For full functionality of this site it is necessary to enable JavaScript.
EMIN.VN
0

What is cross-sensitivity and how does it affect gas measurement accuracy?

2026年06月06日 11時36分26秒

Understanding cross sensitivity helps users interpret measurement data more accurately, reduce false alarms, and select the right instrument for their working environment, especially when using multi-gas detectors and environmental monitoring instruments.

Many electrochemical sensors used in multi-gas detector have an inherent characteristic known as cross sensitivity. This phenomenon can cause measurement results to differ from the actual gas concentration in the environment. A gas sensor does not always respond exclusively to its target gas; its readings can also be influenced by other gases present in the atmosphere.

What Is Cross Sensitivity ?

Cross sensitivity is the phenomenon in which a gas sensor designed to detect a specific gas also responds to other gases with similar chemical properties.

For example, an H₂S sensor may generate a signal when exposed to SO₂, while a CO sensor can be affected by Hydrogen (H₂). In such cases, the instrument detects signals from both the target gas and the interfering gas, then converts those signals into a concentration value displayed on the screen.

As a result, operators may observe readings that are either higher or lower than the actual gas concentration, even though the sensor itself is functioning normally.

Why Does Cross Sensitivity Occur ?

Most portable gas detectors use electrochemical sensors to monitor toxic gases such as CO, H₂S, SO₂, NH₃, and NO₂. Inside the sensor, gas molecules pass through a membrane and undergo electrochemical reactions at the electrodes, generating an electrical current proportional to the gas concentration.

The challenge is that different gases can produce similar electrochemical reactions on the electrode surface. While the sensor can detect the resulting electrical signal, it cannot always determine exactly which gas generated that signal.

The degree of cross sensitivity depends on sensor design, manufacturing technology, and the composition of gases present in the monitoring environment.

How Does Cross Sensitivity Affect Gas Measurements ?

The most common effect is an increase in the displayed reading. For instance, in areas where Hydrogen is present, a CO sensor may respond to both CO and H₂. In this situation, a multi-gas detector may display a CO concentration higher than the actual level, leading users to believe there is a carbon monoxide hazard when the source of interference is Hydrogen.

In other cases, cross sensitivity can reduce the sensor signal. The air quality meter may then display a concentration lower than the actual value, creating a false sense of safety and increasing the risk for personnel working in hazardous environments.

Cross sensitivity is also a common cause of false alarms. A gas detector may trigger an alarm even when the target gas is absent or present only at a very low concentration. This situation is often encountered in chemical plants, wastewater treatment facilities, and industrial environments where multiple gases coexist.

For organizations that rely on continuous gas monitoring systems, cross sensitivity can affect long-term data records and reduce the reliability of environmental and occupational safety reports.

Haz-Dust HIM-6000 Environmental Monitoring System

Gas Sensors Commonly Affected by Cross Sensitivity

Not all gas sensors are affected to the same extent. H₂S and CO sensors are among the most susceptible to cross sensitivity.

H₂S sensors may respond to sulfur-containing gases such as SO₂. Likewise, CO sensors are often influenced by Hydrogen, particularly in battery charging stations and industrial hydrogen production facilities.

SO₂, NO₂, and Cl₂ sensors may also be affected by gases with similar oxidizing or reducing properties. For this reason, when selecting a gas detector for a specific application, users should carefully review cross sensitivity specifications rather than focusing only on measurement range or resolution.

How Can Cross Sensitivity Be Evaluated ?

Most reputable manufacturers provide cross sensitivity tables in their sensor technical documentation. These tables indicate how much signal an interfering gas can generate, usually expressed as an equivalent concentration of the target gas in parts per million (ppm).

By reviewing these specifications, users can estimate potential measurement errors when operating in environments where multiple gases are present.

This information is particularly important for safety engineers, environmental monitoring professionals, and industries where mixtures of hazardous gases may occur.

How to Reduce the Impact of Cross Sensitivity

The most effective approach is to select the appropriate sensor for the intended application. Before investing in a multi-gas tester, users should identify which gases are likely to be present in the workplace and avoid sensors that are highly susceptible to interference from those gases.

In addition, high-quality gas detectors are often equipped with chemical filters, advanced signal-processing algorithms, and improved sensor technologies that significantly reduce the effects of cross sensitivity.

Regular calibration is also essential. Although calibration cannot completely eliminate cross sensitivity, it helps maintain sensor performance and allows abnormal deviations to be identified at an early stage.

When measurement results appear inconsistent with actual site conditions, operators should consider the possibility of interfering gases rather than focusing solely on the target gas.

A clear understanding of cross sensitivity, combined with proper interpretation of technical specifications and careful sensor selection, helps users obtain more reliable measurement data, reduce false alarms, and improve the effectiveness of toxic gas monitoring programs.

関連ニュース

Why do brushless centrifuges generate less heat?
2026年07月18日 09時54分09秒

High-speed centrifugation over extended periods generates heat. For biological samples such as blood, plasma, proteins, or nucleic acids, an unexpected rise in temperature can affect processing results. Consequently, the motor becomes a key factor to consider, alongside rotational speed and rotor capacity

What is the difference between oil-lubricated vacuum pumps and oil-free diaphragm pumps?
2026年07月17日 10時05分46秒

While both generate a vacuum, oil-lubricated pumps and oil-free diaphragm pumps differ significantly in their operating principles, advantages, and applications. Oil-lubricated pumps are typically chosen when a system requires a deep vacuum and strong suction power, whereas diaphragm pumps are preferred for laboratories, chemical processes, and environments where oil vapors must be avoided

Why is the vacuum pump making a loud noise? 6 common causes and how to fix them immediately
2026年07月17日 09時36分33秒

A vacuum pump making louder-than-normal noise often points to issues with the rotating assembly, vanes, pump oil, filters, or the intake piping. The specific sound produced helps narrow down the cause: a sustained whistling sound differs from the rattling inside the pump chamber or a heavy, grinding noise accompanied by strong vibration

Which Vacuum Pump Should You Choose for a Microbiology Lab to Avoid Affecting Samples?
2026年07月15日 14時45分07秒

Vacuum pumps are utilized in a wide range of microbiology laboratory procedures, from membrane filtration and the aspiration of supernatants following centrifugation to sample concentration and the support of negative-pressure systems. Selecting the appropriate pump not only ensures more stable operational processes but also minimizes the risk of sample contamination, reduces maintenance costs, and extends the equipment's lifespan

お得な情報を受け取る

数量割引、まとめ買い価格の更新、新製品情報をメールでお届けします。

登録することで、当社の利用規約およびプライバシーポリシーに同意したものとみなされます。

クイックサポート

認定専門家へ直接アクセス