Voltage-controlled NiO/ZnO p–n heterojunction diode: a new approach towards selective VOC sensing

<p class="first" id="Par1">Metal oxide resistive gas sensors suffer from poor selectivity that restricts their practical applicability. Conventional sensor arrays are used to improve selectivity which increased the system complexity. Here, we have proposed a novel NiO/ZnO-based p–n junction single-diode device for selective sensing of several volatile organic compounds (VOCs) simultaneously by tuning bias voltage. The operating voltage was varied between 3 and 5 volts to achieve selective sensing of 2-propanol (19.1 times for 95 ppm with response and recovery times of 70 s and 55 s respectively‚ at 3 volts), toluene (20.1 times for 95 ppm with response and recovery times of 100 s and 60 s respectively, at 4 volts), and formaldehyde (11.2 times for 95 ppm with response and recovery times of 88 s and 54 s respectively, at 5 volts). A probable mechanism of the tunable selectivity with operating bias voltage due to increase in surface carriers with increasing voltage was hence put forth. Thus, this device may play an important role to develop future selective multiple VOC sensor thereby replacing standard sensor arrays. </p><p id="Par2">Employed in manufacturing many industrial products, volatile organic compounds (VOCs) are often highly toxic. A diode based device has been developed that allows the selective sensing of several VOCs simultaneously in a cost-efficient manner. Various methods can be used to detect VOCs, but they have considerable shortcomings, including high cost, excessive size, and poor selectivity. However, a team headed by Prasanta Kumar Guha at the Indian Institute of Technology Kharagpur, India has succeeded in developing a new single-diode device based on nickel oxide and zinc oxide (NiO/ZnO) heterojunction that can be fabricated in an environment-friendly fashion and allows accurate sensing of VOCs. The authors believe that their voltage-tunable selective NiO/ZnO diode device has considerable potential for application as future VOC sensors, replacing the complex gas sensor arrays that are currently in standard commercial use. </p>