Catalytic activities of noble metal atoms on WO3 (001): nitric oxide adsorption.

Using first-principles density functional theory calculations within the generalized gradient approximation, we investigate the adsorption of NO molecule on a clean WO3(001) surface as well as on the noble metal atom (Cu, Ag, and Au)-deposited WO3(001) surfaces. We find that on a clean WO3 (001) surface, the NO molecule binds to the W atom with an adsorption energy (E ads) of -0.48 eV. On the Cu- and Ag-deposited WO3(001) surface where such noble metal atoms prefer to adsorb on the hollow site, the NO molecule also binds to the W atom with E ads = -1.69 and -1.41 eV, respectively. This relatively stronger bonding of NO to the W atom is found to be associated with the larger charge transfer of 0.43 e (Cu) and 0.33 e (Ag) from the surface to adsorbed NO. However, unlike the cases of Cu-WO3(001) and Ag-WO3(001), Au atoms prefer to adsorb on the top of W atom. On such an Au-WO3(001) complex, the NO molecule is found to form a bond to the Au atom with E ads = -1.32 eV. Because of a large electronegativity of Au atom, the adsorbed NO molecule captures the less electrons (0.04 e) from the surface compared to the Cu and Ag catalysts. Our findings not only provide useful information about the NO adsorption on a clean WO3(001) surface as well as on the noble metal atoms deposited WO3(001) surfaces but also shed light on a higher sensitive WO3 sensor for NO detection employing noble metal catalysts.

Background

NOx gases such as NO and NO2 which are produced from the reaction of nitrogen and oxygen gases in the air during combustion damage not only our environment including air pollution and land contamination but also human health. Therefore, it has attracted much attention in recent years to develop a high-performance NOx-sensing equipment [1-4]. For the detection of NOx, a number of gas sensors using semiconducting metal oxides such as ZnO [5-7], MoO3 [8,9], In2O3 [10], SnO2 [11,12], TiO2 [13], and WO3 [14] have been reported theoretically and experimentally.

Tungsten oxide (WO3) has many unusual properties which make it suitable for various applications, e.g., high sensitivity of reducing and oxidizing gases [14], excellent electron transport and photosensitivity, and high stability-resisting photocorrosion in aqueous solvent [15-20]. Especially, WO3 sensors have been widely applied for the detection of NOx gases [21-23]. In order to enhance the performance for NO2 detection, WO3 sensors have utilized the addition of metal atoms [24,25] as catalysts. However, there have been relatively few reports for the WO3 sensor detecting NO molecule [26,27], and furthermore, theoretical studies for the adsorption of NO on WO3 surfaces are still lacking. In this sense, an accurate first-principles density functional theory (DFT) calculation for the NO adsorption on WO3 surfaces is highly desirable for the application of WO3 sensors to NO detection.

In this work, we perform a first-principles DFT calculation to investigate the adsorption of NO molecule on a clean WO3(001) surface as well as on the noble metal atom (Cu, Ag, and Au) deposited WO3(001) surface. Here, the (001) surface (see Figure 1a,b) of γ-monoclinic WO3 is taken into account because it is the most stable at room temperature [28]. We demonstrate that the Cu-, Ag-, and Au-deposited WO3(001) surfaces exhibit different catalytic behaviors for NO adsorption, that is, the magnitude of adsorption energy (Eads) is in the order of Cu > Ag > Au. This different binding behavior of NO on WO3(001) depending on the noble metal species can be traced to the difference in charge transfer from the substrate to adsorbed NO molecule. Based on our DFT results, we will discuss the enhanced sensitivity of WO3 sensors for NO detection by employing the noble metal catalysts.

Figure 1

Optimized atomic structure. (a) Top view and (b) side view of the clean WO3 (001) surface. The large and small circles represent W and O atoms, respectively. The most stable structures for the Cu, Ag, and Au atoms deposited on WO3 (001) surface are displayed in (c), (d), and (e), respectively. The most stable structures for NO adsorption on a clean WO3 (001) surface and the Cu-, Ag-, and Au-deposited WO3 (001) surfaces are displayed in (f), (g), (h), and (i), respectively. In (f), (g), (h), and (i), the circle for N atom is larger than that for the O atom.

Methods

Our DFT calculations were performed using Vienna ab initio simulation package (VASP) with the projector augmented wave method [29-32]. For the exchange-correlation energy, we employed the generalized gradient approximation functional of Perdew-Burke-Ernzerhof [33]. The electronic wave functions were expanded in a plane wave basis with an energy cutoff of 400 eV. The WO3(001) surface was modeled by a periodic four-atomic-layer slab composing two alternate WO2 plus O layers with approximately 16 Å of vacuum in between the slabs. The k-space integration was carried out using a Monhkorst-Pack grid [34] of 4 × 4 × 1 k points in the surface Brillouin zone of the monoclinic (1 × 1) unit cell whose size is as large as the cubic (2 × 2) unit cell. We relaxed all atoms except the bottom layer along the calculated forces until all the residual force components were less than 0.01 eV/Å. For the interaction of the NO molecule with the clean and metal-deposited WO3(001) surfaces, we initially placed the NO molecule about 3.5 Å away from the surfaces and obtained the adsorption structure by fully structural optimization.

Results and discussion

NO adsorption on a clean WO3 (001) surface

We first investigate the adsorption of a single NO molecule on a clean WO3 (001) surface. Figure 1a,b shows the top and side views of the optimized WO3 (001) surface, respectively. For the adsorption of NO on WO3 (001), we consider the three different adsorption sites such as top W (hereafter denoted as S1), top O (S2), and hollow (S3) sites. We find that the N atom of NO is bonding to the substrate atoms, consistent with a previous theoretical calculation [21]. However, in the hollow site, the O atom of NO can be bound to the substrate atoms (denoted as S4). We calculate the adsorption energy defined as [35] Eads = E(NO/surf) – E(surf) – E(NO), where E(NO/surf) is the total energy of the NO-adsorbed WO3 (001) system, E(surf) is the energy of a clean WO3 (001) before NO adsorption, and E(NO) is the energy of a free NO molecule, obtained using a 12 × 12 × 12 Å3 supercell calculation. As shown in Figure 1f, the S1 configuration is found to be the most stable with Eads = −0.48 eV, larger in magnitude than Eads = −0.05, −0.05, and −0.03 eV for S2, S3, and S4, respectively; see Figure 2a. We note that, in the S1 configuration, the bond length dN-W between the N and W atoms is calculated to be 2.07 Å, which is much shorter than the sum (3.7 Å) of van der Waals radius of the two atoms [14,36]. Thus, we can say that NO molecule can form a chemical bond with the WO3 (001) surface.

Figure 2

Adsorption energies of various configurations calculated for NO adsorption. NO molecule adsorbed on the (a) clean, (b) Cu-deposited, (c) Ag-deposited, and (d) Au-deposited WO3 (001) surfaces. The adsorption configurations such as [S1, S2, S3, S4], [M1, M2, M3, M4], and [P1, P2, P3, P4, P5] are described in the text.

To evaluate charge transfer in the S1 configuration, we perform Bader charge analysis for NO before and after its adsorption on the WO3(001) surface [37,38]. The results for a free NO molecule and adsorbed NO on various substrates are given in Table 1. We find that, upon NO adsorption on a clean WO3(001) surface, the electrons in the N (O) atom increase (decrease) from 4.44 (6.56) to 4.84 (6.35) e, giving rise to an increase of 0.19 e in adsorbed NO molecule. This fact shows that adsorbed NO molecule captures electrons from the WO3(001) surface, indicating that NO behaves as a charge accepter. Indeed, the charge density difference, defined as ∆ρ = ρNO/WO3 − (ρNO + ρWO3), clearly shows a charge transfer from the O (in NO molecule) and W atoms to the N atom; see Figure 3a. As a consequence of the additional electrons in NO in the NO/WO3(001) system, the bond length dN-O of NO molecule slightly increases to 1.181 Å, compared to that (1.170 Å) of a free NO molecule; see Table 1.

Table 1

Charge analysis and bond length of NO molecule

	NO	NO/WO 3	NO/Cu-WO 3	NO/Ag-WO 3	NO/Au-WO 3
N (e)	4.44	4.84	5.00	4.91	4.64
O (e)	6.56	6.35	6.43	6.42	6.40
N + O (e)	11	11.19	11.43	11.33	11.04
d N-O (Å)	1.170	1.181	1.212	1.203	1.182

Bader charges of N and O atoms in a clean WO3(001) surface and various noble metal atom-deposited WO3(001) surfaces are given. Bader charges of N and O atoms in an isolated NO molecule are also given in the first column. The bond length d N-O in each system is also given.

Figure 3

Charge density difference for the most stable configurations of NO adsorption. NO molecule adsorbed on the (a) clean, (b) Cu-deposited, (c) Ag-deposited, and (d) Au-deposited WO3 (001) surfaces. The gain and loss of electrons are drawn in bright and dark colors with an isosurface of 0.005 e/Å3, respectively.

It is noteworthy that the abovementioned charge transfer from the WO3(001) surface to NO molecule leads to a reduction of conduction electrons in WO3(001), thereby forming the electron-depleted layer at the surface. This change of electrical character at the WO3(001) surface can be utilized to the WO3 gas sensor where the contact resistance can be affected by the exposure of NO gas.

NO adsorption on Cu- or Ag-deposited WO3 (001) surface

We begin to optimize the adsorption structure of Cu or Ag on WO3(001). We find that the adsorption of Cu (Ag) on the hollow site is more stable than the other adsorption sites such as top W and top O sites by 0.66 (0.14) and 0.75 (0.14) eV, respectively. Using Bader charge analysis, we find that the adsorption of Cu and Ag on the hollow site loses electrons to the WO3(001) substrate by 0.7 and 0.6 e, respectively. Using the most stable adsorption configuration of Cu or Ag on WO3(001), we continue to study the adsorption of NO on such noble metal atom-deposited WO3(001) substrates. We consider three different adsorption configurations of NO, where N atom is attached to W (denoted as M1), O (M2), and Cu or Ag (M3) atoms. In addition, we also consider another adsorption configuration of NO, where O atom in NO molecule is attached to Cu or Ag atom (denoted as M4). The calculated adsorption energy of NO for each adsorption configuration on Cu-WO3(001) and Ag-WO3(001) is given in Figure 2b,c, respectively. We find that the M1 configuration is the most stable with Eads = −1.69 and −1.41 eV for NO/Cu-WO3(001) and NO/Ag-WO3(001), respectively, which are much larger in magnitude than Eads = −0.48 eV of the S1 configuration at a clean WO3(001) surface. This indicates that Cu and Ag increases the strength of NO binding on WO3(001), thereby serving as catalysts. In the M1 configuration, the N atom is also bonding to the W atom with dN-Cu/Ag (bond length between N and Cu or Ag atoms) = 1.86 or 2.19 Å because of a Coulomb interaction between the negatively charged N atom and the positively charged Cu or Ag atom (see Figure 3b,c), as discussed below. We note that the values of dN-W amount to 2.36 and 2.37 Å for NO/Cu-WO3(001) and NO/Ag-WO3(001), respectively. These values become longer than dN-W = 2.07 Å in the S1 configuration but are still much shorter than the sum (3.7 Å) of van der Waals radius of N and W atoms [14,36], therefore concluding that NO molecule adsorbs chemically on the Cu-WO3(001) and Ag-WO3(001) substrates.

In Table 1, we find that for the M1 configuration of NO/Cu-WO3(001), the electrons in the N (O) atom increase (decrease) from 4.44 (6.56) to 5.00 (6.43) e, giving rise to an increase of 0.43 e in adsorbed NO molecule. On the other hand, for the M1 configuration of NO/Ag-WO3(001), the electrons in the N (O) atom are found to increase (decrease) from 4.44 (6.56) to 4.91 (6.42) e, giving rise to an increase of 0.33 e in adsorbed NO molecule. These results indicate that adsorbed NO molecule on Cu-WO3(001) and Ag-WO3(001) captures more electrons from the substrates compared to the case of NO adsorption at a clean WO3(001) surface, where only 0.19 e is transferred from WO3(001) to NO. As shown in Figure 3b,c, the calculated charge density difference ∆ρ shows charge transfer from the O (in NO molecule) and Cu-WO3(001) or Ag-WO3(001) substrate to the N atom, leading to the polar NO molecule with a negatively charged N atom. We note that, as a consequence of the presence of excess electrons in the polar NO molecule, the bond length dN-O of NO molecule increases to 1.212 and 1.203 Å for NO/Cu-WO3(001) and NO/Ag-WO3(001), respectively. These values of dN-O are longer than dN-O = 1.181 Å for NO/WO3(001) as well as dN-O = 1.170 Å of a free NO molecule.

Since more electrons transfer from the substrate to adsorbed NO molecule by the deposition of Cu or Ag atoms, one expects an enhanced reduction of conduction electrons in WO3(001), therefore increasing the sensitivity of WO3 sensor for NO detection. As a matter of fact, a recent experimental study showed that the deposition of Ag atoms in WO3 sensor improves its sensitivity for NO detection [27]. We note that, even though NO adsorption induces more electron transfer from the Cu-WO3(001) substrate compared to Ag-WO3(001), Cu atoms would be easily oxidized at a usual operation temperature (above 150°C) of WO3 sensor. This oxidizing effect in noble metal atoms should be cautioned for the gas-sensing performance of WO3 sensor.

NO adsorption on Au-deposited WO3 (001) surface

We first optimize the adsorption structure of Au on WO3(001). Unlike the cases of Cu and Au catalysts, Au atom adsorbs only on top of the W atom, as shown in Figure 1e. Here, the adsorption of Au captures electrons from the WO3(001) substrate by 0.34 e because of a high electronegativity of Au atom. For the adsorption of NO on Au-WO3(001), we consider several adsorption configurations of NO, where N atom is attached to Au (denoted as P1), top W (P2), top O (P3), and hollow (P4) sites. In addition, we also consider another adsorption configuration of NO, where O atom in NO molecule is attached to Au atom (P5). The calculated adsorption energy of NO for each adsorption configuration on Au-WO3(001) is displayed in Figure 2d. We find that the P1 configuration is the most stable with Eads = −1.32 eV, which is relatively smaller in magnitude than Eads = −1.69 and −1.41 eV for the M1 configurations of NO/Cu-WO3(001) and NO/Ag-WO3(001), respectively. In the P1 configuration, the calculated bond length of adsorbed NO is dN-O = 1.182 Å (see Table 1), which is shorter than 1.212 and 1.203 Å for NO/Cu-WO3(001) and NO/Ag-WO3(001), respectively. This shortest value of dN-O is due to the fact that NO captures the least electrons (0.04 e) from Au-WO3(001), as shown in Table 1. These features of NO/Au-WO3(001) such as the smaller adsorption energy, the shorter bond length, and the less electron capture of adsorbed NO is traced to a large electronegativity of Au.

Conclusions

We have performed first-principles DFT calculations within the generalized gradient approximation for the adsorption of NO molecule on a clean WO3(001) surface as well as on the Cu-deposited, Ag-deposited, and Au-deposited WO3(001) surfaces. We found that the NO molecule prefers to adsorb on the top of W atom at a clean WO3(001) surface, where a charge transfer from WO3(001) to NO occurs by 0.19 e and Eads is calculated to be −0.48 eV. We also found that, on the Cu- and Ag-deposited WO3(001) surface, the NO molecule also binds to the W atom with Eads = −1.69 and −1.41 eV, respectively, accompanying the relatively larger charge transfer of 0.43 e (Cu) and 0.33 e (Ag) to adsorbed NO compared to the clean WO3(001) surface. On the other hand, Au atoms on WO3(001) prefer to adsorb on the top of W atom, and the NO molecule forms a bond to the Au atom with a small electron transfer of 0.04 e to adsorbed NO. We obtained a relatively smaller adsorption energy of Eads = −1.32 eV for the NO/Au-WO3(001) system compared to NO/Cu-WO3(001) and NO/Ag-WO3(001) because of a large electronegativity of Au atom. The present results demonstrated that the sensitivity of WO3 sensors for NO detection can be improved by employing the noble metal catalysts such as Cu and Ag atoms.