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Effective Doping of Rare-earth Ions in Silica Gel:

A Novel Approach to Design Active Electronic

Devices

D. Haranath∗, Savvi Mishra, Amish G. Joshi, Sonal Sahai, Virendra Shanker

(Received 21 June 2011; accepted 4 August 2011; published online 31 August 2011.)

Abstract: Eu3+ luminescence spectroscopy has been used to investigate the effective doping of alkoxide-based
silica (SiO2) gels using a novel pressure-assisted sol-gel method. Our results pertaining to intense photolumi-

nescence (PL) from gel nanospheres can be directly attributed to the high specific surface area and remarkable

decrease in unsaturated dangling bonds of the gel nanospheres under pressure. An increased dehydroxylation in

an autoclave resulted in enhanced red (∼611 nm) PL emission from europium and is almost ten times brighter

than the SiO2 gel made at atmospheric pressure and ∼50℃ using conventional Stöber-Fink-Bohn process. The

presented results are entirely different from those reported earlier for SiO2:Eu
3+ gel nanospheres and the origin

of the enhanced PL have been discussed thoroughly.

Keywords: Luminescence; Nanophosphor; Short-range order; Electron microscopy

Citation: D. Haranath, Savvi Mishra, Amish G. Joshi, Sonal Sahai and Virendra Shanker, “Effective Dop-
ing of Rare-earth Ions in Silica Gel: A Novel Approach to Design Active Electronic Devices”, Nano-Micro Lett.

3 (3), 141-145 (2011). http://dx.doi.org/10.3786/nml.v3i3.p141-145

Introduction

Luminescent materials have been utilized widely in
applications involving lighting to sensing [1]. The pho-
toluminescence (PL) properties of silica have also been
an important topic of research for a long time, but the
difficulty in the incorporation of rare-earth (RE) ions
attached covalently to the silica (SiO2) network is still
considered a great challenge. The weak PL bands with
peak energies ∼1.9-4.3 eV for both bulk and thin films
of SiO2 have been reported [2]. The sol-gel method
has been used to prepare nanomaterials in the form of
powders, films, fibers and monoliths that are based on
various metal alkoxides [3]. It has been observed that
monodisperse silica nanospheres formed by hydrolysis
and condensation of alkoxides using Stöber-Fink-Bohn
(SFB) process gives negligible luminescence. Incorpora-
tion of inorganic luminescent centres into SFB spheres
has been demonstrated by some research groups [4] us-

ing RE ions, quantum dots and organic flurophores,
but the procedure requires multiple processing steps
and use of expensive and toxic ligands. During the
last few years, there have been few reports [5-10] on
intense PL emission in the visible region of the electro-
magnetic spectrum, by several different nanostructured
materials that are highly disordered such as nanowires,
porous silicon, silica-based mesoporous fractals, ferro-
electrics with ABO3 type and AWO4-type perovskite
structures (A=Ca, Ba, Sr); and many more. The ori-
gin of this type of luminescence is always attributed to
unsaturated chemical bonds in these nanostructures. In
case of ferroelectrics, as their energy band gaps are lo-
cated ∼3-4 eV, the PL emission in the visible region
was correlated to their highly disordered states and
many localized electronic levels present within the op-
tical gap, causing luminescence [6]. Since SiO2 gel is
a well-studied system [11] having visible transparency
and significant absorption peak lying in the ultra-violet

National Physical Laboratory, Council of Scientific and Industrial Research, Dr K S Krishnan Road, New Delhi, 110 012, India
*Corresponding author. E-mail: haranath@nplindia.org

Nano-Micro Lett. 3 (3), 141-145 (2011)/ http://dx.doi.org/10.3786/nml.v3i3.p141-145



Nano-Micro Lett. 3 (3), 141-145 (2011)/ http://dx.doi.org/10.3786/nml.v3i3.p141-145

region, the introduction of dopant ions act as a pertur-
bation to the well-studied system leading to interesting
optical properties. The RE ions are used as probes in
the sol-gel method due to their sensibility to change
with the surrounding matrix probing the local struc-
ture [12,13]. Thus derived SiO2 and organically modi-
fied matrix composites could be the main precursor to
prepare many RE based smart optical materials [14].

In this paper, we propose a novel methodology to pre-
pare alkoxide-based silica gel nanospheres doped with
Eu3+ ions that show enhanced PL brightness, uniform
size distribution and improved quantum efficiencies.
This is a process by which highly disordered but doped
silica gels could be effectively made useful for practi-
cal applications involving luminescence. It has already
been evidenced that high pressure and temperature
leads to more closely packed structures [14]. The pre-
sented analogy is unique and could be extended to many
crystalline and non-crystalline phosphor based systems
to design new family of sol-gel based nanocomposites,
having a wide variety of applications in lasers, chemi-
cal sensing, waveguides, bioanalytical assays, blood flow
monitoring and effectively harvesting the solar energy
for improving the solar cell efficiency.

Experimental

Silica nanospheres were prepared with its surface
modified by sol-gel method and studied through the
incorporation of Europium (III) ions in two differ-
ent ways. The europium nitrate (EuNO3) was mixed
with sufficient ethanol (EtOH) and this was added
to tetraethylorthosilicate (TEOS). The stoichiometric
amount of water, which is essential to carryout hydrol-
ysis reaction, was added drop wise under continuous
stirring. Prior to gelling the low and high resolution
transmission electron microscopy (TEM) images of col-
loidal silica solution (also called silica sol) were taken
at a magnification of 125 and 400 kX, respectively as
shown in Fig. 1. The silica particles observed are al-
most spherical with an average cluster size of ∼5 nm.
The schematic of the SiO2 gel network [11] and the
probable description of pore and particle sizes were il-
lustrated in Fig. 1(c). The silica sol was then divided
in two halves for a systematic experimentation. For
the first experiment, one of the solution containing
vials was allowed to gel at atmospheric pressure (1 bar)
and a controlled oven temperature of ∼50℃ (±0.1℃).
In the second case the solution was kept in an auto-
clave, subjected to high temperature and pressure at
∼150℃ and 120 bars, respectively for about 5 hours.
It was intentional to keep the processing time same for
both the cases. Once the wet silica gels were obtained,
SiO2:Eu

3+ nanospheric powders were obtained by dry-
ing the gels overnight in vacuum oven at ∼55℃. All

the samples were studied using morphology, composi-
tion evaluation, UV-VIS absorption and luminescence
spectroscopy techniques.

Fig. 1 (a) TEM and (b) HRTEM images of silica sol
particles aged for 5 hours at room temperature, 25℃; (c)
schematic illustration of gel network structure showing the
pore and particle sizes (Courtesy from ref. [11]).

For TEM observations, the samples were redispersed
in methanol by ultrasonic treatment and dropped on
carbon-copper grids. TEM images were collected using
a Tecnai G2 F30 S-Twin (FEI; Super Twin lens with
CS=1.2 mm) instrument operating at an accelerating
voltage at 300 kV, having a point resolution of 0.2 nm
and lattice resolution of 0.14 nm) with an EDAX at-
tachment. Program Digital Micrograph (Gatan) was
used for image processing. Scanning electron mi-
croscopy was performed using Zeiss EVO MA10.

X-ray diffraction (XRD) of the powder sample was
performed using Bruker D-8 advance powder X-ray
diffractometer with CuKα radiation operated at 35 kV
and 30 mA. All the samples showed the amorphous na-
ture.

X-ray Photoelectron Spectroscopy (XPS) studies
have been carried out using a Perkin Elmer 1257 model,
at 300 K with a non-monochromatic AlKα line at
1486.6 eV. During photoemission studies, small spec-
imen charging was observed which was later calibrated
by assigning the C 1s signal at 285 eV.

The room temperature photoluminescence (PL)
spectra were recorded using an Edinburgh Lumines-
cence Spectrometer (Model F900) equipped with a
xenon lamp. The excitation and emission spectra were
recorded in the fluorescence mode over the range of 300-
700 nm.

Results and discussion

It is important to highlight the pressure-assisted hy-
drothermal/solvothermal process for the preparation of
variety of nanoparticles of oxides and chalcogenide ma-
terials. The solution based nanomaterial synthesis of-
ten involves reactions carried out near the boiling point

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Nano-Micro Lett. 3 (3), 141-145 (2011)/ http://dx.doi.org/10.3786/nml.v3i3.p141-145

of the solvent. This may lead to poor quality of the
nanomaterial and less yield. In order to obtain crys-
talline, monodisperse nanoparticles, it is always neces-
sary to work at relatively high temperatures and pres-
sures. Use of acid digestion bomb (commonly called
Autoclave) is the best alternative to work with. De-
tails of the autoclave synthesis of intrinsic silica gels
have been reported extensively by Haranath et al. since
1996. In the current case, rare-earth (RE) doped sil-
ica gels were made under pressure at elevated temper-
atures as described in latter sections. This method of
preparation, which is based on pressure-assisted sol-gel
method, has compatibility in modifying the coordinat-
ing environment of RE (dopant) ions so that the loss
in energy of the excited states via. non-radiative mech-
anism is minimum. The x-ray diffraction pattern of
Eu3+ doped SiO2 gel powder depicted in Fig. 2 clearly
shows a broad hump at ∼23◦ indicating the complete
amorphous nature of the SiO2 nanospheres. SEM im-
ages shown in inset of Fig. 2 illustrate the quality of
the nanospheres with respect to their size and shapes.
In other words, the conventional sol-gel method leads
to a broad distribution of particle sizes in the range
10-50 nm (Fig. 2(a)) whereas the pressure assisted sol-
gel method has resulted in almost uniform particles
(∼15 nm) with spherical shape (Fig. 2(b)). This es-
tablishes the fact that high pressure and temperature
leads to more closely packed structures and increased
charge transfer energies that are efficiently transferred
to the Eu3+ ions. The TEM and scanning electron mi-
crographs (SEM) reveal that the optimization of exper-
imental and processing parameters allow microscopic
preparation of uniform silica nanospheres.

Fig. 2 X-ray diffraction (XRD) pattern of SiO2 gel pow-
der at room temperature (∼25℃) indicating the amorphous
nature of the gel under study. The insets shows the SEM
micrographs of SiO2:Eu gels prepared at (a) atmosphere
pressure (1 bar) and 50℃; and (b) 120 bars and 150℃, re-
spectively.

Moreover, the chemical composition and the relevant
surface chemistry of SiO2:Eu

3+ nanospheres were an-
alyzed using x-ray photoelectron spectroscopy (XPS).
The XPS observations revealed three peaks correspond-
ing to the elements Si, O and Eu, respectively. Pass
energy for general survey scan and core level spectra
was kept at 143.05 and 71.55 eV respectively. Sur-
face contamination was removed by Ar ions with 4 keV
beam energy. Sputtering performed in raster mode
with emission current of 20 mA for 5min at base pres-
sure 4.5×10−7 torr. Figure 3 shows the survey spectra
of SiO2:Eu

3+ nanospheres acquired in the range of 0-
1200 eV. During photoemission studies, small specimen
charging was observed, which was later calibrated by
assigning the C 1s signal at 285 eV. Survey spectra af-
ter sputtering show sharp peaks of C 1s (285 eV), O 1s
(537 eV). Two clear distinct state of Eu were observed
at 1171 and 1141 eV for Eu 3d3/2 and 3d5/2 respec-
tively. The separation between two states is because of
spin-orbit splitting. Inset of Fig. 3 shows the Si(2p) core
level spectra. The value of elemental Si(2p) is 99.15 eV,
since, appearance of Si(2p) at 104 eV confirms the Si
exist in SiO2 state. The binding energies of various
elements match very well with the peaks observed for
standard SiO2:Eu

3+. The presence of C is due to the air
atmosphere and the organics used for the preparation
of Eu3+ doped in silica matrix.

Fig. 3 XPS survey scan spectra of sputtered and nanopar-
ticles of SiO2:Eu

3+ recorded with photon energy of AlKα
(hν=1486.6 eV), Inset shows the Si(2p) core level.

Figure 4 shows the UV-VIS absorbance spectra of
Eu3+ doped SiO2 gel samples prepared at 50℃, 1 bar;
and 150℃, 120 bars, respectively. The spectra are the
strong indicative two findings. One is being the reduc-
tion of surface states of the gel nanospheres and other
being the maintenance of almost the same size for the
gel particles even after subjecting to high pressure and
temperature cycles. The same has been evidenced by
the absorption peaks indicated in the inset of Fig. 4.

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Nano-Micro Lett. 3 (3), 141-145 (2011)/ http://dx.doi.org/10.3786/nml.v3i3.p141-145

2.5

2.0

1.5

1.0
330 336 342

nm
A

b
s.

332 nm

334 nm

3

2

1

0
325 350 375 400 450425

Wavelength (nm)

A
b
so

rb
a
n
ce

 (
%

)
50°C, 1 bar

150°C, 120 bar

Fig. 4 Absorbance spectra of Eu doped-SiO2 samples pre-
pared at atmosphere pressure (1 bar) and 120 bars and
150℃, respectively. Inset shows the expanded version of
the absorption peaks.

The observation of weak photoluminescence (PL) at
room temperature in various amorphous silica nanos-
tructures has been reported in the literature [15-18] but
not sufficient to use for any fundamental or potential
application. Figure 5 shows the PL excitation (PLE)
and PL spectra from Eu3+ doped and baked SiO2 gel
in an autoclave respectively. It is known that the sur-
face states and unsaturated dangling bonds play a crit-
ical role in determining the overall PL characteristics
of nanostructures. If the silica gel is prepared with a
rare-earth dopant (Eu3+ in the present case), the PL
is dominated by the radiative transitions (5D0 →

7Fj,
j=0-3) from the levels of Eu3+ ions [19] as shown in the
inset of Fig. 5. The emission spectra of Eu3+ doped
SiO2 gels prepared at 50℃, 1 bar; and 150℃, 120 bars,
were shown in Fig. 5. For recording the PL spectra
the excitation energy has been fixed as 395 nm which
is the 5L6 level of Eu

3+ ligand band. The PL from the
Eu3+ doped SiO2 gel prepared at atmospheric pressure
(1 bar) and 50℃ was found to be weak and inefficient
for any practical application, whereas the PL intensity
from the gel turn out to be much stronger (>10 times)
when the sol was gelled under high temperature (150℃)
and pressures (120 bars) inside an autoclave. Moreover,
the PLE spectrum also became narrower under auto-
clave treated gel sample, which indicate that there is
a remarkable decrease in unsatisfied chemical bonds in
the final product. The most intense line at ∼611 nm
corresponds to the hypersensitive transition between
the 5D0 and

7F2 level of the Eu
3+ ions and will be rel-

atively strong if the surrounding symmetry is low. In
the sense, it is generally admitted that the ratio of the
emission intensities R=I(5D0 →

7F2)/I(
5D0 →

7F1) is
an asymmetry parameter for the Eu3+ sites and a mea-
sure of the extent of its interaction with the surround-
ing ligands [20]. This indicates that the environment
of the Eu3+ is dictated by the nano-SiO2 host under

high pressure and temperature conditions. In addition,
broad excitation peaks observed between 250-500 nm
became distinct and sharp for the sample made under
high pressures. The sharp peaks in the PL and PLE
spectra of SiO2:Eu nanospheres may be due to quantum
confinement effects related to size restrictions. A com-
bination of unique features of high surface-to-volume
ratios, monodispersion and strong photoluminescence
suggest that these silica nanospheres will find many in-
teresting applications in semiconductor photophysics,
inorganic light emitting diodes, solar cells, environmen-
tal remediations and optoelectronic devices.

150°C, 120 bar

50°C, 1 bar

20

15

10

5

0

E
n
er

g
y
, 
1
0

3
 c

m
_

1 Energy levels of Eu3+

5DJ

5D0
_7F2

5D0
_7F1

5D0
_7F0 5D0

_7F3

λex=395 nmλem=611 nm

X10
PLE

30

20

10

0

250 500 625
Wavelength (nm)
375

X10

7FJ

J=2
J=0

J=6

J=0

PL
In

te
n
si

ty
 (

a
rb

.u
n
it

s)

Fig. 5 PLE and PL spectra of SiO2:Eu gels made at (a)
50℃, 1 bar and (b) 120 bars and 150℃, respectively. Inset
shows the mechanism of Eu3+ transitions.

Conclusions

In conclusion, we have demonstrated a mechanism by
which photoluminescence enhancement in SiO2:Eu

3+

phosphor nanospheres could be successfully achieved
using pressure-assisted sol-gel method. The observed
red emission is from typical 5D0−

7F2 transition of
Eu3+ and is found to be almost ten times brighter
than the gel made at atmospheric pressure (1 bar) and
∼50℃ using Stöber-Fink-Bohn process. This kind of
process is highly desirable for many crystalline and non-
crystalline materials system wherein the doping is inap-
propriate. This may lead to design many fundamental
and novel optoelectronic applications.

Acknowledgments

The authors (DH, SM and SS) gratefully acknowl-
edge the Department of Science and Technology (DST),
Ministry of Science and Technology, Government of In-
dia for their respective fellowships under various spon-
sored projects to carryout the work.

144



Nano-Micro Lett. 3 (3), 141-145 (2011)/ http://dx.doi.org/10.3786/nml.v3i3.p141-145

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	Introduction
	Experimental
	Results and discussion
	Conclusions
	Acknowledgments
	References