What is Infrared Spectroscopy?
Infrared spectroscopy is an analytical technique used to study how infrared radiation interacts with matter. This technique involves measuring the absorption of infrared light by a sample, which provides information about the molecular composition and structure of the substance being analyzed.

What is Infrared Spectroscopy Used For?
Infrared spectroscopy is a versatile tool used to identify and study chemical substances in various states—solid, liquid, or gas. It is commonly employed in fields such as chemistry, biology, environmental science, and materials science to analyze molecular bonds, identify compounds, and monitor chemical reactions.
What Does Infrared Spectroscopy Tell You?
Infrared spectroscopy provides valuable information about molecular groups within a sample. By detecting the absorption of infrared radiation at specific wavelengths, it helps identify functional groups and molecular structures. This technique is useful for qualitative and quantitative analysis of complex mixtures.
How Much Does an Infrared Spectroscopy System Cost?
The cost of an infrared spectroscopy system can vary based on factors such as brand, features, and performance. For a detailed quote on Optosky FT-IR spectrometers, please contact us directly.
How Does Infrared Spectroscopy Work?
Infrared spectroscopy works by measuring the absorption of infrared light by a sample. When infrared radiation passes through a sample, specific wavelengths are absorbed by molecular bonds, creating an absorption spectrum. This spectrum reveals information about the molecular composition and structure of the sample.
How to Choose an Infrared Spectroscopy System?
  1. Brand Reputation: Look for a well-established brand with a good reputation for reliability and performance.
  1. Performance: Assess the performance specifications of the infrared spectrometer, including resolution, sensitivity, and accuracy.
  1. Service and Support: Consider the level of customer support and service provided by the manufacturer or distributor.
Where to Buy Infrared Spectroscopy Systems?
You can purchase Optosky FT-IR spectrometers directly from the Optosky website or through our local distributors. Our systems are available with comprehensive support and service options.
Why Choose Optosky Infrared Spectroscopy?
Optosky is a trusted name in infrared spectroscopy, known for delivering high-performance solutions at a competitive cost. Our FT-IR and ATR spectrometers offer advanced features and reliable results, making them ideal for various analytical applications. Optosky's commitment to quality ensures that you receive a cost-effective solution without compromising on performance.

Optosky FT-IR Spectrometer: Advanced Performance with Cost-Effective Solutions

Optosky’s FT-IR spectrometer sets a new standard in infrared spectroscopy with its superior performance and user-friendly features, offering an impressive alternative to high-end systems like those from Bruker. Here’s how Optosky stands out:

  • Spectral Range: 7800–350 cm⁻¹, covering a broad range of infrared wavelengths for comprehensive analysis.
  • Resolution: <1 cm⁻¹, ensuring high precision in spectral data.
  • Signal-to-Noise Ratio (SNR): 40,000:1, delivering clear and accurate measurements.
  • Measurement Time: Only 1 minute per sample with a peak-to-peak resolution of 4 cm⁻¹.
  • Wavenumber Accuracy: <0.01 cm⁻¹ and Wavenumber Precision: <0.1 cm⁻¹, guaranteeing reliable and repeatable results.
  • Modular Design: Optional plug-and-play measurement modules for easy replacement and upgrades.
  • Battery Life: Built-in lithium battery with >8 hours of operational life for extended use.
  • Power Requirements: AC220V / 50Hz for versatile setup options.
  • Analysis Time: Approximately 5 seconds, offering rapid data acquisition.
  • System: Runs on Windows 10 for seamless integration with your existing IT infrastructure.
  • Software: Comprehensive suite including infrared control, spectrum processing, multi-component quantitative analysis, auto-inspection software, advanced macro programming, and continuous online monitoring of optical components (e.g., laser light source, sensor, beam splitter) to ensure optimal performance. The software also features automatic removal of air, water, and CO₂ for enhanced accuracy.
  • GMP Compliance: Fully compliant with GMP and 21CFR 11 regulations, ensuring adherence to industry standards.

Optosky’s FT-IR spectrometer combines high performance with cost efficiency, making it a practical choice for both research and industrial applications. With its advanced features and competitive pricing, it offers an exceptional value compared to traditional high-end systems like Bruker FT-IR spectrometers.


How to Select a Suitable FT-IR Spectrometer?

FT-IR Spectrometer Selection Questionnaire

To help us recommend the most suitable FT-IR spectrometer for your needs, please provide the following information:

  1. Desired Spectral Range:

    • Mid-IR
    • NIR
    • Both
  2. Primary Focus of Analysis:

    • Physical analysis
    • Chemical analysis
    • Both
  3. Intended Usage:

    • Laboratory setting
    • Field applications
  4. Application Type:

    • Scientific-grade research
    • Industrial-grade applications
  5. Type of Analysis:

    • Online process analysis
    • Static (batch) analysis
  6. Type of Analysis Required:

    • Qualitative analysis
    • Quantitative analysis
    • Both
  7. Sample Types:

    • Solids
    • Liquids
    • Gases
    • All of the above

Please fill out the questionnaire and send it to us to receive a tailored recommendation for the FT-IR spectrometer that best suits your needs.


What's FT-IR Spectrometer Applications?

  1. Pharmaceuticals:

    • Raw Material Identification: Confirm the identity and purity of pharmaceutical ingredients.
    • Functional Group Analysis: Identify and characterize functional groups in synthetic and natural products.
    • Contaminant Analysis: Detect and quantify contaminants in pharmaceutical products.
  2. Cosmetics:

    • Material Identification: Verify the composition of cosmetic ingredients.
    • Contaminant Analysis: Ensure safety by identifying contaminants in cosmetic products.
  3. Food Products:

    • Raw Material Identification: Verify ingredients and raw materials used in food production.
    • Packaging Material Analysis: Ensure packaging materials meet safety and regulatory standards.
    • Contaminant Analysis: Detect contaminants to ensure food safety.
  4. Environmental Analysis:

    • Water Analysis: Assess contaminants and pollutants in water sources.
    • Soil Analysis: Detect pollutants and contaminants in soil samples.
    • Exhaust Gas Analysis: Monitor emissions and pollutants from industrial processes.
    • Particle Measurement: Analyze particles in water or air for environmental monitoring.
    • Asbestos Analysis: Identify asbestos fibers in environmental samples.
    • Oil in Water Analysis: Quantify oil contamination in water sources.
  5. Chemicals and Polymers:

    • Raw Material Identification: Verify chemical and polymer compositions.
    • Qualitative Analysis: Characterize plastics and rubber materials.
    • Functional Group Analysis: Identify functional groups in synthetic polymers.
    • Surface Preparation Agents: Analyze agents used in surface treatments.
    • Thin Film Analysis: Measure thickness and composition of thin films.
    • Catalyst Analysis: Assess catalyst composition and performance.
    • Paints and Coatings Analysis: Evaluate composition and quality of paints and coatings.
    • Contaminant Analysis: Detect contaminants in chemical and polymer products.
    • Quantitative Analysis: Measure concentration and purity of substances.
    • Recycling Analysis: Analyze materials for recycling processes.
  6. Electrical, Electronics, and Semiconductors:

    • Epitaxial Film Measurement: Measure thickness of epitaxial films.
    • Oxygen and Carbon Analysis: Quantify interstitial oxygen and substituted carbon.
    • Phosphorus and Boron Analysis: Analyze phosphorus and boron in BPGS.
    • Hydrogen Concentration: Measure hydrogen levels in nitride and amorphous silicon films.
    • Flame Retardant Detection: Detect brominated flame retardants to meet RoHS standards.
    • Semiconductor Gas Analysis: Analyze gases used in semiconductor manufacturing.
    • Thin Film Analysis: Evaluate thin films for quality and composition.
    • Contaminant Analysis: Detect contaminants affecting electronic components.
  7. Automobiles:

    • Material Identification: Verify materials used in automotive manufacturing.
    • Contaminant Analysis: Identify contaminants that may affect vehicle performance.
    • Failure Analysis: Analyze components to determine causes of failure.
  8. Metals:

    • Thin Film Analysis: Measure and analyze thin films on metal plates.
    • Contaminant Analysis: Detect contaminants in metal products.
  9. Construction:

    • Material Identification: Verify materials used in construction.
    • Coating Degradation Analysis: Assess the degradation of coatings over time.
  10. Academia:

    • Research & Development: Support advanced research and experimental analysis.
    • Educational Laboratories: Facilitate learning and practical experience in laboratory settings.