Abstract

A novel sensor operation concept for detecting ppb-level NO2 concentrations at room temperature is introduced. Today’s research efforts are directed to make the sensors as fast as possible (low response and recovery times). Nevertheless, hourly mean values can hardly be precisely calculated, as the sensors are still too slow and show baseline drifts. Therefore, the integration error becomes too large. The suggested concept follows exactly the opposite path. The sensors should be made as slow as possible and operated as resistive gas dosimeters. The adsorption/desorption equilibrium should be completely shifted to the adsorption side during a sorption phase. The gas-sensitive material adsorbs each NO2 molecule (dose) impinging and the sensor signal increases linearly with the NO2 dose. The actual concentration value results from the time derivative, which makes the response very fast. When the NO2 adsorption capacity of the sensor material is exhausted, it is regenerated with ultraviolet (UV) light and the baseline is reached again. Since the baseline is newly redefined after each regeneration step, no baseline drift occurs. Because each NO2 molecule that reaches the sensor material contributes to the sensor signal, a high sensitivity results. The sensor behavior of ZnO known so far indicates that ZnO may be suitable to be applied as a room-temperature chemiresistive NO2 dosimeter. Because UV enhances desorption of sorbed gas species from the ZnO surface, regeneration by UV light should be feasible. An experimental proof demonstrating that the sensor concept works at room temperature for ppb-level NO2 concentrations and low doses is given.

Highlights

  • Since NO2 is a harmful toxic gas, legal limits must not be exceeded and the NO2 concentrations must be monitored—for example by gas sensors [1]

  • CLD and the calculated NO2 dose, DNO 2, over time for a 3% Al-doped ZnO sensor at room temperature temperature in dry synthetic air

  • The results show that the 3% Al-doped ZnO behaves like a resistive in dry synthetic air

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Summary

Introduction

Since NO2 is a harmful toxic gas, legal limits must not be exceeded and the NO2 concentrations must be monitored—for example by gas sensors [1]. Emission limits are given as hourly mean values SM,NO2 to which a dose is directly proportional, see Equations (1) and (2). For NO2 , for instance, the hourly mean value SM,NO2 is 200 μg/m3 (corresponding to an average NO2 concentration of cNO 2 = 104.6 ppb) and the annual mean value is 30 μg/cm (cNO 2 = 15.7 ppb) according to the EU immission legislation Directive 2008 and according to the German air quality standards [2,3]. To obtain the dose DNO 2 (in ppb·s), one must integrate the concentration over time in accordance with Equation (1). If the hourly mean value shall be calculated, tges is 1 h.

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