Details

Autor(en) / Beteiligte

• Wang, Kuangye
• Kuo, Tzu‐Wen
• Yang, Tzu‐Yi
• Cyu, Ruei‐Hong
• Hsu, Chen‐Wei
• Hsu, Yu‐Chieh
• Yu, Yi‐Jen
• Chen, Yu‐Ze
• Chueh, Yu‐Lun

Titel

Controllable Oxygen‐Incorporated 2D‐SnSe2 Layered Thin Film by Plasma‐Assisted Selenization Process with Enhanced NO2 Gas Sensitivity and Improved Humidity Stability

Ist Teil von

• Advanced materials technologies, 2024-01, Vol.9 (2), p.n/a

Erscheinungsjahr

2024

Quelle

Wiley Online Library

Beschreibungen/Notizen

• Herein, oxygen‐incorporated 2D‐SnSe2 layered films are successfully fabricated by a plasma‐assisted selenization process. The oxygen concentrations inside the 2D‐SnSe2 layered film are controllable by controlling the proportion of hydrogen in the mixed gas of nitrogen and hydrogen during the plasma‐assisted selenization reaction. Oxygen atoms mainly exist in the form of the incorporated oxygen in the 2D‐SnSe2 layered film with an exceedingly small grain size of SnO2, which significantly increases the total interface area of the SnO2/SnSe2. Significant enhancement of the gas response to NO2 (709% under 100 ppb NO2) is reached when the proportion of hydrogen during the plasma‐assisted selenization process is 25%, thus showing excellent sensitivity and selectivity. Moreover, the sensor also demonstrated excellent stability under an increase in relative humidity. It is verified that the response will not significantly decrease when the relative humidity is below 90%. The obtained results demonstrate that oxygen‐incorporated 2D‐SnSe2 layered film with excellent commercial potential, is a highly suitable candidate for next‐generation gas sensors. Herein, oxygen‐incorporated 2D‐SnSe2 layered films are successfully fabricated by a plasma‐assisted selenization process. Oxygen atoms mainly exist in the form of the incorporated oxygen in the 2D‐SnSe2 layered film with an exceedingly small grain size of SnO2, which significantly increases the total interface area of the SnO2/SnSe2. Significant enhancement of the gas response to NO2 (709% under 100 ppb NO2) is reached when the proportion of hydrogen during the plasma‐assisted selenization process is 25%, thus showing excellent sensitivity and selectivity.