Vitalii Boiko1, Maria Luisa Saladino2, Francesco Armetta2, Federica Ursi2, Marta Markowska1, Karina Grzeszkiewicz1, Cecilia Mortalò3, Cristina Leonelli4, Dariusz Hreniak1. 1. Institute of Low Temperature and Structure Research, Polish Academy of Sciences, ul. Okólna 2, PL-50-422 Wrocław, Poland. 2. Department of Biological, Chemical and Pharmaceutical Sciences and Technologies (STEBICEF) and INSTM UdR - Palermo, University of Palermo, Viale delle Scienze, Bld. 17, IT-90128 Palermo, Italy. 3. Institute of Condensed Matter Chemistry and Energy Technologies (ICMATE), National Research Council of Italy, Corso Stati Uniti, 4, IT-35127 Padova, Italy. 4. Department of Engineering "Enzo Ferrari", University of Modena and Reggio Emilia, Via Pietro Vivarelli, 10, IT-41125 Modena, Italy.
Abstract
A new approach for the synthesis of Y3Al2Ga3O12 (YAGG) nanophosphors allowing the preparation of crystallites with sizes starting from 45 nm is presented. The controllability of the energy and trap density of the resulting material samples by annealing temperature was confirmed by thermoluminescence (TL) measurements. It has been shown that the annealing of samples at temperatures up to 1300 °C does not cause any substantial growth of crystallites, still remaining below 100 nm, but leads to changes in the activation energy of the persistent luminescence (PersL) process. On the other hand, annealing above 1400 °C results in grain growth on the submicron scale, which was confirmed by X-ray powder diffraction (XRPD) and electron transmission microscopy (TEM) measurements. In addition, with an increase in the molar ratio of urea to the total amount of metals used (R), qualitative changes are observed in the PersL process occurring from the excited states of Cr3+ and Pr3+ ions. This proves the influence of the synthesis process, in particular of the metal complexation at its initial stage, on the final structure ordering in the annealed materials. These observations are linked to previously reported defects in the YAGG structure, leading to PersL.
A new approach for the synthesis of Y3Al2Ga3O12 (YAGG) nanophosphors allowing the preparation of crystallites with sizes starting from 45 nm is presented. The controllability of the energy and trap density of the resulting material samples by annealing temperature was confirmed by thermoluminescence (TL) measurements. It has been shown that the annealing of samples at temperatures up to 1300 °C does not cause any substantial growth of crystallites, still remaining below 100 nm, but leads to changes in the activation energy of the persistent luminescence (PersL) process. On the other hand, annealing above 1400 °C results in grain growth on the submicron scale, which was confirmed by X-ray powder diffraction (XRPD) and electron transmission microscopy (TEM) measurements. In addition, with an increase in the molar ratio of urea to the total amount of metals used (R), qualitative changes are observed in the PersL process occurring from the excited states of Cr3+ and Pr3+ ions. This proves the influence of the synthesis process, in particular of the metal complexation at its initial stage, on the final structure ordering in the annealed materials. These observations are linked to previously reported defects in the YAGG structure, leading to PersL.
In recent years, great interest in nanomaterials
has been observed
due to their enormous potential in fundamental studies and the technological
field. In this broad class of nanomaterials, an important role is
played by luminescent nanoparticles and, in particular, by those activated
by trivalent lanthanide ions, due to their promising applications
in the fields of bioimaging, lighting, optical nanothermometry, and
solar concentrators.[1−3]Many research groups around the world are strongly
motivated to
develop not only new hosts for such phosphors but also new synthetic
routes to obtain them in the well-defined nanomaterial form.[4−11] It is well known that the physical properties of crystalline materials
are highly dependent on the host material, phase purity, grain size
distribution, and crystalline homogeneity. Over the years, mixed oxide
systems have been of particular interest due to their stability and
design potential for a wide range of properties, such as energy gaps,
mainly through ion replacement. In the next step, of course, it is
necessary to provide specific properties and the final form of the
material, respectively, by appropriate doping and selection and optimization
of their synthesis method.[12−14]One of the most promising
materials intensively investigated in
recent years in various research centers is yttrium aluminum gallium
garnet (YAGG, Y3Al2Ga3O12), which exhibits specific luminescent properties after appropriate
doping.[15,16] The crystal structure of YAGG is shown in Figure . The structure belongs
to the space group Ia3̅d. The general chemical formula of an
oxide garnet is X3A2B3O12, where X refers to a dodecahedral site, A to an octahedral site,
and B to a tetrahedral site. The garnet structure has many edges shared
between adjacent polyhedra; each tetrahedron and octahedron share
edges with two or six dodecahedra, while each dodecahedron divides
edges with two tetrahedra, four octahedra, and four other dodecahedra;
finally, tetrahedra and octahedra are connected to each other from
all angles.[17] Gilleo and Geller reported
that aluminum and gallium prefer tetrahedral sites,[17] but the reasons are different. Aluminum is located in a
four-coordinate site due to the small radius, while the preference
of gallium to the tetrahedral site is explained by the nature of Ga3+ rather than by the effect of the radius. In fact, the ions
with electronic configuration d10 tend to settle according
to sp3 hybridization, preferring the tetrahedral site.[18] YAGG doped singly or codoped with Cr3+ is known as one of the new so-called persistent phosphors, which
exhibit continuous luminescence for a long duration (minutes, hours,
or days) after ceasing the excitation source.[19−22] Most recent studies are devoted
to nanophosphors emitting in the red and near-infrared (NIR) regions.[23−25] Although YAGG with such properties could be obtained by its codoping
with Cr3+ and other trivalent ions, the intensity and duration
of persistent luminescence (PersL) in the red region cannot compete
with green and blue ones.[19] PersL in the
red region can be used in biomarkers for in vivo imaging, temperature
sensing, and security marks in bonds and banknotes.[9,26,27] Polycrystalline YAGG codoped with Cr3+ and Ce3+ (YAGG:Ce3+,Cr3+) has been intensively studied by the Tanabe group.[19,21,28] The introduction of Cr3+ to YAGG:Ce3+ was proposed for obtaining long PersL of
Ce3+ at room temperature. Furthermore, YAGG nanopowders
can also be used as a starting material for the production of high-quality
optical ceramics with PersL properties, which can be used, for example,
in optical storage applications.[29]
Figure 1
Y3Al2Ga3O12 structure.
Y3Al2Ga3O12 structure.The addition of a third dopant to this system allows
obtaining
new red and near-infrared phosphors, which are of current interest,[30−32] preferably broad bands excited by blue LEDs. Some doping ions such
as Nd3+, Pr3+, and Yb3+ have been
successfully used to obtain emissions through efficient energy transfer
(ET) from Ce3+ and Cr3+.[33,34] In previous works, optimal dopant ratios were already investigated
for both spectral properties[35] and PersL
effects.[36] Special attention has been given
to the investigation of the mechanism involved in persistent luminescence,[37−39] which is correlated to the size and aggregation of particle or lattice
defects. Recently, we reported particle size-related limitations of
persistent phosphors based on the nanocrystalline YAGG obtained by
the Pechini method[30] and coprecipitation
method.[40] It was found that although at
higher annealing temperatures, the properties of the resulting phosphors
do not change significantly, the smaller crystallites obtained exhibit
more surface defects that can lead to PersL quenching. Therefore,
the goal of this study was to investigate the controllability of the
energy and trap density of Y3Al2Ga3O12:Ce3+,Cr3+, Pr3+ while
better maintaining the nanometric size and uniform morphology of particles.
To this aim, the urea glass route (UGR) method was chosen for their
synthesis, followed by annealing at several temperatures in the range
of 900–1400 °C. This one-pot, green, and time-saving synthetic
method has already been developed for the preparation of nitride nanoparticles[41] and Ce:YAG nanopowders[42] and allows the preparation of materials with high control of powder
purity, crystalline structure, and morphology. According to the UGR
procedure, metallic salts are solubilized in ethanol, and after the
addition of urea, they form a so-called gel-like phase. Urea in ethanol
can form complexes with many metals, usually through the carbonyl
group or, in the case of more soft metals, with the nitrogen of the
amino group. The gel-like phase is the result of the ability of urea
to form a polymeric-like organization, which is able to accommodate
the nuclei that form during the subsequent heat treatment. Thanks
to the formation of an intermediate “gel-/glass-like”
material, the primary nanoparticles are stabilized during the heat
treatment.
Experimental Part
Materials
Urea (Acros Organics, 98%), ethanol (Aldrich,
99.98%), Y(NO3)3·6H2O (Aldrich,
99.8%), Al(NO3)3·9H2O (Aldrich,
98%), Ga(NO3)3·9H2O (Aldrich,
99.9%), Pr6O11 (Sigma-Aldrich, 99.99%), Ce(NO3)3·6H2O (Aldrich, 99.99%), Cr(NO3)3·9H2O (Fluka 97%) were used in
the paper.
Preparation of Nanocrystals
YAGG codoped with Ce3+, Cr3+, and Pr3+ nanocrystals were
synthesized following this procedure. A solution containing Al(NO3)3·9H2O, Y(NO3)3·6H2O, Ga(NO3)3·9H2O, Pr6O11, Ce(NO3)3·6H2O, and Cr(NO3)3·9H2O salts in ethanol was prepared in a (Y + Ce + Pr)/(Al + Cr)/Ga
molar ratio of 3:2:3 by setting the concentration of Y(NO3)3 as 0.12 mol L–1 to obtain the following
formula Y2.9865Ce0.006Pr0.0075Al1.9875Cr0.0125Ga3O12. An appropriate
amount of urea was added to the ethanolic solution with metals to
obtain urea/metal molar ratios, R, of 0, 0.25, 0.5,
1, and 2. The obtained systems were subjected to agitation in an ultrasonic
bath for 20 min to obtain homogeneous and transparent dispersions
identifiable with a gel-like system, as can be observed in Figure .
Figure 2
Systems obtained by the
urea glass route with urea/metal molar
ratios, R, of 0, 0.25, 0.5, 1, and 2 (left). Image
of the Ce3+-, Cr3+-, Pr3+-codoped
powder (right).
Systems obtained by the
urea glass route with urea/metal molar
ratios, R, of 0, 0.25, 0.5, 1, and 2 (left). Image
of the Ce3+-, Cr3+-, Pr3+-codoped
powder (right).For R > 1, the formation of
a white dispersion
was observed, which separates within a few hours. White dispersion
may be associated with the decomposition of urea; for this reason,
for the correct purposes of the present paper, only systems with R < 1 are suitable. This study was thus performed by
calcining only two systems at R = 0.25 and 1 for
1 h at temperatures of 900, 1000, 1100, 1200, 1300, and 1400 °C.
The system at R = 0.5 was not treated and deeply
studied because of a few differences in behavior observed between R = 0.25 and 1 (see the Results and Discussion section). After the heat treatment, the powders appear green (Figure ).
Characterization Techniques
X-ray powder diffraction (XRPD)
XRPD patterns were
acquired by a Philips PW 1050/39 diffractometer in the Bragg–Brentano
geometry using Ni-filtered Cu Kα radiation (λ = 1.54056
Å) in the 2θ range of 5–90° with a step of
0.05° and a time for the step of 5 s. The X-ray generator worked
at a power of 40 kV and 30 mA, and the resolution of the instrument
(divergent and antiscatter slits of 0.5°) was determined using
R-SiO2 and R-Al2O3 standards free
from the effect of reduced crystallite size and lattice defects. The
phase identification has been performed using X′pert HighScore
Software. To obtain information about phase composition, cell parameters,
and the crystalline size of the phases, XRPD patterns were analyzed
according to the Rietveld method using MAUD software.[43,44].
Transmission Electron Microscopy (TEM)
TEM micrographs
of YAGG:Ce3+,Cr3+,Pr3+ nanophosphors
annealed at 900, 1000, and 1100 °C were acquired using a JEM-2100
(JEOL, Japan) microscope operating at an accelerating voltage of 200
kV. Each powder was homogeneously dispersed in isopropanol by sonication
for 2 min. A drop of the suspension was deposited on a lacey carbon
grid of 300 mesh, and after complete solvent evaporation, the grid
was introduced into the TEM chamber for analysis. TEM micrographs
of YAGG:Ce3+,Cr3+,Pr3+ nanophosphors
annealed at 1200 and 1400 °C were acquired using a last-generation
high-resolution scanning/transmission electron (S/TEM) microscope
(Thermo Scientific Talos F200S) equipped with energy-dispersive X-ray
spectroscopy (EDS) and operating at an accelerating voltage of 200
kV. Samples were homogeneously dispersed in bidistilled water (Millipore)
by sonication for 10–15 min. A drop of each suspension was
deposited on a copper grid of 200 mesh coated with a transparent polymer
(Formvar/carbon) and then dried. Subsequently, specimens were carbonated
(carbon coater: Balzers CED-010) for TEM investigations.
Photoluminescence Emission (PL) and Excitation (PLE) Spectra
Photoluminescence emission (PL) and excitation (PLE) spectra as
well as photoluminescence lifetime (microsecond range) were measured
using an FLS980 Fluorescence Spectrometer from Edinburgh Instruments.
As an excitation source, a 450 W xenon lamp (for PL and PLE) and a
150 W xenon pulse lamp (for a lifetime) were used. An R928P side window
photomultiplier tube from Hamamatsu was used as a detector. Both the
excitation and emission 300 mm focal length monochromators were in
the Czerny Turner configuration. The excitation arm was supplied with
a holographic grating of 1800 lines mm–1, blazed
at 300 nm, while the emission arm was supplied with ruled grating,
1800 lines mm–1 blazed at 500 nm. The scanning range
was from 250 to 680 nm for PLE spectra and from 460 to 820 nm for
PL spectra. For external quantum yield (QY) measurements, an integrating
sphere (SM4 from Edinburg Instruments) with a diameter of 30 cm was
additionally used. In this case, the signal intensity on the sample
was about 60 mW.The photoluminescence lifetime (nanosecond
range) was carried out using a femtosecond laser setup composed of
a Coherent Libra-S all-in-one ultrafast oscillator and a regenerative
amplifier laser system, with a pulse duration of less than 100 fs
at a 1 kHz repetition rate, a Coherent OPerA-Solo optical parametric
amplifier, and a Hamamatsu C5677 streak camera with a time resolution
of 14 ps.
Thermoluminescence (TL)
Thermoluminescence (TL) curves
were measured with a lexsygresearch TL/OSL reader (Freiberg Instruments
GmbH, Freiberg, Germany). The signal was collected with an R13456
PMT (Hamamatsu Photonics) monitoring the global emission from the
whole spectral response (from 185 to 980 nm) with an integration (channel)
time of 0.1 s. A blue laser diode PL450B (λmax =
450 nm, FWHM = 2 nm, power 1 mW cm–2) by Osram was
used as an irradiation source. To learn more about the properties
of the traps contributing to the main thermoluminescent peaks, the Tmax–Tstop (partial cleaning) experiment proposed by McKeever was performed.[45] The method involved the following procedure:
the sample was irradiated at room temperature, partially heating the
sample to temperature Tstop, cooling to
room temperature, and reheating to record (heating rate 0.5 °C
s–1) all of the remaining glow curves. Positions
of the first maximum Tmax in the glow
curve versus Tstop were plotted in the Tstop range between 30 and 150 °C with a
step of 10 °C to cover completely the glow curve. These studies
were complemented by an initial rise analysis.[46] All modules were controlled by LexStudio 2, and the obtained
data were processed with Origin software.
Results and Discussion
Structure and Morphology
The structure of codoped YAGG
samples was studied by XRPD. The XRPD patterns of the samples with R = 0.25 and 1 treated at various temperatures are shown
in Figure .
Figure 3
XRD patterns
of the YAGG:Ce3+,Cr3+,Pr3+ powder
obtained with the UGR method with R = 0.25 and 1
calcined in the range of 900–1400 °C. The
reference pattern (PDF#75-0555) is reported at the bottom.
XRD patterns
of the YAGG:Ce3+,Cr3+,Pr3+ powder
obtained with the UGR method with R = 0.25 and 1
calcined in the range of 900–1400 °C. The
reference pattern (PDF#75-0555) is reported at the bottom.All XRPD patterns are constituted by a single garnet
phase[47,48] and are in good agreement with that of YAGG.
The transformation
from amorphous to the stable phase garnet occurs completely with heat
treatment at a relatively low temperature (900 °C). No additional
diffraction peaks were observed, thus indicating the absence of any
secondary phases. All diffraction peaks became narrower with increasing
temperature, which indicates the higher crystallinity of the powder.
This behavior could be attributed to the particle size increase or
the strain effect, which could also contribute to the peak broadening
of the XRPD patterns. The diffraction patterns were simulated by the
Rietveld refinement analysis. For each sample, the agreement between
the experiment and the model was evaluated by Rb (4–6%) and the curve of residues. The cell parameter a and the size of crystallites D obtained
for each sample are given in Figure .
Figure 4
Cell parameter, a, and crystallite size, D, obtained for YAGG:Ce3+,Cr3+,Pr3+ with R = 0.25 and 1 and calcined for 1
h in a temperature range of 900–1400 °C. Dashed lines
are a guide for eyes only.
Cell parameter, a, and crystallite size, D, obtained for YAGG:Ce3+,Cr3+,Pr3+ with R = 0.25 and 1 and calcined for 1
h in a temperature range of 900–1400 °C. Dashed lines
are a guide for eyes only.The obtained values of the cell parameter a are
in agreement with the hypothesis of Al3+ replacement with
Ga3+, in agreement with Vegard′s law, and are due
to the difference in ionic radii (Ga(III) = 0.76 Å and Al(III)
= 0.53 Å).[48] The cell parameter of
undoped YAG is 12.008 Å, while the ones of yttrium gallium garnet
(YGG) when all aluminum ions are substituted with gallium is 12.270
Å.[44] Ga3+ ionmainly occupies
24d lattice sites and Al3+ occupies 16a lattice sites.[47,48] The ratio between the octahedral (16a) and tetrahedral (24d) is
equal to 2:3. Ce3+ and Pr3+ ions partially substitute
Y3+ ions, while Cr3+ ions replace aluminum ions
in the octahedral position.[49]As
the analysis of the diffraction patterns of the two series showed
no significant differences between the cell parameter, a, and the crystallite size, D, subsequent studies
thus focused on the effect of temperature. During the heat treatment,
urea has been decomposed releasing gaseous products that do not interfere
with the formation of the garnet phase but result in possible defects
or in formation of small particles. In both cases, R = 0.25 and 1, the decrease in the cell parameter with increasing
annealing temperature can depend on a homogeneous disorder introduced
into the lattice during the amorphous to crystalline transformation
and on an imperfect local stoichiometry, which causes an increase
in the lattice parameter.On the other hand, the treatment at
a higher temperature allows
the release of this disorder with further densification even if in
both series the microstrain ε was between 1 × 10–5 and 4 × 10–5, without a significant effect
from the temperature. The average crystallite size increases by increasing
the temperature for both series, as already observed.[30,40]Some representative TEM micrographs with different magnifications
of the YAGG:Ce3+, Cr3+, Pr3+ samples
prepared at R = 0.25 and 1 after annealing in the
range of 900–1400 °C are reported in Figure and in Figure S1 with lower magnification. Two different enlargements
have been chosen per sample to evidence primary nanoparticle distribution
(low enlargements) and the details of each particle or aggregate (high
enlargements).
Figure 5
TEM micrographs at different magnifications of YAGG:Ce3+,Cr3+,Pr3+ powders.
TEM micrographs at different magnifications of YAGG:Ce3+,Cr3+,Pr3+ powders.TEM micrographs clearly show that the treatment
at 900 °C
causes the formation of agglomerates made of few YAGG particles not
regular in shape. Particles of smaller size and more uniform in shape
are formed starting from being gel-like at R = 1.
Similar results were obtained for Ce:YAG nanocrystals in a previous
study of some of us, where R = 1 was considered the
best to obtain a more homogeneous material.[42] The annealing process at a higher temperature sharpens the nanoparticles′
edges and evidences their irregular polyhedral shapes for all temperatures.
The particle size increases with the temperature, as well as the crystalline
size evaluated by XRPD data. However, the particle size is a little
bit bigger than the crystalline size, and this can be explained considering
that TEM permits to observe the details of the particles (with a polydispersion),
while the XRPD technique evaluates the material in all volumes, giving
an average of the crystalline size. The effect of R is not so significant in the mean value of particle size. The crystalline
nature of the particles has been evident in collecting the SAED patterns
(reported in Figure S2a). All elements
(Ga, Al, Y, Cr, Ce, Pr) are present in the EDS spectra (Figure S2b), and their ratio corresponds to the
ones of the nominal composition.
Photoluminescence
To correlate the crystal structure
parameters of the samples obtained at different synthesis conditions
with the local structure of the dopant ions, which have a fundamental
influence on their luminescence properties, selective studies by optical
spectroscopy were carried out in the next step. In addition to the
primary mechanism leading to PersL, which is the direct relaxation
of the trapped energy due to irradiation into the luminescent ion,
it is also possible to observe PersL resulting by exploiting in some
cases the more likely energy transfer to the same ion through other
dopants present in the material. Such an extended process to obtain
a PersL signal can be studied in detail by analyzing the energy transfers,
leading to normal photoluminescence occurring along, exactly, the
same pathway. It is, therefore, crucial to gather basic information
about possible energy transfers with the help of the analysis of emission,
excitation, and lifetime spectra of subsequent excited levels involved
in these transfers.The PLE spectra of the samples for R = 0.25 and 1 are presented in Figures and S3. The PLE
spectra were acquired at λem = 520, 606, and 710
nm (respectively for well-known Ce3+, Pr3+,
and Cr3+ emission peaks). All collected spectra show broad
bands centered at 280, 350, and 435 nm, and a series of sharp lines
at ∼450 nm additionally appeared in the PLE spectra of Pr3+ and Cr3+. A detailed analysis of energy transfer
based on PLE spectra for this dopant system was carried out in our
previous work.[40] Briefly, the band centered
at 280 nm is assigned to Pr3+:4f → 5d transition[50] and most likely the overlapping Cr3+:4A2g → 4T1g(4P)
transition.[37] The presence of this band
also in the PLE spectrum of Ce3+ indicates a pronounced
ET from the lowest-lying 4f5d state of Pr3+ to the 5d state
of Ce3+.[51] In the excitation
spectra of Ce3+ emission (520 nm), the two bands centered
at 350 and 435 nm are attributed to the well-known splitting of the
4f → 5d Ce3+ state by the crystal field.[52] In the excitation spectra of both Pr3+ (1D2 → 3H4, λem = 606 nm) and Cr3+ (4T2 → 4A2, λem = 710 nm),
characteristic bands in the blue light range associated with f–f
transitions of Pr3+ were recorded. Additionally, in the
PLE spectrum of Cr3+, a typical 4A2 → 4T2 transition in the red range with
a maximum at 617 nm was found.
Figure 6
Photoluminescence excitation spectra of
the YAGG:Ce3+,Cr3+,Pr3+ powder synthesized
at R = 0.25 (a) and 1 (b) and calcined at 1200 °C.
Photoluminescence excitation spectra of
the YAGG:Ce3+,Cr3+,Pr3+ powder synthesized
at R = 0.25 (a) and 1 (b) and calcined at 1200 °C.The PL spectra acquired upon 350 nm excitation
and presented in Figure S4 show a characteristic
broad band corresponding
to the d–f transition of Ce3+ with a maximum centered
at 512 nm and a sharper band with a maximum at 712 nm (Cr3+:4T2 → 4A2 transition).
In between, less intensive but evident narrow lines are also present
due to indirectly induced f–f transitions of Pr3+:1D2 → 3H4 (606
nm) and 3P0 → 3H6 (634 nm) evident upon 450 nm excitation (Figure ).
Figure 7
Photoluminescence spectra of the YAGG:Ce3+,Cr3+,Pr3+ powder synthesized at R = 0.25
(a) and 1 (b). λexc = 450 nm at RT.
Photoluminescence spectra of the YAGG:Ce3+,Cr3+,Pr3+ powder synthesized at R = 0.25
(a) and 1 (b). λexc = 450 nm at RT.In terms of practical application, the observed
spectral characteristics
and the possibility of obtaining efficient emission from all ions
upon 450 nm excitation (Figure ), which can be generated using commonly available LEDs, are
very advantageous.[53,54] In general, an increase in the
intensity of all bands was noticed as the annealing temperature increased
for both R = 0.25 and 1 samples. This behavior is
a consequence of the fact that the surface-to-volume ratio decreases
together with the decrease of the probability of nonradiative recombination
through the elimination of quenching defects.[55,56] To find out which of the UGR synthesis parameters yields better
results, affecting the final properties of PersL, it was necessary
to study these aspects in more detail by analyzing the luminescence
kinetics.The luminescence lifetime is a very important parameter
for understanding
the quenching mechanisms related to many aspects of nonradiative relaxation
of excited states depending mainly, but not exclusively, on the distance
between dopant ions (their concentration), the local crystal field
of the luminescence center and its distortions, grain size, effective
refractive index, and the presence of the OH group.[55−57] On the other
hand, it provides with the combined analysis of the excitation spectra
an understanding of the excitation pathways between dopant ions. In
view of this, the lifetimes for emission at 520 nm (Ce3+:5d → 4f transition), 606 nm (Pr3+:1D2 → 3H4 transition), and 690 nm (Cr3+:4T2 → 4A2 transition)
after excitation at 350 nm (specific for Ce3+) and 450
nm for exciting all ions at the same time were detected (Figures S5 and S6, respectively). Then, an effective
(average) lifetime was calculated (Figure S7). From the profile of the lifetime Ce3+ emission, it
can be seen that increasing annealing temperatures has a slight impact
on decreasing lifetime, which is related to crystalline size and has
no significant effect on the energy transfer to Pr3+ and
Cr3+. The average lifetime for Pr3+ coincides
with the values previously obtained for the garnet matrix[58] and confirms the affiliation of this band to
the 1D2 → 3H4 transition.
At the same time, it is worth noting that the lifetime may depend
on many factors, and as we can see at annealing temperatures from
900 to 1100 °C, the number of hydroxyl groups,[30] which are the quenching centers, decreases but at the same
time the so-called effective refractive index, which affects the rate
of radiation processes from lanthanide ions, increases. As a result,
depending on the contribution of both factors, one can observe first
an increase in the lifetime with quenching and then its decrease to
values typical for reference single crystals. The effect of the effective
refractive index, which can also be related to the degree of agglomeration
(in the case of powders) as well as to porosity (of optical ceramics)
on the rate of radiation processes in luminescent materials, is quite
well described in previous papers.[55,57] What is relevant
here is only the information that with the increasing agglomeration
of powders (or removal of porosity from ceramics) there is a shortening
of the measured lifetime, finally to a value corresponding to the
lifetime of the monocrystals of the compounds under consideration.The QYs for all samples were detected after excitation at both
350 and 450 nm with an integrated sphere, and the obtained results
are reported in Figures S8 and 8.
Figure 8
Quantum yields of the YAGG:Ce3+,Cr3+,Pr3+ powder synthesized at R = 0.25
(a) and
1 (b).
Quantum yields of the YAGG:Ce3+,Cr3+,Pr3+ powder synthesized at R = 0.25
(a) and
1 (b).For both investigated series, quantum yields are
very low for excitation
at 350 nm (Figure S8). This may be because
the total emission is only due to the transfer of energy from Ce to
Pr and Cr. In the case of λexc = 450 nm, the energies
of all doped ions exited at the same time and QY are higher. In this
case, for the R = 0.25 series, no trend is observed
with increasing calcination temperature. However, for the R = 1 series for the same relation, more stable values of
the quantum efficiency are observed with small deviations within the
error limit. As we can see from Figure , the QY is maximal for an annealing temperature of
1200 °C.
Thermoluminescence
The TL curves have been acquired
to obtain information about the traps in obtained nanophosphors and
the effect of urea/metal molar ratios on the trap redistribution.
The recorded TL curves (Figures and S9) clearly show the
main band with a maximum at ∼47 °C (∼320 K) and
the additional band on the high-temperature side, which is not clearly
pronounced against the background of the main band with a maximum
of ∼87 °C (∼360 K). The general shape of the TL
curve is similar to that obtained previously for such structure syntheses
with other methods.[30,40] For both urea/metal ratios (R), TL curves are quite symmetrical (except for the band
on the high-temperature side), which indicates a homogeneous redistribution
of traps with similar energy. Nevertheless, the contribution from
the trap component with the TL maximum at around 47 °C is the
most pronounced. However, these traps are not clearly separated, which
may indicate the free transfer of electrons between them. For a more
detailed analysis of the redistribution of traps and the nature of
the additional band, a series of TL curves (Figure S10) was registered based on the method of precleaning traps,
a so-called Tmax–Tstop method.[45]
Figure 9
TL curve of the YAGG:Ce3+,Cr3+,Pr3+ powder synthesized at R = 0.25 (a) and 1 (d) and
calcined at 1200 °C. Graphs of Tmax to Tstop dependence (b, e), and the
photograph of the obtained powder after UV irradiation (c, f).
TL curve of the YAGG:Ce3+,Cr3+,Pr3+ powder synthesized at R = 0.25 (a) and 1 (d) and
calcined at 1200 °C. Graphs of Tmax to Tstop dependence (b, e), and the
photograph of the obtained powder after UV irradiation (c, f).Based on the obtained data, plots of Tmax versus Tstop are drawn
and presented
in Figure b,e for R = 0.25 and 1, respectively. The linear nature of the obtained
curves with a line of a slope near 1.0 indicates that we have a series
of first-order peaks. As the peaks overlap more, the interpretation
tends toward the existence of a quasi-continuous distribution of peaks
(and, therefore, of trapping centers).[59,60] As shown in
the plots, the final release temperature for the sample synthesized
at R = 0.25 is 150 °C (for calcination temperature
1400 °C), while for R = 1, it is 120 °C.
As a result, long-term luminescence is registered only for nanoparticles
with an annealing temperature of 1400 °C (Figures c and S11a). It
should be noted that for samples synthesized at R = 0.25, the slope was 0.65 ± 0.3 for nanoparticles annealed
at 900 °C and approached 1 with increasing annealing temperature.
It was 0.98 ± 0.03 for the sample annealed at 1400 °C. By
comparing these data with the PersL of this series (Figures c and S11a), we can assume that there is a correlation between the
glow and the degree of trap redistribution. In particular, we can
expect that with a uniform quasi-continuous distribution of traps,
the retrapping process is more uniform and thus contributes to long-term
emission, while, for the series of single traps, the detrapping process
will be uneven, and the recapture process will increase, resulting
in increased losses and reduced afterglow time. In addition, the final
release temperature for the sample synthesized at R = 0.25 is 150 °C, while for R = 1, it is 120
°C (in both cases when calcined at 1400 °C). This means
that for R = 0.25, there are traps with maxima at
higher temperatures. At the same time, the samples synthesized at R = 1 show a completely different trend of the slope in
terms of trap redistribution based on Tmax–Tstop data analyses. The slope
increases from 0.78 ± 0.1 to 0.98 ± 0.02 with increasing
calcination temperature from 900 to 1200 °C and then begins to
decrease to 0.85 ± 0.02 at 1400 °C, which in turn also correlates
with the brightness of PersL (Figures f and S11b). Thus, the effect
of R on the resulting redistribution of traps is
worth noting, namely, for R = 1, it is possible to
obtain nanophosphors with a smaller size of crystallites.To
analyze these traps, in addition to the Tmax–Tstop method, initial
rise analyses[61] were used to determine
the energies of each of the recorded curves. As a result, it was found
that the activation energies for both series are the same and equal
to around 0.75 ± 0.01 eV. Additionally, the analysis of the data
using the initial rise method allowed the possibility for us to dedicate
a series of traps with an energy of about 0.3 eV for a band from the
high-temperature side for both samples. The existence of shallow traps
can have an additional impact on the observed effects (PersL), and
their nature may be directly related to structural changes, including
surface defects.The similarity of the activation energy for
the samples from both
series with different results with respect to the afterglow may indicate
a nonlinear relationship between the depth of the trap and the efficiency
of the glow, as previously reported.[40,62] By linking
these results with the previous analysis of the structure and optical
properties, it can be concluded with a high probability that despite
traps with similar energy values, the intensity and duration of PersL
may be influenced by other factors. In particular, morphology, phase
change, redox reactions of the dopant ions, changes due to clustering
of such dopants, and so on. However, this should be further established.
Conclusions
The synthesis of YAGG:Ce3+,Cr3+,Pr3+ crystallites with sizes starting from 45
nm by the urea glass route
method (UGR) is successfully realized. UGR can be considered a more
ecological, inexpensive, one-pot method with high yields, and therefore,
it is suitable for large-scale production. The UGR method is relatively
easy to carry out and gives results similar to other methods we have
previously tested. The ratio of urea/metal salts, R, influences the formation of the gel-like, and for this study, we
selected two systems at R = 0.25 and 1. The gel-like
prepared at R = 0.5 was not selected because of a
few differences in behavior observed between them. The two gel-like
substances were then treated at 900, 1000, 1100, 1200, 1300, and 1400
°C for 1 h. From the structural and morphological point of view,
there are no substantial differences in the cell parameters, crystallite
size, and particle size with R. However, at the same R, the increase in size occurs with increasing temperature.
At all temperatures, the composition of the powders respects the nominal
ratio between atoms in the powders. Only some samples, treated at
higher temperatures, showed efficient persistent luminescence. Regardless
of synthesis parameters, we obtain nanopowders with long-term emission,
which is associated with the presence of a series of first-order quasi-continuous
distribution traps, which, in terms of applications, are important
and contribute new knowledge. In potential biological applications
and also in the field of luminescent labeling, not always duration
and intensity are the most important criterion for their suitability.
By changing the parameter R, it is possible to achieve
a more uniform distribution of quasi-continuous traps, which in turn
has a positive effect on obtaining PersL from phosphors in the nanoscale
range. Additional maxima at the shoulder of high temperatures with
an energy of around 0.3 eV are detected. This may be due to the presence
of traps associated with structural imperfections in particular to
the heterogeneous redistribution of dopant ions on the surface of
the obtained nanophosphors.
Authors: M A Chaika; R Tomala; W Strek; D Hreniak; P Dluzewski; K Morawiec; P V Mateychenko; A G Fedorov; A G Doroshenko; S V Parkhomenko; K Lesniewska-Matys; D Podniesinski; A Kozłowska; G Mancardi; O M Vovk Journal: J Chem Phys Date: 2019-10-07 Impact factor: 3.488
Figure 1
Figure 2
Figure 3
Figure 4
Figure 5
Figure 6
Figure 7
Figure 8
Figure 9