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Identifying and rationalizing the morphological,
structural, and optical properties of β-Ag2MoO4
microcrystals, and the formation process of
Ag nanoparticles on their surfaces: combining
experimental data and first-principles calculations

Maria T Fabbro, Carla Saliby, Larissa R Rios, Felipe A La Porta, Lourdes
Gracia, Máximo S Li, Juan Andrés, Luís P S Santos & Elson Longo

To cite this article: Maria T Fabbro, Carla Saliby, Larissa R Rios, Felipe A La Porta, Lourdes
Gracia, Máximo S Li, Juan Andrés, Luís P S Santos & Elson Longo (2015) Identifying and
rationalizing the morphological, structural, and optical properties of β-Ag2MoO4 microcrystals, and
the formation process of Ag nanoparticles on their surfaces: combining experimental data and
first-principles calculations, Science and Technology of Advanced Materials, 16:6, 065002, DOI:
10.1088/1468-6996/16/6/065002

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Identifying and rationalizing the
morphological, structural, and optical
properties of β-Ag2MoO4 microcrystals, and
the formation process of Ag nanoparticles
on their surfaces: combining experimental
data and first-principles calculations

Maria T Fabbro1,2, Carla Saliby1, Larissa R Rios1, Felipe A La Porta4,
Lourdes Gracia6, Máximo S Li5, Juan Andrés6, Luís P S Santos3 and
Elson Longo7

1Department of Chemistry, CDMF, Universidade Federal de São Carlos, 13565-905, São Carlos, Brazil
2 Department of Inorganic and Organic Chemistry, Universitat Jaume I, Campus Riu Sec, E-12071,
Castellón, Spain
3Department of Chemistry, INCTMN, Instituto Federal do Maranhão, Monte Castelo, 65030-005, São
Luís, Brazil
4 Department of Chemistry, Universidade Tecnológica Federal do Paraná, 86036-370, Londrina, Brazil
5 Instituto de Física de São Carlos, Universidade de São Paulo, 13560-970, São Carlos, Brazil
6 Department of Physic and Analytical Chemistry, Universitat Jaume I, Campus Riu Sec, E-12071,
Castellón, Spain
7 CDMF, INCTMN, Instituto de Química, Universidade Estadual Paulista, Araraquara, 14801-907, Brazil

E-mail: presleyserejo@gmail.com

Received 23 June 2015, revised 13 October 2015
Accepted for publication 13 October 2015
Published 5 November 2015

Abstract
We present a combined theoretical and experimental study on the morphological, structural, and
optical properties of β-Ag2MoO4 microcrystals. β-Ag2MoO4 samples were prepared by a co-
precipitation method. The nucleation and formation of Ag nanoparticles on β-Ag2MoO4 during
electron beam irradiation were also analyzed as a function of electron beam dose. These events
were directly monitored in real-time using in situ field emission scanning electron microscopy
(FE-SEM). The thermodynamic equilibrium shape of the β-Ag2MoO4 crystals was built with
low-index surfaces (001), (011), and (111) through a Wulff construction. This shape suggests
that the (011) face is the dominating surface in the ideal morphology. A significant increase in
the values of the surface energy for the (011) face versus those of the other surfaces was
observed, which allowed us to find agreement between the experimental and theoretical
morphologies. Our investigation of the different morphologies and structures of the β-Ag2MoO4

crystals provided insight into how the crystal morphology can be controlled so that the surface
chemistry of β-Ag2MoO4 can be tuned for specific applications. The presence of structural
disorder in the tetrahedral [MoO4] and octahedral [AgO6] clusters, the building blocks of β-

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Ag2MoO4, was used to explain the experimentally measured optical properties.

Keywords: theoretical calculations, morphology, electron beam irradiation, β-Ag2MoO4

1. Introduction

Metal molybdates are of both theoretical and technological
importance because they exhibit a wide range of electrical and
optical properties that are broadly applicable in photo-
catalysis, solar energy conversion, and energy storage [1–14].
Recently, Zhang et al [15] reviewed the representative
hydrothermal strategies for synthesizing inorganic semi-
conducting nanostructures. Several methods have been used
to synthesize metal molybdates with different sizes and
morphologies, including precipitation [16], sol-gel [17, 18],
solid state [19], hydrothermal [20], complete evaporation of a
polymer-based metal-complex precursor solution [21], and a
microwave-assisted hydrothermal method [22–24].

Ag2MoO4 is an important member of the molybdate
family. Several reports have been published on its attractive
properties for numerous applications in materials science [25–
39]. Up to now, various nano- or microstructures of
Ag2MoO4 have been fabricated, such as nanoparticles [25],
wire-like nanostructures [35], and flower-like microstructures
[36]. Bao et al [37] reported the synthesis of silver molybdate
nanowires decorated with Ag nanoparticles (NPs) using a
solution-based chemical reaction at room temperature.
Ag2MoO4 exists in two polymorphic forms: tetragonal (α-
phase) and cubic (β-phase) [38–40]. Recently our research
group performed a systematic first-principles investigation to
calculate the structural and electronic properties of both α-
and β-Ag2MoO4, and its pressure-induced phase transitions
[28]. We also investigated the correlation between theoretical
calculations and our experimental data to better understand
the nucleation and early evolution of Ag filaments on β-
Ag2MoO4 crystals. These crystals were synthesized by a
microwave-assisted hydrothermal method [25] and a co-pre-
cipitation method at pH 4 [29]. The electronic structures of α-
and β-Ag2MoO4 have also been investigated [41].

This paper presents a detailed study, based on experi-
mental data combined with first-principles calculations, on the
correlation between growth conditions, morphology, and
optical properties of β-Ag2MoO4. Samples were structurally
characterized using x-ray diffraction (XRD) with Rietveld
refinement and micro-Raman (MR) spectroscopy. The mor-
phology, shape, and elemental composition of the crystals
were verified by FE-SEM. Room temperature optical prop-
erties were investigated by ultraviolet–visible (UV–vis)
absorption spectroscopy and photoluminescence (PL) mea-
surements. According to Wulff’s law [42], the thermo-
dynamic equilibrium morphology of the β-Ag2MoO4 crystals
is obtained from the surface energies of the facets. The
inherent instability of crystals under an electron beam means
that the illuminating radiation can potentially induce atomic
movement, resulting in modifications to the surfaces and
internal structures. Therefore, the formation of Ag NPs on β-
Ag2MoO4 induced by electron irradiation was studied. Elec-
tron irradiation effects must be carefully analyzed to ensure

high fidelity in the characterization of particle structure.
Details of this analysis are reported. These findings provide a
better understanding of β-Ag2MoO4-based materials at the
atomic scale. This new understanding will be beneficial for
the fabrication of other metal oxide nanomaterials with highly
exposed crystal surfaces, which have potential applications in
gas sensing devices, optical devices, and catalysts.

The paper is organized as follows: section 2 describes the
experimental and computational methods. In section 3,
experimental and theoretical results are presented and dis-
cussed in detail. A brief summary and the main conclusions
will be offered in section 4.

2. Experimental details

2.1. Synthesis of β-Ag2MoO4

β-Ag2MoO4 microcrystals were synthesized without the use
of a surfactant via a co-precipitation method using ethanol as
a solvent. First, 1 mmol of sodium molybdate dihydrate
(Na2MoO4.2H2O; 99.5% purity, Sigma-Aldrich) was dis-
solved in 50 ml of ethanol (solution 1). Separately, 2 mmol of
silver nitrate (AgNO3; 99.8% purity, Sigma-Aldrich) was
dissolved in 50 mL of ethanol (solution 2). Solution 2 was
added drop-wise to solution 1 under vigorous magnetic stir-
ring while heating at 70 °C for 10 min. The precipitate was
collected by centrifugation, washed several times with deio-
nized water, and dried at 60 °C for 12 h.

2.2. Characterization

The β-Ag2MoO4 samples were structurally characterized by
XRD using a DMax/2500 PC diffractometer (Rigaku) with
Cu-Kα radiation (λ=1.5406 Å). Two different scan settings
were used, both with a step of 0.02°: (1) normal routine in the
2θ range of 10–75° with a scanning velocity of 2°min−1, and
(2) Rietveld routine in the 2θ range of 10–110° with a
scanning velocity of 1°min−1. The phase analysis by the
Rietveld method [43] was performed using the General
Structure Analysis System (GSAS) software [44]. MR mea-
surements were recorded using a Modular Raman Spectro-
meter (Horiba, Jobin Yvon), model RMS-550 with Ar laser
excitation at 514 nm, and a fiber-microscope operating at
30–1000 cm−1. The morphology, microanalysis, and size of
the β-Ag2MoO4 structures were determined by FE-SEM
(Supra 35-VP, Carl Zeiss), operated at different voltages (i.e.,
5, 10, 15, and 20 kV). UV–vis spectra were recorded using a
Varian spectrophotometer (Model Cary 5G) in the diffuse
reflection mode. PL spectra were collected with a Thermal
Jarrel Ash Monospec monochromator and a Hamamatsu
R446 photomultiplier. The 350.7 nm (2.57 eV) line of a
krypton ion laser (Coherent Innova) was used with the output

2

Sci. Technol. Adv. Mater. 16 (2015) 065002 M T Fabbro et al


of the laser kept at 200 mW. All measurements were taken at
room temperature.

2.3. Computational methods

First-principles total-energy calculations were carried out
within the periodic density functional theory (DFT) frame-
work using the Vienna ab initio Simulation Package (VASP)
[45–48]. The Kohn–Sham equations were solved using the
generalized gradient approximation (GGA) in the Perdew–
Burke–Ernzerhof (PBE) functional to determine the electron
exchange and correlation contributions to the total energy
[49, 50]. The conjugate gradient (CG) energy minimization
method was used to obtain the minimum (relaxed) energy
state of the crystal. Atoms are considered fully relaxed when
the Hellmann−Feynman forces converge to less than
0.005 eV Å−1 per atom. The electron–ion interaction was
described within a plane wave basis set by the projector
augmented wave (PAW) method [51]. The plane-wave
expansion was truncated at the 460 eV cut-off energy. The
Brillouin zones were sampled through Monkhorst–Pack spe-
cial k-point grids that assured geometrical and energetic
convergence for the β-Ag2MoO4 structures. Vibrational-fre-
quency calculations were performed at a point in the har-
monic approximation. The dynamical matrix was computed
by numerical evaluation of the first derivative of the analytical
atomic gradients.

To confirm the convergence of the total energy with
respect to the slab thickness of the different surface models,
the Esurf for several low-index planes was calculated. Esurf is
defined as the total energy per repeating cell on the slab (Eslab)
minus the total energy of the perfect crystal per molecular unit
(Ebulk) multiplied by the number of molecular units on the
surface (n), divided by the surface area per repeating cell of
the two sides of the slab, as shown in equation (1):

E
E nE

A2
. 1surf

slab bulk ( )=
-

The equilibrium shape of a crystal can be calculated by
using the classic Wulff construction that minimizes the total
surface free energy at a fixed volume. It provides a simple
relationship between the surface energy, Esurf, of the (hkl)
plane and its distance rhkl in the normal direction from the
center of the crystallite.

The conventional cubic unit cell of β-Ag2MoO4 contains
8 formula units. Mo atoms occupy 8a tetrahedral sites, Ag
atoms reside at the octahedral 16d position, and O atoms stay
at 32e positions. The (001), (011) and (111) surfaces of β-
Ag2MoO4 were characterized by an unreconstructed slab
model using a calculated equilibrium geometry (a=9.454 Å,
u(O)=0.2351) using a (3×3×1) Monkhorst–Pack spe-
cial k-point grid. A vacuum spacer of 15 Å was introduced in
the z-direction so that the surfaces would not interact with
each other.

3. Results and discussion

XRD patterns of β-Ag2MoO4 are illustrated in figure 1. All
XRD peaks of β-Ag2MoO4 crystals indicate that this material
exhibits a cubic spinel structure without any deleterious
phases, in good agreement with the Inorganic Crystal Struc-
ture Database (ICSD) card no. 28891 [40]. These micro-
crystals have sharp, well-defined diffraction peaks, which
indicate a long-range structural order and crystallinity.

The Rietveld refinement method was employed in this
study (see figure 2(a)), in order to understand the crystal
structure of β-Ag2MoO4, and prove that the as-synthesized
compounds are pure single-phase crystals. Figure 2(a) shows
the Rietveld refinement plots for the observed XRD patterns
versus the calculated patterns of the β-Ag2MoO4 crystals. In
particular, the fitting parameters (RWP, Rp, Rexp, and χ2) in
figure 2(a) (inset) indicate good agreement between the
refined and observed XRD patterns. These parameters con-
firm the existence of a single phase with a spinel structure
belonging to the space group Fm3m. We compared the
experimental structural parameters determined for the as-
synthesized β-Ag2MoO4 crystals using the Rietveld refined
parameters with the theoretical data obtained using first-
principles calculations. The experimental values for the cell
dimensions of the β-Ag2MoO4 crystals are 9.314 Å, while the
calculations yielded a lattice parameter of 9.427 Å, which is
only 1.2% greater than the experimental value. These results
are consistent with the experimental values reported by Arora
et al [38]. Arora’s group performed powder XRD measure-
ments at ambient pressure, obtaining a single-phase material
with a lattice parameter of 9.313 Å. Based on this structural
analysis, we can determine the differences between the values
of the angles between the [AgO6] and [MoO4] clusters, and
the atomic positions.

Figure 2(b) shows a schematic representation of the β-
Ag2MoO4 unit cells. The experimental values for the lattice
parameters and atomic positions were calculated using the

Figure 1. XRD patterns of the β-Ag2MoO4 crystals. Red lines are
drawn from the ICSD card no. 28891.

3

Sci. Technol. Adv. Mater. 16 (2015) 065002 M T Fabbro et al


Visualization for Electronic and Structural Analysis (VESTA)
program (Version 3.1.3 for Windows) [52], so that we could
model the cubic β-Ag2MoO4 spinel structure. β-Ag2MoO4

belongs to the space group Fd-3m, where each Mo atom is
surrounded by four O atoms, forming distorted tetrahedral
[MoO4] clusters, whereas Ag atoms occupy the center of
distorted octahedral [AgO6] clusters. These results indicate
that the tetrahedral [MoO4] and octahedral [AgO6] clusters
have lattice distortions and exhibit specific characteristics
related to differences in the [O–Mo–O] and [O-Ag-O] bond
angles.

It is noteworthy that the presence of defects in the local
structure of these materials results from a large number of
factors that are strongly dependent on synthesis methods
and experimental conditions (e.g., choice of precursor,
modifier, solvent, temperature, pH, processing time, etc)
[53–56]. Thus, the structural characteristics of these clusters
may explain some specific properties of the β-Ag2MoO4

crystals that have a cubic spinel structure at the atomic
level.

MR spectroscopy was used as a probe to investigate the
degree of structural order–disorder in the crystal at short-
range [57]. The MR spectra of the synthesized β-Ag2MoO4

microcrystals are depicted in figure 3. According to group
theory calculations, molybdates with a cubic spinel structure
exhibit five Raman-active modes, which are represented by
equation (2) [28]:

A E T3 . 2g g g1 2 ( )G = + +

As seen in figure 3(a), the MR spectrum shows the pre-
sence of five Raman-active vibrational modes for β-
Ag2MoO4. Figure 3(a) also shows an MR spectrum exhibiting
broad vibrational modes, indicating structural disorder at
short-range. The Raman-active mode observed for β-
Ag2MoO4 at 872 cm−1 is ascribed to the A1g mode. The
symmetric stretching vibration of the Mo–O bond in [MoO4]
clusters caused this mode. The T2g mode detected at
779 cm−1 refers to the asymmetric stretching of this bond. We
assigned a bending mode for the peak at 372 cm−1 in the
tetrahedral [MoO4] cluster, whereas the Eg mode at 282 cm−1

10 20 30 40 50 60 70 80 90 100 110

In
te

ns
ity

 (a
rb

. u
ni

ts
)

Experimental

Diference
Calculated

Octahedral
[AgO8] clusters

Tetrahedral
[MoO4] clusters

2-Theta (Cu/Kαα) / degree

(a) (b)

R  = 6.48%

R = 5.41%

R = 4.03%

χ = 2.455

a

c

b

Figure 2. (a) Observed (black line), calculated (red line), and difference (blue line) profiles obtained after Rietveld refinement for
β-Ag2MoO4. (b) Illustration of the β-Ag2MoO4 spinel structure.

100 200

200

0

400

600

800

1000

200

0

400

600

800

1000

300 400 500 600 700 800 900 1000

R
am

an
 s

hi
ft 

(c
m

-1
)

Raman Shift (cm-1)

R
am

an
 s

hi
ft 

(c
m

-1
)

T2g

T2g T2g

T2g

Eg

Eg

T2g T2g A1g

A1g

Raman-active modes

In
te

ns
ity

 (a
rb

. u
ni

ts
)

Experimental Raman modes
Teoretical Raman modes

76 10
2

29
6

37
2

77
9

89
3

(a)

(b)

Figure 3. (a) Raman spectrum of β-Ag2MoO4. (b) A comparison of theoretical and experimental analyses of the Raman-active vibrational
modes in β-Ag2MoO4.

4

Sci. Technol. Adv. Mater. 16 (2015) 065002 M T Fabbro et al


represents a lattice mode involving vibrations of Ag cations.
Therefore, the T2g modes detected at 81 cm−1 are also asso-
ciated with the vibrations of Ag cations, as reported by Bel-
tran et al [28]. Figure 3(b) confirms agreement between the
observed vibrations and those reported in the literature [29].
Small shifts in observed Raman mode positions can arise
from different factors such as preparation methods, average
crystal size, interaction forces between the ions, or the degree
of structural order in the lattice [57]. Moreover, active Raman
modes confirm that β-Ag2MoO4 is structurally ordered at
short-range, but the peaks are relatively wide, which is an
indication of some structural disorder.

Our group observed the formation of Ag filaments on β-
Ag2MoO4 via electron beam irradiation during FE-SEM
imaging [41]. Such beam effects have been also reported for
α-Ag2WO4 [58–60]. Figure 4 shows a time-resolved series of
FE-SEM images obtained under high vacuum (1×10−5 Pa)
during the growth of Ag nanoparticles after the absorption of
energetic electrons by the β-Ag2MoO4 surface at 5, 10, 15,
and 20 kV, respectively, and at different times: 0 and 5 min.
Figure 4 also shows the size distribution of Ag nanoparticles
at different voltages after 5 min of image acquisition. When
the absorption of energetic electrons by the β-Ag2MoO4

surface occurs, the nucleation of Ag nanoparticles generating
Ag vacancy defects occurs, which are related to the different
average size distributions of particles. As observed in figure 4,
the growth of Ag nanoparticles on the surface of β-Ag2MoO4

increases as the applied voltage increases. However, the
growth process does not have a preferred region but rather
occurs in all regions irradiated by the electron beam.

The absorption of electrons at the surface of the crystal
generates an n-type semiconductor with Ag vacancies. The
formation of Ag filaments caused the creation of a new p-type
semiconductor, in which the nanoparticles of Ag on the β-
Ag2MoO4 have collective oscillations of their electrons in the
conduction band, which are known as localized surface
plasmon resonances (LSPRs). These two systems are linked
by the LSPR effect. The formation of silver filaments con-
tinues as the exposure time increases, increasing the con-
centration of silver vacancies. Additionally, the system that
was polarized at the short- and medium-range produces a
long-range polarization. This event leads to a structural
rearrangement of the crystal, with the formation of new
absorption centers of electrons and creation of silver fila-
ments. It is important to note that the crystal structure is
maintained along these phenomena and the formation process
of Ag filaments is reversible, i.e. some Ag filaments are
created on the surface while some others disappear.

The design of new complex functional materials with
control of shape and surface structure is essential for a variety
of technological applications and, hence, represents a fasci-
nating challenge for researchers [61–66]. It is well known that
the surface energy of facets and their stability depend on the
strength of the bond between a surface atom and its nearest
neighbors. Therefore, more open facets, edges, and apexes
with under-coordinated atoms (i.e., reduced coordination
numbers), will increase the crystal’s energy, resulting in a
decreased energy barrier for atom movement. The result, then,

is a crystal with lower structural stability. Conversely, high-
index facets often exhibit increased chemical activity, such as
catalysis, photodegradation, and antibactericide performance,
as they offer active sites for adsorption of reactant molecules.

A way to control the structure and morphology of new
complex functional materials would play a significant role in
determining their physical and chemical properties. This
ability would naturally lead to subsequent scientific and
technological applications and, in particular, provide oppor-
tunities to tune and explore the optical of new structures.
Nanocrystals can be grown in a variety of shapes and
morphologies through the modification of surface energies of
facets via adjustment of the experimental parameters, such as
surfactant, and solvent choice. Therefore, control of structure
and morphology is of great interest in the development of
complex functional materials with customized features
[67–71].

A range of stoichiometric surfaces for β-Ag2MoO4 with
low Miller indices including (011), (001), and (110) surfaces
were constructed and subjected to first-principles studies. The
morphologies were built witha range of shapes. Figure 5
shows the Wulff construction of optimized β-Ag2MoO4, and
the different morphologies that could be obtained assuming
different surface energy ratios for several facets. These results
clearly demonstrate that the transformations between various
morphologies are due to the geometric constraints imposed by
the crystal structure, and are associated with the relative
surface energy values of each face. This approach has the
advantage that all faces are derived from the same initial
crystal shape (ideal), grown as a function of their surface
energy values.

It is important to note that the (011) and (001) surfaces
are the most stable among all of the surfaces evaluated,
whereas the (111) surface has the highest surface energy.
After the corresponding convergence test on the systems, slab
models containing 6, 8 and 6 molecular units for (001), (011)
and (111) surfaces, with areas of 44.7, 63.2 and 38.7 Å2,
respectively, were evaluated. It is worth noting that the (001)
and (011) surfaces are O- and Ag-terminated, while the (111)
surface is O- and Mo-terminated. The slab representation is
shown in figure 6. In this case, the (011) orientation is the
dominating surface in the predicted equilibrium shape (ideal)
of the β-Ag2MoO4 crystals. This prediction was obtained
using the Wulff construction. This analysis suggests that the
Wulff model of the β-Ag2MoO4 crystal shapes is closely
related to the surrounding chemical environment. Hence, a
larger increase in the surface energy of the (011) surface
rather than an increase in the other surfaces showed good
agreement between the experimental and theoretical
morphologies. In particular, when the values of the surface
energies of both (001) and (011) surfaces are similar,
experimental and theoretical morphology agrees (see
figure 5(b)).

Despite some differences between the in vacuum condi-
tions employed in the calculations and the actual conditions
used for crystal growth in the laboratory, the most stable
predicted faces usually showed the largest fraction of crystal
surfaces. Therefore, the diagrams presented in figure 5 are a

5

Sci. Technol. Adv. Mater. 16 (2015) 065002 M T Fabbro et al


strong motivation to develop a relationship between crystal
growth conditions and the experimentally observed
morphologies. This relationship would allow us to predict
morphologies resulting from different conditions. These
findings promise to be very useful in interpreting changes in
morphology. The above results are an illustration of how DFT
calculations can provide substantial insight into the

fundamental mechanisms for stabilizing micro- and nano-
morphologies at the atomic level. Our work has shown that
theory can be used to obtain a more in-depth understanding of
experimental results. Theory may also help orient researchers
in the choice of solvent, surfactants, and other relevant
experimental parameters. Theory can also serve as guideline
for tuning the performance of these materials by altering their

Figure 4. FE-SEM images of the β-Ag2MoO4 microcrystals (left) and growth of Ag nanoparticles on the β-Ag2MoO4 surface facets at 5, 10,
15, and 20 kV (right), respectively; histograms of Ag particle area distribution at different voltages after 5 min.

6

Sci. Technol. Adv. Mater. 16 (2015) 065002 M T Fabbro et al


shape. Using this approach, researchers can avoid following a
trial-and-error process, which often follows the chemical
synthesis of complex functional materials, and conduct
rational structural design of new experiments.

The UV–visible diffuse reflectance spectrum of β-
Ag2MoO4 was recorded and the optical band gap energy (Eg)
calculated by the Kubelka and Munk equation [71], as shown
in figure 7. According to Li et al [72], the optical band gap for

Figure 5. Wulff’s construction of β-Ag2MoO4. Morphologies and facets as a function of their surface energy values.

Figure 6. Schematic representation of the geometry for the (001), (011), and (111) faces.

7

Sci. Technol. Adv. Mater. 16 (2015) 065002 M T Fabbro et al


β-Ag2MoO4 is of the indirect type. Using optical measure-
ments, Li and his group deduced a band gap for β-Ag2MoO4

of 3.37 eV. In our case, the value calculated from the UV–vis
spectrum is 3.33 eV. This result is in agreement with the lit-
erature [28, 29, 72] that indicates the existence of inter-
mediary energy levels within the optical band gap of β-
Ag2MoO4 crystals. Hence, they are formed by structural
disorder of the tetrahedral [MoO4] and octahedral [AgO6]
clusters that increase the numbers of electron–hole pairs.

The PL emission spectra of both as-synthesized and
irradiated β-Ag2MoO4 microcrystals are shown in figure 8.
The PL profile suggests an emission mechanism characterized
by the participation of several energy levels or light emission
centers able to trap electrons within the band gap. This
mechanism is typical of a multiphonon process [54]. These
results indicate that the specific atomic arrangement of β-
Ag2MoO4 microcrystals can distort the [O–Ag–O] and [O–

Mo–O] bonds. Consequently, different levels of distortion on
the tetrahedral [MoO4] and octahedral [AgO6] clusters in the
β-Ag2MoO4 lattice can occur, which are mainly responsible
for PL emissions. These changes can in turn alter the Ag–O
and Mo–O bond lengths, the O–Ag–O and O–Mo–O bond
angles and therefore the electronic and optic behavior of the
material, resulting in complex coupled phenomena. This
effect is similar to previous studies reported by our group on
the PL emissions in tungstates [73], molibdates [74], and
perovskite based materials [75–77]. Indeed, the PL emission
profile analysis reveals a common feature; a pronounced
maximum in the blue region (449 nm) that is related to dis-
tortions in the tetrahedral [MoO4] clusters [29, 78]. A weak
emission was also observed in the orange (650 nm) region
that indicates an ordered structure (see figure 8). On the other
hand, the observations of PL emission of the irradiated β-
Ag2MoO4 microcrystals appear to favor a nucleation process
for Ag.

Therefore, electron irradiation generates structural and
electronic disorder, increasing the density of electron–hole
pairs. These structural changes are related to charge transfer in
a crystal that contains more than one kind of cluster, and is
characterized by excitations involving electronic transitions
from one cluster to another. Then, clusters of a silver oxide
[AgOx] absorb electron irradiation resulting in reduction of
the silver ion to metallic silver (Ag°). This effect is called
eletrochemireduction (ECR). In this sense, PL emission pro-
files are very sensitive to structural changes and serve as a
powerful detector to monitor the ECR process. Therefore, the
silver filaments do not form a defined interface. There is
rather a combination of Ag° and VMoO , Od x4 Ag[ ] ⎡⎣ ⎤⎦⋅ clusters.
The ECR increases with time, creating clusters of silver and
silver vacancies. These clusters interact, giving rise to nano-
wires that emerge at the surface of the crystal. Simultaneously
there is a large density of V OxAg

⎡⎣ ⎤⎦¢ and holes (h•), which are
confined within the clusters that result in the formation of new
intermediate states.

4. Conclusions

β-Ag2MoO4 samples with different morphologies were syn-
thesized by a co-precipitation method using ethanol as the
solvent. β-Ag2MoO4 was characterized by XRD with Riet-
veld refinement, MR spectroscopy, and FE-SEM. Optical
properties were investigated by UV–vis and PL spectroscopy
at room temperature. First-principles calculations were per-
formed to complement the experimental data. The main
conclusions from this study are summarized in the following
seven points.

1. The theoretical and experimental values for structural
parameters and Raman vibrational frequencies are in
good agreement.

2. The reversible Ag formation process during FE-SEM
imaging were rationalized based on the formation of an

Figure 7. UV–visible diffuse reflectance spectrum of β-Ag2MoO4.

Figure 8. Room temperature PL spectra of the β-Ag2MoO4

microcrystals, excited by the 350.7 nm line of a krypton ion laser
before (black) and after irradiation (blue) by an accelerated
electron beam.

8

Sci. Technol. Adv. Mater. 16 (2015) 065002 M T Fabbro et al


n–p semiconductor, maintaining the structural and
chemical integrity of the samples.

3. First-principles calculations were done to investigate
the mechanism of the morphological transformation of
surface chemistry-controlled β-Ag2MoO4 microcrys-
tals. FE-SEM images also show faceted morphologies
similar to the morphologies calculated by Wulff
construction.

4. The combined experimental and theoretical results may
provide new insights into the crystal’s plane-dependent
performance.

5. The theoretical and experimental values for the band
gap are in good agreement. The presence of inter-
mediary energy levels within the optical band gap can
be associated with a structural disorder of the
tetrahedral [MoO4] and octahedral [AgO6] clusters,
which are the building blocks of β-Ag2MoO4. Struc-
tural disorder enhances the presence of electron–hole
pairs.

6. The PL emissions of the as-synthesized and irradiated
β-Ag2MoO4 microcrystals depend critically on the
structural disorder of tetrahedral [MoO4] and octahedral
[AgO6] clusters.

7. These findings will be useful for designing and
constructing novel nanostructures with specifically
exposed crystal planes for surface related applications
such as gas sensors, optical devices, and catalysts.

Acknowledgments

The authors acknowledge the financial support of the fol-
lowing agencies: Conselho Nacional de Desenvolvimento
Científico e Tecnológico (304531/2013-8), Fundação de
Amparo à Pesquisa do Estado de São Paulo (2013/07296-2)
and CNPq (304531/2013-8). Generalitat Valenciana for
PrometeoII/2014/022 and ACOMP/2014/270, and Minis-
terio de Economia y Competitividad, project CTQ2012-
36253-C03-02 and ACOMP/2014/270.

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	1. Introduction
	2. Experimental details
	2.1. Synthesis of &#x003B2;-Ag2MoO4
	2.2. Characterization
	2.3. Computational methods

	3. Results and discussion
	4. Conclusions
	Acknowledgments
	References