
Water Testing
Water is essential to life, playing a vital role in human health, environmental sustainability, and industrial processes. Ensuring water quality through reliable water testing services is critical for safeguarding drinking water supplies, monitoring environmental health, and maintaining regulatory compliance. Whether it’s tap water, groundwater, surface water, or wastewater, testing for contaminants such as heavy metals, nitrates, bacteria, and pesticides is key to identifying potential health risks and ensuring water meets safety standards. With increasing concerns about pollution, aging infrastructure, and environmental changes, accurate water analysis has never been more important to protect communities, ecosystems, and industries.
At our water testing laboratory, we specialize in comprehensive testing solutions tailored to meet the needs of businesses, homeowners, and environmental agencies. From testing for lead in drinking water to assessing industrial wastewater for compliance with environmental regulations, our advanced techniques provide detailed and reliable results. Whether you’re concerned about your home’s water quality, managing industrial discharge, or protecting natural resources, our services are designed to provide the insight and assurance you need. Trust us to help you maintain safe, clean water through professional water testing that meets the highest standards.

Tap Water
Testing tap water ensures it meets regulatory standards for safe human consumption, free from harmful contaminants such as lead, chlorine byproducts, and pathogens. Regular monitoring also helps identify potential issues in the distribution system, such as pipe corrosion or contamination from external sources.
Surface Water
Surface water testing is vital for assessing the health of rivers, lakes, and reservoirs, which are often sources of drinking water and support aquatic ecosystems. It helps detect pollutants like agricultural runoff, industrial waste, and microbial contamination, ensuring environmental sustainability and water quality for downstream users.
Ground Water
Groundwater testing identifies contaminants such as nitrates, heavy metals, and pesticides that can seep from agricultural or industrial activities. Since groundwater is a major source of drinking water globally, regular testing is essential to detect natural contaminants like arsenic and safeguard long-term water safety.
Mineral Water
Testing mineral water ensures it meets quality standards and accurately reflects its claimed mineral content, providing health benefits to consumers. It also verifies the absence of contaminants like bacteria, heavy metals, or plastics, ensuring safety and consumer trust in bottled water products.
Water Analysis Techniques
pH Measurement
pH measurement determines the acidity or alkalinity of water on a scale of 0 to 14, with values below 7 indicating acidity and above 7 indicating alkalinity. Maintaining proper pH levels is essential for industrial, agricultural, and domestic water use, as extreme pH levels can corrode infrastructure or harm aquatic life. pH meters provide accurate readings, allowing for effective monitoring and adjustment to ensure water quality standards are met.
TDS Measurments
Total Dissolved Solids (TDS) measurement quantifies the concentration of dissolved inorganic and organic substances in water, such as salts, minerals, and metals. TDS levels are crucial indicators of water purity, impacting taste, suitability for consumption, and effectiveness in industrial processes. A TDS meter uses electrical conductivity to provide a fast and reliable estimation of dissolved solids, ensuring water meets the required quality standards.

Inductively Couples Plasma Optical Emission Spectroscopy
Inductively Coupled Plasma Optical Emission Spectroscopy (ICP-OES) is a versatile analytical technique widely used for detecting and quantifying trace elements in water. By exciting atoms and ions in a high-energy argon plasma, it measures the characteristic light emissions of various elements, enabling rapid, multi-element analysis. ICP-OES is particularly valued for its cost-effectiveness and robustness, handling high total dissolved solids (TDS) and complex water matrices better than some alternatives. Its broad dynamic range makes it ideal for analyzing both trace and higher concentrations of metals in drinking water, wastewater, and environmental samples.
Compared to Inductively Coupled Plasma Mass Spectrometry (ICP-MS), ICP-OES offers less sensitivity, making it less effective for detecting ultra-trace contaminants like lead or arsenic at parts-per-trillion levels. While ICP-MS excels in applications requiring extremely low detection limits or isotope analysis, ICP-OES remains a reliable choice for routine water testing where higher throughput and lower operational costs are priorities. However, ICP-OES is susceptible to spectral interferences from overlapping emission lines, which can limit its accuracy for complex or highly specific analyses.
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Inductively Coupled Plasma Mass Spectrometry
Inductively Coupled Plasma Mass Spectrometry (ICP-MS) is a powerful analytical technique renowned for its exceptional sensitivity and precision in detecting trace and ultra-trace elements in water. By ionizing samples in a high-energy argon plasma and separating ions based on their mass-to-charge ratios using a mass spectrometer, ICP-MS achieves detection limits in the parts-per-trillion (ppt) range. This makes it the method of choice for applications requiring the identification and quantification of minute concentrations of elements like lead, arsenic, or cadmium. Additionally, ICP-MS can perform isotopic analysis, which is invaluable in environmental studies, geochemical research, and industrial forensics.
Compared to Inductively Coupled Plasma Optical Emission Spectroscopy (ICP-OES), ICP-MS offers unparalleled detection limits but comes with higher operational costs and greater complexity. While ICP-OES is more robust in handling samples with high total dissolved solids (TDS), ICP-MS is more susceptible to matrix interferences, requiring advanced techniques such as collision or reaction cells to mitigate them. Despite these challenges, ICP-MS is favored for its broad elemental coverage, rapid analysis times, and its ability to provide detailed isotopic data, making it indispensable in applications demanding both sensitivity and specificity.

How it Works
- It starts with a conversation, contact us through our web form or email.
- We’ll discuss your requirments.
- When we’ve agreed the requirments we’ll provide a detailed quotation for the work
- If you’d like to proceed we’ll arrange shipping of the samples
- We’ll perform the analysis and send you the results you need.

Whatever your analysis needs, we’re here to help.