1. Introduction

In the post-epidemic era, rapid industrial recovery has produced large amounts of polluting gases, such as SO₂F₂, SOF₂, SO₂, NO, and CO₂ [1,2,3,4,5,6,7,8]. In order to avoid irreversible damage to the environment and human body caused by excessive pollution gases, pollution gases should be controlled and eliminated. To solve this problem, the first step is to monitor the pollution gas in real-time, accurately and intelligently.

Gas-sensing technology is an effective and reliable gas monitoring method [9,10,11]. With the rapid development of material science, two-dimensional nanomaterials, such as graphene, boron nitride, and molybdenum disulfide, have become widely used in gas-sensing technology [12,13,14,15,16,17,18,19,20]. However, due to the physical and chemical inertness of the defect-free monolayer structure, the adsorption between intrinsic boron nitride and small gas molecules is relatively weak, resulting in a relatively poor gas-sensing response [21,22,23,24,25,26,27,28]. As an interesting transition element, Zr has attracted global researchers due to its wide application prospect. Studies have shown that Zr and its complexes can effectively improve the adsorption effect for specific gases [29,30,31,32,33,34,35,36,37]. The gas sensor prepared by it has an appropriate working temperature and good cycle characteristics. At present, atoms or atomic groups are doped on the surface of two-dimensional nanomaterials to improve their gas-sensing response ability mainly through the experimental preparation method and theoretical calculation method. However, the experimental preparation method is time-consuming as well as laborious, and it often causes environmental pollution. The theoretical calculation method based on density functional theory not only has the advantages of being fast, simple, and accurate, and having a low cost, but also can explain the adsorption mechanism of gas-sensing materials from a micro perspective, so as to better modify and optimize the gas-sensing materials [38,39,40,41,42,43,44]. However, there are relatively few studies on gas sensors for the above-mentioned polluted gases.

In this study, an h-BN monolayer, the Zr-doped h-BN monolayer, and five kinds of polluted gases (SO₂F₂, SOF₂, SO₂, NO, and CO₂) were constructed based on density functional theory. The adsorption parameters and electronic properties of each adsorption system were calculated, and the adsorption effects of Zr-BN on the above-mentioned polluted gases were explored. The preparation of high-performance Zr-BN gas sensors for atmospheric pollutant monitoring provides a theoretical basis and new ideas and methods for the development of other gas sensors.

2. Computational Details

Based on the DFT method, all the models in this study were established and calculated in Materials Studio (MS) software. In order to better describe the non-uniform electron density in the actual system, the Perdew–Burke–Ernzerhof (PBE) functional of the generalized gradient approximation (GGA) was used to deal with the exchange–correlation between electrons. In order to better deal with van der Waals force in the calculation process, all calculations were corrected by DFT-D. In order to simplify the existence of more electrons between atoms in the doping system, DFT semi-core pseudopods (DSPP) were used for simplification using a 6 × 6 × 1 k point for geometric optimization and electronic structure calculation. For the charge transfer between gas molecules and single-molecule layers, the Mulliken population was selected for calculation. In the optimization process, the maximum difference, maximum displacement, and maximum displacement of the iteratively convergent energy were set to 1 × 10⁻⁶ Ha, 2 × 10⁻³ Ha/Å, and 5 × 10⁻³ Å, respectively. In addition, in order to avoid the intermolecular interaction, the vacuum layer was set to 15 Å. The h-BN monolayer (9 N atoms and 9 B atoms), Zr-BN monolayer, and gas molecular models were optimized in a 3 × 3 × 1 supercell. Considering the influence of a high-humidity environment on the gas sensor, we adopted a higher dielectric constant in Dmol3 solvent in the aqueous solution environment at 298 K, ε = 78.5 C²/(N − M²).

3. Results and Discussion

As shown in Figure 1, the graphical abstraction describes that in an ideal state, a real-time, accurate, and intelligent pollution gas detection system can be established by combining the Internet of Things (IoT) with a Zr-BN gas sensor.

First, h-BN monolayers were constructed, as shown in Figure 1(a1,a2). In order to obtain the most stable Zr-doped h-BN monolayer, one Zr atom was doped over the B atom (position 1), N atom (position 2), and a six-membered ring (position 3) of h-BN monolayer for structural optimization. At the same time, we calculated the geometric structure parameters and formation energy (E_b). In this study, the calculation formula of formation energy was as follows:

E_b = E_Zr-BN − E_h-BN − E_Zr(1)

After calculation, the bond lengths between the Zr atom and the substrate formed after doping at three positions were 2.276 Å, 2.411 Å, and 2.471 Å, respectively. The binding energies formed at the three positions were −1.671 eV, −1.671 eV, and −1.671 eV, respectively. This shows that the doping reactions at the three positions were exothermic, which was conducive to the spontaneous formation of Zr-BN, and its stability was position 1 > position 2 > position 3. Therefore, subsequent studies were based on the Zr-atom-doped Zr-BN above the B atom of the h-BN monolayer, as shown in Figure 1(b1,b2).

In order to reasonably explore the adsorption of SO₂F₂, SOF₂, SO₂, NO, and CO₂ gas molecules on the Zr-BN monolayer, the gas molecules were placed near the Zr-BN monolayer in different orientations and positions. The most stable adsorption configuration was obtained by optimizing the adsorption structure, as shown in Figure 1(c1–g2). At the same time, the charge transfer (ΔQ), the shortest distance between gas and substrate (d_sub/gas), and the adsorption energy were calculated. The adsorption energy of this study was calculated as follows:

E_ads = E_gas/Zr-BN − E_h-BN − E_gas(2)

The results show that the Zr-BN monolayer had a strong adsorption effect on the above gases, and the adsorption effect was SO₂F₂ > SOF₂ > SO₂ > NO > CO₂. The shortest distance between the gas and substrate (d_sub/SO2F2 = 1.942 Å, d_sub/SOF2 = 1.953 Å, d_sub/SO2 = 2.044 Å, d_sub/NO = 2.121 Å, d_sub/CO2 = 1.787 Å) and the amount of transferred charge were similar to the order of adsorption [45,46]. The negative adsorption energy indicates that the adsorption reaction between the Zr-BN monolayer and the above gases can be carried out spontaneously. It is generally believed that the adsorption reaction can be judged as chemical adsorption when the adsorption energy is less than −0.6 eV [47,48]. However, combined with our subsequent research, it was judged that the adsorption systems were between physical and chemical processes. This is very useful for adsorption and desorption between gas sensors and target gases. It provides a fundamental guarantee for the repeated use and cycle performance of gas sensors.

In order to further explore the electrical properties of the Zr-BN monolayer and various adsorption systems, we calculated TDOS, ELF, and CDD, as seen in Figure 2. In TDOS, the peak change near the Fermi level had the most important influence on the gas-sensing parameters. The increase or decrease in TDOS far above the Fermi level was far less significant than the change near the Fermi level in the conductivity. This is because the increase in electron filling probability at the highest Fermi level contributes little to conductivity. Figure 2a shows that TDOS significantly shifted to the left after doping one Zr atom, which means that the Zr-BN monolayer was more stable. Continuous TDOS showed that Zr-BN had good conductivity. The TDOS near the Fermi level showed that the doping of one Zr atom significantly improved the electron transition ability of the substrate, which is the key to improving the gas-sensing ability of the substrate. As seen in Figure 2(b1–f1), after the adsorption of various gas molecules, the TDOS of the Zr-BN monolayer changed significantly. One of the common characteristics was seen in that the adsorbed TDOS changed dramatically and decreased near the Fermi level. For the first two adsorption systems, the TDOS changes in the SO₂F₂ and SOF₂ adsorption systems were particularly obvious. This is also consistent with the above two adsorption systems. This is because the doping of Zr atoms improves the molecular structure of the original boron nitride, so the adsorption of gas molecules at different sites will have a moderate impact on the crystal structure. Although the TDOS of the last three adsorption systems (SO₂, NO, CO₂) also changed dramatically, it was milder than in the first two adsorption systems. This is because the latter three adsorption systems had a smaller number of carriers than the former two systems. This guarantees that the mixed gas can be detected in real time, accurately, and distinguished macroscopically. At the same time, when the Fermi level was high, the above adsorption systems also underwent great changes, and the common point moved to the left, that is, this adsorption process occurred stably. As shown in Figure 2(b2–f3), when the ELF and CDD were combined, we can see that electrons underwent dramatic changes in the adsorption process. At the same time, the electronic regions in ELFs tended to be fused, which not only shows the strong adsorption between the Zr atom and the adsorbed gas but also shows the adsorption in the five adsorption systems was not chemical adsorption. This proved that the adsorption systems were between physical adsorption and chemical adsorption. In the CDDs of each adsorption system, the electron dissipation area and electron concentration area were extremely dense. This shows that in the process of adsorption, electrons move violently between the substrate and the gas. This also explains why the five adsorption systems of TDOS experience more intense changes before and after adsorption. From the perspective of TDOS, ELFs, and CDDs, Zr-BN can efficiently monitor SO₂F₂, SOF₂, SO₂, NO, and CO₂.

In order to further explore the adsorption mechanism, the band structures of h-BN, Zr-BN, and adsorption systems were calculated, as shown in Figure 3. The results show that compared with h-BN, the band gap energy of the Zr-BN monolayer formed by one Zr atom doping above the B atom of the h-BN monolayer was significantly reduced, and the electron transition was easier. After the adsorption of each gas, the band gap energy increased significantly. This means that after the adsorption of gas, the conductivity of the adsorption system decreases, the resistance increases, and either the reaction’s voltage or current macroscopically increases or decreases, respectively. As shown in Figure 3h, the band gap energy change rate changed by 554.63~2141.67%. This is obvious enough to distinguish between the types of adsorbed gases.

In order to further explore the practicability of Zr-BN, the sensitivity (S) of each system was calculated. The sensitivity calculation formula used in this study is as follows:

S = (1/σ_Zr-BN/gas − 1/σ_Zr-BN)/(1/σ_Zr-BN)(3)

As shown in Figure 4, each adsorption system showed very high sensitivity at different temperatures; the sensitivity was in the order of SOF₂ > SO₂F₂ > CO₂ > SO₂ > NO. At room temperature (298 K), the sensitivity of SOF₂ can reach 3.57 × 10¹⁹. This fully demonstrates that Zr-BN has great potential to become a gas sensor for monitoring the above-mentioned polluted gases.

4. Conclusions

Based on the DFT method, this paper constructed the most stable Zr-BN monolayer and its optimal adsorption configurations with SO₂F₂, SOF₂, SO₂, NO, and CO₂, and calculated the adsorption parameters of each adsorption system. By comparing and analyzing the above parameters, the following conclusions were obtained:

• (1). The Zr-atom-doped h-BN monolayer is the best doping site above the B atom of the h-BN monolayer.

• (2). The adsorption between Zr-BN monolayer and the above gases occurs between physical adsorption and chemical adsorption. The adsorption order is SO₂F₂ > SOF₂ > SO₂ > NO > CO₂.

• (3). The sensitivity of each adsorption system is high, and the sensitivity is in the order of SOF₂ > SO₂F₂ > CO₂ > SO₂ > NO.

• (4). The Zr-BN monolayer has the potential to monitor the above-mentioned pollution gases. This paper provides new ideas and methods for the development of other gas sensors.

Publisher’s Note: MDPI stays neutral with regard to jurisdictional claims in published maps and institutional affiliations.

Enlarge this image.

Figure 1. The geometric structures of (a1,a2) h−BN monolayer, (b1,b2) Zr−BN monolayer, (c1,c2) SO2F2 adsorption system, (d1,d2) SOF2 adsorption system, (e1,e2) SO2 adsorption system, (f1,f2) NO adsorption system, (g1,g2) CO2 adsorption system.

Enlarge this image.

Figure 2. (a) The TDOS of h−BN monolayer and Zr−BN monolayer. The TDOS, ELF, and CDD of (b1–b3) SO2F2 adsorption system, (c1–c3) SOF2 adsorption system, (d1–d3) SO2 adsorption system, (e1–e3) NO adsorption system, (f1–f3) CO2 adsorption system. The Fermi energy was set at zero.

Enlarge this image.

Figure 3. The band energy of (a) h-BN monolayer, (b) Zr-BN monolayer, (c) SOF2 adsorption system, (d) SO2F2 adsorption system, (e) CO2 adsorption system, (f) SO2 adsorption system, (g) NO adsorption system. (h) ΔEg of all adsorption systems.

Enlarge this image.

Figure 4. The sensitivity (S) of all adsorption systems.

References

1. Nie, Y.; Zheng, Q.; Liang, X.; Gu, D.; Lu, M.; Min, M.; Ji, J. Decomposition treatment of SO₂F₂ using packed bed DBD plasma followed by chemical absorption. Environ. Sci. Technol.; 2013; 47, pp. 7934-7939. [DOI: https://dx.doi.org/10.1021/es400786p] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/23772855]

2. Fá, A.G.; Faccio, R.; López-Corral, I. Detection of SOF₂ and SO₂F₂ through aluminium nitride nanosheets: A DFT study. Appl. Surf. Sci.; 2021; 538, 147899.

3. Cortés-Arriagada, D.; Villegas-Escobar, N.; Ortega, D.E. Fe-doped graphene nanosheet as an adsorption platform of harmful gas molecules (CO, CO₂, SO₂ and H₂S), and the co-adsorption in O₂ environments. Appl. Surf. Sci.; 2018; 427, pp. 227-236. [DOI: https://dx.doi.org/10.1016/j.apsusc.2017.08.216]

4. Picón-Pagès, P.; Garcia-Buendia, J.; Muñoz, F.J. Functions and dysfunctions of nitric oxide in brain. Biochim. Biophys. Acta-Mol. Basis Dis.; 2019; 1865, pp. 1949-1967. [DOI: https://dx.doi.org/10.1016/j.bbadis.2018.11.007]

5. Cinelli, M.A.; Do, H.T.; Miley, G.P.; Silverman, R.B. Inducible nitric oxide synthase: Regulation, structure, and inhibition. Med. Res. Rev.; 2020; 40, pp. 158-189. [DOI: https://dx.doi.org/10.1002/med.21599] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/31192483]

6. Wang, J.; Lin, S.; Tian, N.; Ma, T.; Zhang, Y.; Huang, H. Nanostructured metal sulfides: Classification, modification strategy, and solar-driven CO₂ reduction application. Adv. Funct. Mater.; 2021; 31, 2008008. [DOI: https://dx.doi.org/10.1002/adfm.202008008]

7. Wang, S.; Han, X.; Zhang, Y.; Tian, N.; Ma, T.; Huang, H. Inside-and-out semiconductor engineering for CO₂ photoreduction: From recent advances to new trends. Small Struct.; 2021; 2, 2000061. [DOI: https://dx.doi.org/10.1002/sstr.202000061]

8. Shen, J.; Cai, L.; Mao, Z.; Sha, H. Research progress and kinetic model review of biological processes for purifying SO₂ and NO_x. Int. J. Environ. Sci. Technol.; 2021; pp. 1-16. [DOI: https://dx.doi.org/10.1007/s13762-021-03668-6]

9. Popa, D.; Udrea, F. Towards integrated mid-infrared gas sensors. Sensors; 2019; 19, 2076. [DOI: https://dx.doi.org/10.3390/s19092076]

10. Bhati, V.S.; Hojamberdiev, M.; Kumar, M. Enhanced sensing performance of ZnO nanostructures-based gas sensors: A review. Energy Rep.; 2020; 6, pp. 46-62. [DOI: https://dx.doi.org/10.1016/j.egyr.2019.08.070]

11. Feng, S.; Farha, F.; Li, Q.; Wan, Y.; Xu, Y.; Zhang, T.; Ning, H. Review on smart gas sensing technology. Sensors; 2019; 19, 3760. [DOI: https://dx.doi.org/10.3390/s19173760] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/31480359]

12. Xu, K.; Fu, C.; Gao, Z.; Wei, F.; Ying, Y.; Xu, C.; Fu, G. Nanomaterial-based gas sensors: A review. Instrum. Sci. Technol.; 2018; 46, pp. 115-145. [DOI: https://dx.doi.org/10.1080/10739149.2017.1340896]

13. Li, G.; Cheng, Z.; Xiang, Q.; Yan, L.; Wang, X.; Xu, J. Bimetal PdAu decorated SnO₂ nanosheets based gas sensor with temperature-dependent dual selectivity for detecting formaldehyde and acetone. Sens. Actuator B Chem.; 2019; 283, pp. 590-601. [DOI: https://dx.doi.org/10.1016/j.snb.2018.09.117]

14. Mahajan, S.; Jagtap, S. Metal-oxide semiconductors for carbon monoxide (CO) gas sensing: A review. Appl. Mater. Today; 2020; 18, 100483. [DOI: https://dx.doi.org/10.1016/j.apmt.2019.100483]

15. Poloju, M.; Jayababu, N.; Reddy, M.R. Improved gas sensing performance of Al doped ZnO/CuO nanocomposite based ammonia gas sensor. Mater. Sci. Eng. B; 2018; 227, pp. 61-67. [DOI: https://dx.doi.org/10.1016/j.mseb.2017.10.012]

16. Yuan, H.; Aljneibi, S.A.A.A.; Yuan, J.; Wang, Y.; Liu, H.; Fang, J.; Tang, C.; Yan, X.; Cai, H.; Gu, Y. ZnO nanosheets abundant in oxygen vacancies derived from metal-organic frameworks for ppb-level gas sensing. Adv. Mater.; 2019; 31, 1807161. [DOI: https://dx.doi.org/10.1002/adma.201807161]

17. Kumar, R.; Liu, X.; Zhang, J.; Kumar, M. Room-temperature gas sensors under photoactivation: From metal oxides to 2D materials. Nano-Micro Lett.; 2020; 12, pp. 1-37. [DOI: https://dx.doi.org/10.1007/s40820-020-00503-4]

18. Irshad, R.; Tahir, K.; Li, B.; Sher, Z.; Ali, J.; Nazir, S. A revival of 2D materials, phosphorene: Its application as sensors. J. Ind. Eng. Chem.; 2018; 64, pp. 60-69. [DOI: https://dx.doi.org/10.1016/j.jiec.2018.03.010]

19. Munteanu, R.-E.; Moreno, P.S.; Bramini, M.; Gáspár, S. 2D materials in electrochemical sensors for in vitro or in vivo use. Anal. Bioanal. Chem.; 2021; 413, pp. 701-725. [DOI: https://dx.doi.org/10.1007/s00216-020-02831-1]

20. Tan, W.C.; Ang, K.W. Volatile organic compound sensors based on 2D materials. Adv. Electron. Mater.; 2021; 7, 2001071. [DOI: https://dx.doi.org/10.1002/aelm.202001071]

21. Sajjad, M.; Feng, P. Study the gas sensing properties of boron nitride nanosheets. Mater. Res. Bull.; 2014; 49, pp. 35-38. [DOI: https://dx.doi.org/10.1016/j.materresbull.2013.08.019]

22. Bian, Y.; Li, L.; Song, H.; Su, Y.; Lv, Y. Porous boron nitride: A novel metal-free cataluminescence material for high performance H₂S sensing. Sens. Actuator B-Chem.; 2021; 332, 129512. [DOI: https://dx.doi.org/10.1016/j.snb.2021.129512]

23. Tian, W.; Wang, Y.; Zhang, Y.; Cao, J.; Guan, R.-F. WO3 Nanoflakes Coupled with Hexagonal Boron Nitride Nanosheets for Triethylamine Sensing. ACS Appl. Nano Mater.; 2021; 4, pp. 6316-6327.

24. Bareza, N.J.; Paulillo, B.; Slipchenko, T.M.; Autore, M.; Dolado, I.; Liu, S.; Edgar, J.H.; Vélez, S.L.; Martín-Moreno, L.; Hillenbrand, R. Phonon-Enhanced Mid-Infrared CO₂ Gas Sensing Using Boron Nitride Nanoresonators. ACS Photonics; 2022; 9, pp. 34-42. [DOI: https://dx.doi.org/10.1021/acsphotonics.1c01254]

25. Sajjad, M.; Jadwisienczak, W.M.; Feng, P. Nanoscale structure study of boron nitride nanosheets and development of a deep-UV photo-detector. Nanoscale; 2014; 6, pp. 4577-4582. [DOI: https://dx.doi.org/10.1039/C3NR05817D]

26. Sultan, A.; Ahmad, S.; Anwer, T.; Mohammad, F. Binary doped polypyrrole and polypyrrole/boron nitride nanocomposites: Preparation, characterization and application in detection of liquefied petroleum gas leaks. RSC Adv.; 2015; 5, pp. 105980-105991. [DOI: https://dx.doi.org/10.1039/C5RA21173E]

27. He, Y.; Li, D.; Gao, W.; Yin, H.; Chen, F.; Sun, Y. High-performance NO₂ sensors based on spontaneously functionalized hexagonal boron nitride nanosheets via chemical exfoliation. Nanoscale; 2019; 11, pp. 21909-21916. [DOI: https://dx.doi.org/10.1039/C9NR07153A]

28. Zhang, Q.; Wang, Y.; Zhou, Q.; Chen, Y.; Zheng, Y.; Tang, S.; Zhao, Y.; Jiang, L. Highly efficient cataluminescence gas sensor based on nanosized h-BN for trace acetylacetone detection. Meas. Sci. Technol.; 2021; 32, 095114. [DOI: https://dx.doi.org/10.1088/1361-6501/abf95b]

29. Ravikumar, N.; Dilip, R.; Elango, P. Gas sensing nature and characterization of Zr doped TiO₂ films prepared by automated nebulizer spray pyrolysis technique. Optik; 2020; 206, 164347.

30. Lee, J.-H.; Nguyen, T.T.T.; Nguyen, L.H.T.; Phan, T.B.; Kim, S.S.; Doan, T.L.H. Functionalization of zirconium-based metal–organic frameworks for gas sensing applications. J. Hazard. Mater.; 2021; 403, 124104. [DOI: https://dx.doi.org/10.1016/j.jhazmat.2020.124104]

31. Kumar, M.; Rani, S.; Bhatnagar, M.; Roy, S.C. Structure, ferroelectric and gas sensing properties of sol–gel derived (Ba, Sr)(Ti, Zr)O₃ thin films. Mater. Chem. Phys.; 2008; 107, pp. 399-403. [DOI: https://dx.doi.org/10.1016/j.matchemphys.2007.08.010]

32. Deng, J.; Zhu, W.; Tan, O.; Yao, X. Amorphous Pb(Zr, Ti)O₃ thin film hydrogen gas sensor. Sens. Actuator B-Chem.; 2001; 77, pp. 416-420. [DOI: https://dx.doi.org/10.1016/S0925-4005(01)00707-9]

33. Izu, N.; Oh-hori, N.; Itou, M.; Shin, W.; Matsubara, I.; Murayama, N. Resistive oxygen gas sensors based on Ce_1−xZr_xO₂ nano powder prepared using new precipitation method. Sens. Actuator B-Chem.; 2005; 108, pp. 238-243. [DOI: https://dx.doi.org/10.1016/j.snb.2004.11.064]

34. Surya, S.G.; Bhanoth, S.; Majhi, S.M.; More, Y.D.; Teja, V.M.; Chappanda, K.N. A silver nanoparticle-anchored UiO-66 (Zr) metal–organic framework (MOF)-based capacitive H₂S gas sensor. Crystengcomm; 2019; 21, pp. 7303-7312. [DOI: https://dx.doi.org/10.1039/C9CE01323G]

35. Li, X.; Jiang, D.; Fan, Y.; Zhang, N.; Liu, C.; Adimi, S.; Zhou, J.; Wen, S.; Ruan, S. The effects of Zr-doping on improving the sensitivity and selectivity of a one-dimensional α-MoO₃-based xylene gas sensor. Inorg. Chem. Front.; 2020; 7, pp. 1704-1712. [DOI: https://dx.doi.org/10.1039/D0QI00019A]

36. Vazquez, R.M.; Mozalev, A.; Calavia, R.; Gispert-Guirado, F.; Vilanova, X.; Habazaki, H.; Llobet, E. Gas sensing properties of the nanostructured anodic Zr–W oxide film. Sens. Actuator B-Chem.; 2014; 204, pp. 588-595. [DOI: https://dx.doi.org/10.1016/j.snb.2014.08.014]

37. Yang, Q.; Wang, Y.; Liu, J.; Liu, J.; Gao, Y.; Sun, P.; Zheng, J.; Zhang, T.; Wang, Y.; Lu, G. Enhanced sensing response towards NO₂ based on ordered mesoporous Zr-doped In₂O₃ with low operating temperature. Sens. Actuator B-Chem.; 2017; 241, pp. 806-813. [DOI: https://dx.doi.org/10.1016/j.snb.2016.09.145]

38. Zhang, Y.; Wang, Y.; Zhu, L.; Zhang, R.; Cao, J. Enhanced CO sensing performance of WO₃ nanorods with PtAg nanoparticles modification: A combined experimental and first-principle study. Vacuum; 2021; 193, 110526. [DOI: https://dx.doi.org/10.1016/j.vacuum.2021.110526]

39. Kumar, P.; Chiu, Y.-H.; Deng, Z.-I.; Kumar, U.; Chen, K.-L.; Huang, W.-M.; Wu, C.-H. Surface modification of ZnO nanopillars to enhance the sensitivity towards methane: The studies of experimental and first-principle simulation. Appl. Surf. Sci.; 2021; 568, 150817. [DOI: https://dx.doi.org/10.1016/j.apsusc.2021.150817]

40. Tang, X.; Du, A.; Kou, L. Gas sensing and capturing based on two-dimensional layered materials: Overview from theoretical perspective. Wiley Interdiscip. Rev.-Comput. Mol. Sci.; 2018; 8, e1361. [DOI: https://dx.doi.org/10.1002/wcms.1361]

41. Mariappan, S.M.; Eswaran, M.K.; Schwingenschlögl, U.; Thangeeswari, T.; Vinoth, E.; Shkir, M.; Said, Z.; Karthikeyan, B. Impact of reducing agents on the ammonia sensing performance of silver decorated reduced graphene oxide: Experiment and first principles calculations. Appl. Surf. Sci.; 2021; 558, 149886. [DOI: https://dx.doi.org/10.1016/j.apsusc.2021.149886]

42. Park, J.; Saidi, W.A.; Wuenschell, J.K.; Howard, B.H.; Chorpening, B.; Duan, Y. Assessing the Effects of Temperature and Oxygen Vacancy on Band Gap Renormalization in LaCrO₃−δ: First-Principles and Experimental Corroboration. ACS Appl. Mater. Interfaces; 2021; 13, pp. 17717-17725. [DOI: https://dx.doi.org/10.1021/acsami.1c03503] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/33831299]

43. Qin, Y.; Wang, X. Experiments combined with first-principles calculations to compare the enhancement of Ag-doping and-functionalization on the sensing properties of two-dimensional SnS. Phys. E; 2021; 131, 114752. [DOI: https://dx.doi.org/10.1016/j.physe.2021.114752]

44. Ge, W.; Zhang, G.; Wang, P.; Li, Z.; Deng, Y. Highly selective detection of ethanol based on hierarchical three-dimensional SnO₂: Combining experiment with first-principles calculation. Sens. Actuator A-Phys.; 2021; 331, 112994. [DOI: https://dx.doi.org/10.1016/j.sna.2021.112994]

45. Peng, Z.; Tao, L.-Q.; Wang, G.; Zhang, F.; Sun, H.; Zhu, C.; Zou, S.; Yu, J.; Chen, X. The promotion of sulfuric vacancy in two-dimensional molybdenum disulfide on the sensing performance of SF6 decomposition components. Appl. Surf. Sci.; 2022; 571, 151377. [DOI: https://dx.doi.org/10.1016/j.apsusc.2021.151377]

46. Sun, H.; Tao, L.-Q.; Li, T.; Gao, X.; Sang, T.; Li, Y.; Wei, Y.; Wang, G.; Peng, Z.; Gui, Y. TiO₂–Doped GeSe Monolayer: A highly selective gas sensor for SF6 decomposed species detection based on DFT method. Appl. Surf. Sci.; 2022; 572, 151212. [DOI: https://dx.doi.org/10.1016/j.apsusc.2021.151212]

47. Bahamon, D.; Khalil, M.; Belabbes, A.; Alwahedi, Y.; Vega, L.F.; Polychronopoulou, K. A DFT study of the adsorption energy and electronic interactions of the SO₂ molecule on a CoP hydrotreating catalyst. RSC Adv.; 2021; 11, pp. 2947-2957. [DOI: https://dx.doi.org/10.1039/C9RA10634K]

48. Mushtaq, M.; Khan, S.; Tit, N. Magnetization effect of Mn-embedded in C₂N on hydrogen adsorption and gas-sensing properties: Ab-initio analysis. Appl. Surf. Sci.; 2021; 537, 147970. [DOI: https://dx.doi.org/10.1016/j.apsusc.2020.147970]