SilcoTek is rooted in offering inert and non reactive coatings to the analytical and process analytical market. The only issue? Customers may not go far enough in coating flow paths.
SilcoTek® coated analytical components provide an inert sample flow path, preventing interaction of the test analyte with reactive surfaces like stainless steel, glass and ceramics. The result? An inert, non-reactive surface that will assure the entire sample reaches the detector unchanged. The only problem with coating the flow path is that customers may not go far enough. Let's explain.
In this blog post you will learn:
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The purpose of coating reactive stainless steel, glass and ceramic surfaces with an inert coating is to prevent adsorption of the test compounds. This allows all the sample to reach the analytical detector and enabling the analyst to better see and analyze even trace compounds.
The issue is that some systems may not be realizing the entire benefit of a coated flow path because some parts of the system are not coated. For example, it makes no sense to coat 100 feet of tubing but not coat the nearly equivalent surface area found in that metal fritted filter at the end of the flow path. For some reactive compounds like sulfurs, the metal filter will adsorb a significant amount of sulfur and sulfur compounds. This means analysts are not realizing the full benefits of the coated flow path, just by not coating one component. (read more about coating fritted filters in our blog post: Do CVD Coatings Clog Fritted Filters?
The benefits of an inert flow path in gas chromatography and laboratory sampling systems include:
SilcoTek coatings are used in gas chromatography applications to prevent interaction of the test analyte with the flow path surface. Our inert coatings like SilcoNert® and Dursan® prevent adsorption, reactivity, and improve surface corrosion resistance. Applications include:
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An inert injection flow path is a critical factor in achieving consistent low level detection of sensitive compounds. The inert coatings, like SilcoNert® 2000 and Dursan®, prevent interaction of sample flow path, injection port and liner surfaces with reactive compounds, allowing the lab to consistently achieve the lowest detection limits for many industry standards relating to GC testing.
But for trace analysis and testing some particularly reactive compounds, a single uncoated part may result in very high adsorption. Achieve the lowest level of detection for:
Let's explore some real world analytical results to better explain and show how a relatively small uncoated area can significantly disrupt analytical results.
Sulfur Analysis
First we'll compare the performance of SilcoNert 2000 in sulfur analysis applications. Reactive compounds like hydrogen sulfide (H2S) get stuck in analytical systems, causing significant delays in response time. SilcoNert® coated surfaces allow compounds to travel through critical flow paths unimpeded, offering near-real-time response and improving lab productivity. Comparative data from CONCOA (below) show a nearly 10x improvement in response time for a SilcoNert coated flow path (blue line) compared to an uncoated stainless steel system when sampling part-per-million and part-per-billion level hydrogen sulfide. This is a test of a coated vs. uncoated regulator. The data shows that single uncoated regulator can affect results.
Adsorption Prevention
Adsorption of reactive compounds in sampling and calibration systems can cost labs time and money. A slow responding analytical system can complicate and delay troubleshooting of flow paths and gas delivery systems, causing major productivity loss and jeopardizing plant regulatory compliance. Inert coatings, like SilcoNert®, eliminate adsorption and give the analyst virtually real-time results.
Comparing deactivation technologies on glass liners demonstrate the benefit of an inert coating for the prevention of breakdown of reactive organochlorides. The comparison below shows the Dursan coated liner offers the least amount of breakdown of reactive analytes compared to common deactivated liners. This assures all the sample reaches the detector and achieves the highest quality test results, and also demonstrates how not coating (or deactivating with lesser performing technologies) can cause significant variation in results.
Response and Peak Quality
A SilcoNert® coated flow path will reduce signal loss, peak tailing and chemical adsorption while improving peak separation, sensitivity and baseline quality. A reactive flow path and GC column can result in peak distortion, lost peaks and overall poor chromatography (as seen in the example below left). A truly inert flow path will dramatically improve chromatography quality. SilcoNert coated GC surfaces prevent lost peaks and improve peak quality (as seen on the right chromatograph).
Components to Coat for Improved Peak Resolution and Analytical Sensitivity
A Shimadzu Application Specialist highlighted other points about coating and deactivation in general. His points are quoted below:
The take-away is to spend a few dollars to coat the entire flow path will maximize test efficiency, reduce test errors and ultimately same time and money while improving test results. Or as our Production Manager says "don't step over the dollar to get to the dime"!
The good news is that you don't have to send your parts to SilcoTek for custom coating service. There are plenty of OEM manufacturers that offer SilcoTek coated analytical products from stock. Go to our Products and Partners page to get a complete list and contact information for vendor offering coated analytical products. To learn more about our coatings and how they can improve the performance of your products and processes, subscribe to our email and blog. Or follow us on LinkedIn.