routinely utilized across academic and industrial R&D sectors to characterize materials, coatings, and thin films. They deliver precise measurements essential for in-depth understanding of sample composition and behavior.

Powerful analytical instrumentation for chemical identification and molecular structure determination, specifically utilizing Fourier Transform Infrared (FTIR) Spectroscopy. This highly effective, user-friendly technique offers customers a rapid method to analyze material composition, delivering accurate results based on comprehensive and dedicated spectral databases.

Analytical instruments for UV-Vis Spectrophotometry, a key technique used to measure how substances absorb or transmit light in the ultraviolet and visible spectrums. This methodology is essential in research for comparing the composition and light reactivity of unknown samples against known references.

Solutions based on Raman spectroscopy – a vibrational spectroscopic technique employed for the analysis of the chemical structure and composition of materials. As a non-destructive method, this technology is widely utilized for the identification of raw materials and finished products across various industries worldwide. These instruments are particularly valued for their unique ability to detect and analyze substances directly through transparent and opaque containers.