We have systematically studied the photocatalytic mechanisms of nitrogen doping in anatase TiO2 using first-principles calculations based on density functional theory, employing Hubbard U (8.47 eV) on-site correction. The impurity formation energy, charge density, and electronic structure properties of TiO2 supercells containing substitutional nitrogen, interstitial nitrogen, or oxygen vacancies were evaluated to clarify the mechanisms under visible light. According to the formation energy, a substitutional N atom is better formed than an interstitial N atom, and the formation of an oxygen vacancy in N-doped TiO2 is easier than that in pure TiO2. The calculated results have shown that a significant band gap narrowing may only occur in heavy nitrogen doping. With light nitrogen doping, the photocatalysis under visible light relies on N-isolated impurity states. Oxygen vacancies existence in N-doped TiO2 can improve the photocatalysis in visible light because of a band gap narrowing and n-type donor states. These findings provide a reasonable explanation of the mechanisms of visible light photocatalysis in N-doped TiO2.
1. Introduction
Photocatalytic mechanisms are created with an electron-hole pair by exciting an electron from the valence band to the conduction band through absorption of the electromagnetic radiation. Since the pioneering work of Fujishima and Honda in 1972 [1], titanium dioxide (TiO2) has attracted attention as a photocatalytic material due to nontoxicity, low cost, and chemical stability. However, anatase TiO2 has a wide band gap (3.2 eV) and only absorbs ultraviolet (UV) light at wavelengths shorter than 387 nm. UV light accounts for a small fraction (~5%) of solar energy impinging on the surface of the Earth; that is, solar energy utilization is low. Limitations due to the wide band gap make TiO2 ineffective for many potential applications. Because visible light (400–700 nm) accounts for a large fraction (~45%), the modification of TiO2 for extending optical absorption to the visible light region has become a thoroughly researched topic.
Since Asahi et al. [2] reported in 2001 that nitrogen doping enhances photocatalytic activity under visible light, TiO2 has been doped with a variety of elements, such as N [3–10], C [11], B [12], P [13], Fe [14, 15], and La [16] to study photocatalytic activity under visible light with nitrogen doping proving effectiveness. Although the nitrogen doping is considered more effective and widely studied, the photocatalytic mechanisms under visible light are still debatable. Asahi et al. [2] indicated that the N 2p states hybridize with O 2p states that result in a narrowing of the band gap with the material becoming photoactive in the visible light region. However, other studies have supported the notion that N-doping does not cause a narrowing of the band gap of TiO2 [3, 4]. For example, Irie et al. [4] considered that an isolated N 2p band above the valence band was responsible for the response to visible light. Oxygen vacancies induced by N-doping contributed to the absorption as well as photoactivity in the visible light region were also reported [17–19]. Valentin et al. [20] employed theoretical calculations to show that nitrogen doping led to a substantial reduction of energy costs to form oxygen vacancies in TiO2. This suggested that nitrogen doping was likely to be accompanied by the formation of oxygen vacancies. Rumaiz et al. [21] indicated that the related defect level of oxygen vacancies was approximately 1 eV above the valence band maximum (VBM) and explained the knee formation in the optical absorbance spectra of N-doped TiO2. Lee et al. [22] suggested that the interstitial N-doping states with the oxygen deficiency were more effective for photocatalysis than the substitutional N-doping states with the oxygen deficiency. Zhao and Liu [23] have employed density functional theory (DFT) and adopted a 2 × 1 × 1 supercell model to investigate the modification mechanism of N-doped anatase TiO2. The calculated band gap of pure anatase TiO2 was 2.68 eV, which was smaller than the experimental value of 3.2 eV, due to the limitation of DFT. The results have shown that except for oxygen deficient model, the band gaps of N-doped TiO2, including substitutional and interstitial N-doping models, were narrowed between 0.03 and 0.23 eV. The fundamental absorption edges extended to the visible light region.
As mentioned above, the mechanisms of N-doping in TiO2 under visible light region have three views: (1) band gap narrowing, (2) impurity energy levels, and (3) oxygen vacancies. Although theoretical calculations have been investigated for the mechanisms, most of them greatly underestimated the band gap of TiO2 due to the adoption of conventional DFT method. In this paper, first-principles calculations employing the generalized gradient approximation (GGA) and Hubbard U approach are performed to investigate the formation energy, charge density, and electronic structure of N-doped anatase TiO2 with oxygen vacancies systematically to comprehend the mechanisms of N-doped anatase TiO2. The calculated results were analyzed and compared with the previous literature.
2. Calculation Models and Methods
A 2 × 2 × 1 supercell of a pure anatase TiO2 containing 16 Ti atoms and 32 O atoms was considered in this study as shown in Figure 1(a). To investigate the effect of the N-doping and oxygen vacancy in TiO2 on the electronic structure, five defect types were modeled as shown in Figures 1(b)–1(f). The substitutional N-doping supercell (Figure 1(b)) was labeled Ns and constructed by substituting one oxygen atom with one nitrogen atom (2.1 at.%) and the interstitial N-doping supercell (Figure 1(c)) being labeled Ni, with one N atom was embedded into the interspace. In oxygen vacancy systems, one O atom was removed and were labeled Ov (Figure 1(d)), NsOv (Figure 1(e), with one O atom being substituted by N atom), and NiOv (Figure 1(f), with one N atom being embedded into the interspace).
2 × 2 × 1 anatase TiO2 supercell models: (a) pure TiO2; (b) substitutional N-doping (Ns); (c) interstitial N-doping (Ni); (d) oxygen vacancy (Ov); (e) substitutional N-doping with oxygen vacancy (NsOv); and (f) interstitial N-doping with oxygen vacancy (NiOv). Gray, red, blue, and dotted line spheres represent Ti, O, and N atoms, and oxygen vacancy, respectively.
First-principles calculations were performed using the CASTEP module [24] in Materials Studio 5.0 developed by Accelrys Software Inc. Electron-ion interactions were modeled using ultrasoft pseudopotentials in the Vanderbilt form [25]. The valence atomic configurations were 2s22p4 for O, 2s22p3 for N, and 3s23p63d24s2 for Ti. The wave functions of the valence electrons were expanded through a plane wave basis set, and the cutoff energy was selected as 400 eV. The Monkhorst-Pack scheme [26] K-points grid sampling was set at 4 × 4 × 3 (less than 0.04 Å−1) in the supercells. The convergence threshold for self-consistent iterations was set at 5 × 10−6 eV. In the optimization process, the energy change, maximum force, maximum stress, and maximum displacement tolerances were set at 9 × 10−5 eV/atom, 0.09 eV/Å, 0.09 GPa, and 0.009 Å, respectively.
The spin-polarized GGA+U approach introduced an intra-atomic electron-electron interaction as an on-site correction to describe systems with localized d and f electrons capable of producing a more optimal band gap. Determination of an appropriate effective Hubbard Ueff parameter is necessary in GGA+U calculations to interpret the intra-atomic electron correlation correctly. As shown in Figure 2, for anatase TiO2, the band gap widens when the effective Hubbard Ueff was increased. The band gap was effectively widened by increasing Ueff from 2 to 8 eV. Here, the effective on-site Coulomb interaction was Ueff = 8.47 eV for Ti 3d in the GGA+U approach and the calculated band gap of pure anatase is 3.21 eV, similar to the experimental value.
Relationship between the effective Hubbard parameter (Ueff) and the band gap (Eg) of anatase TiO2.
3. Results and Discussion3.1. Formation Energy
To examine the relative stability of N-doped TiO2 for various defective models, the defect formation energies (Ef) were calculated according to the following formula:
(1)Ef=Etot(defect)-Etot(pure)-mμN+nμO.Etot(defect) and Etot(pure) are the total energies of defective models and pure TiO2; μN and μO represent the chemical potentials of the N and O atoms; m and n are the numbers of doped nitrogen and removed oxygen atoms; m=1 and n=1 for Ns model, and m=1, n=0 for Ni model, m=0, n=1 for Ov model, m=1, n=2 for NsOv model, m=1, n=1 for NiOv model. The formation energy depends on growth conditions and can be Ti-rich or O-rich. For TiO2, μTi and μO satisfy the relationship μTi+2μO=μTiO2. Under the O-rich growth condition, μO is determined by the total energy of an O2 molecule (μO=μO2/2) and μTi is determined by the formula μTi=μTiO2-2μO. Under the Ti-rich growth condition, μTi is the energy of one Ti atom in bulk Ti and μO is determined by μO=(μTiO2-μTi)/2.
It should be noted that the formation energy of a defective system depends on the selected U value. The U value of 8.47 eV was fixed to qualitatively examine the relative stability of N-doped TiO2 for various defective models in this study. Table 1 summarizes the calculated formation energies for different defective models in TiO2. The smaller Ef value represents that a defective system is more stable. The Ef(Ns) (formation energy of Ns model) is smaller under the Ti-rich condition than that under O-rich condition, indicating that the incorporation of N into TiO2 at the O site is thermodynamically favorable. At the Ti-rich condition, the Ef(Ns) is smaller than Ef(Ni), indicating that substitutional N atoms are more probable to be formed. This result is opposite with Zhao’s calculated result (interstitial N atoms are favored) [23], but is consistent with Lee’s calculated result [22]. It can be found that the formation energy of an oxygen vacancy from pure TiO2 is 1.0 eV (Ef(Ov)=1.0) and that from Ns-doped TiO2 is 0.26 (Ef(NsOv)-Ef(Ns)). This represents that the formation of oxygen vacancies with N existence in TiO2 is easier than pure TiO2 and is in agreement with the previous literature [21, 23].
Formation energy and average Mulliken population of various defective models of N-doped TiO2.
TiO2
Formation energy
Mulliken population (|e|)
Model
Ti-rich
O-rich
Ti
O
N
Pure
1.470
−0.730
Ns
0.21
4.51
1.464
−0.737
−0.620
Ni
3.07
3.07
1.469
−0.728
−0.270
Ov
1.00
5.30
1.435
−0.744
NsOv
0.47
9.07
1.435
−0.741
−0.750
NiOv
4.18
8.48
1.419
−0.726
−0.180
3.2. Electronic Density
Table 1 summarizes Mulliken populations. Figure 3 indicates the charge distribution of each defective model of N-doped TiO2. For pure TiO2, the average population values of Ti and O atoms are 1.47 and −0.73. The Ti atom has a much higher population value which indicates that a large oxidation occurred. For Ns model, Table 1 shows that the Mulliken population of Ns (−0.62) is larger than that of O (−0.737) and leads to an unfilled 2p orbital in the N atom because the electronegativity of N is lower than that of O as shown in Figure 3(a). For Ni model, the Mulliken population of Ni is −0.27, indicating that the Ni atom obtains fewer electrons from Ti atoms. Figure 3(b) shows that the charge is shared between the Ni atom and its neighbor O atom and the similar results were reported by Rumaiz et al. [21]. For Ov model, as caused by two extra electrons after removing an oxygen atom, the Mulliken populations of Ti and O (1.435 and −0.744) are both smaller than in the pure model and lead to more electrons in Ti and O atoms. Figure 3(c) shows that the electrons are remained in a Ti atom near the oxygen vacancy. Comparing the Ns with NsOv models, the Mulliken population of N atom decreases from −0.62 to −0.75, indicating that there are more electrons that transfer from oxygen vacancy to the N atom, and the N 2p orbital is filled as shown in Figure 3(d). For NiOv model, the electron clouds are shared between Ni and the adjacent O atoms. They increase the population values in Ni and O atoms.
Charge distribution of various defective models in N-doped TiO2: (a) Ns, (b) Ni, (c) Ov, (d) NsOv, and (e) NiOv.
3.3. Electronic Structure
Figure 4 indicates the total density of states (TDOS), and the projected density of states (PDOS) of various defective models was calculated to investigate the electronic properties of N-doped anatase TiO2. Other related values that were calculated include the band gap (Eg), the width of the valence band (WVB), and the maximum absorption wavelength (λmax = 1240/Eg) that Table 2 summarizes. The band gap (Eg) of pure anatase TiO2 is 3.21 eV as shown in Figure 4(a) and is consistent with the experimental value of 3.2 eV. The valence band of TiO2 has a large bandwidth (WVB) of approximately 4.63 eV, showing a strong delocalization among the O 2p electrons. For Ns model from Figure 4(b), the Eg gap is 3.17 eV and the WVB is 4.68 eV, implying that Eg and WVB are not changed obviously compared with the pure TiO2. It is demonstrated from Figure 4(b) that one isolated N 2p state is localized above the top of the VB of the host TiO2 and is consistent with the calculations of Long [27]. The electron in the VB is excited to localized impurity states in the band gap and subsequently to the CB through absorption of visible light. For Ni model from Figure 4(c), the Eg is narrowed to 3.08 eV and the WVB is broadened to 4.86 eV. It was observed that the N 2p states primarily contributed to three energy ranges: −7.5 to −6.1, −0.6 to 0, and 1.8 to 2 eV. For Ov model from Figure 4(d), the Eg (3.18 eV) is not changed obviously and the WVB is broadened to 5.12 eV. The two extra electrons resulted from removing an oxygen atom lead to an occupied state near Fermi energy level and are localized at 1.0 eV above the top of VB and consistent with the experimental results [21]. Comparing with the Ns and Ni models, both band gaps of the NsOv and NiOv (2.95 and 3.06 eV) became smaller and extended optical absorption into the visible region (420 and 405 nm). Figures 4(e)-4(f) show that the WVB became broader. Therefore, the existence of oxygen vacancies in N-doped anatase TiO2 improves the photocatalysis under visible light. Our previous work regarding DOS for heavy nitrogen doping in the N-doped anatase TiO2 are shown in Figures 4(g)-4(h) [8]. It can be observed that a significant narrowing of the band gap of N-doped TiO2 occurs only for heavy nitrogen doping (≥8.3 at.%) and is in agreement with Ashai calculated results [2]. As a result, the electron transition energy from the valence band to the conduction band decreased by approximately 0.88 eV because of the heavy nitrogen doping and, thus, may induce a red shift (extending to 532 nm) at the edge of the optical absorption range. Both the narrowing of the band gap and the increased mobility of photo-generated carriers in heavy nitrogen doping concentrations improve the photocatalytic activity under visible light, as illustrated in recent experimental results [6, 7].
Band gap, maximum absorption, wavelength, and width of valence band for various defective models of N-doped TiO2.
Model
Eg (eV)
λmax (nm)
WVB (eV)
Pure
3.21
386
4.63
Ns (2.1 at.%)
3.17
391
4.68
Ni
3.08
402
4.86
Ov
3.18
390
5.12
NsOv
2.95
420
4.97
NiOv
3.06
405
5.04
Ns (8.3 at.%)
2.33
532
5.14
Ns (10.4 at.%)
2.36
525
5.80
DOS of various defective models of N-doped TiO2: (a) pure TiO2, (b) Ns (2.1 at.%), (c) Ni, (d) Ov, (e) NsOv, (f) NiOv, (g) Ns (8.3 at.%), and (h) Ns (10.4 at.%).
4. Conclusions
Using the GGA+U method, this study calculated impurity formation energy, charge density, and electronic properties of an N-doped anatase TiO2 with oxygen vacancies system to investigate the photocatalytic mechanisms of N-doped TiO2 under visible light. An effective Hubbard U of 8.47 eV was adopted to determine the experimental band gap correctly. The formation energy calculated results have shown that the substitutional N atom was easier to be formed than the interstitial one and the formation of oxygen vacancies under nitrogen existence in TiO2 was easier to be formed than pure TiO2. The calculated results have shown that the mechanisms of photocatalytic activity under visible light are concluded as the following: (1) the significant band gap narrowing may occur in heavy nitrogen doping; (2) with light nitrogen doping, the mechanism is the result of N-isolated impurity states; and (3) oxygen vacancies existence in N-doped TiO2 improves the photocatalysis in visible light because of a band gap narrowing and n-type donor states.
Acknowledgments
This work was supported by the National Science Council in Taiwan (NSC 101-2221-E-131-022), for which the authors are grateful. The authors also acknowledge the National Center for High-Performance Computing for computer time and the use of its facilities.
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