| Literature DB >> 29019645 |
Eric S Muckley1, Michael Naguib, Hsiu-Wen Wang, Lukas Vlcek, Naresh C Osti, Robert L Sacci, Xiahan Sang, Raymond R Unocic, Yu Xie, Madhusudan Tyagi2,3, Eugene Mamontov, Katharine L Page, Paul R C Kent, Jagjit Nanda1, Ilia N Ivanov1.
Abstract
Understanding of structural, electrical, and gravimetric peculiarities of water vapor interaction with ion-intercalated MXenes led to design of a multimodal humidity sensor. Neutron scattering coupled to molecular dynamics and ab initio calculations showed that a small amount of hydration results in a significant increase in the spacing between MXene layers in the presence of K and Mg intercalants between the layers. Films of K- and Mg-intercalated MXenes exhibited relative humidity (RH) detection thresholds of ∼0.8% RH and showed monotonic RH response in the 0-85% RH range. We found that MXene gravimetric response to water is 10 times faster than their electrical response, suggesting that H2O-induced swelling/contraction of channels between MXene sheets results in trapping of H2O molecules that act as charge-depleting dopants. The results demonstrate the use of MXenes as humidity sensors and infer potential impact of water on structural and electrical performance of MXene-based devices.Entities:
Keywords: MXene; humidity sensor; intercalation; neutron scattering; pillaring; quartz crystal microbalance
Year: 2017 PMID: 29019645 DOI: 10.1021/acsnano.7b05264
Source DB: PubMed Journal: ACS Nano ISSN: 1936-0851 Impact factor: 15.881