Introduction

Infrared to visible upconversion luminescence has been extensively studied for its fundamental value1,2,3 and its various potential applications in upconversion lasers,4 bioimaging,5 etc. The codoping of Er3+ and a high concentration of sensitizer Yb3+ forms the most attractive energy transfer upconversion (ETU) system. Under infrared (980 nm) excitation of the sensitizer Yb3+, this system can generate green and red upconversions originating from the 4S3/24I15/2 and 4F9/24I15/2 transitions of Er3+, respectively. Unlike the green upconversion, the red upconversion benefits from several possible excitation mechanisms.6,7 Multiphonon relaxation (MPR) from the upper 4S3/2 state and ETU from the lower intermediate 4I13/2 state are generally considered dominant at low infrared excitation densities because other mechanisms involving three photon processes6,7 become important only at high infrared excitation densities,8 which is not the topic of this work.

The MPR is not the only mechanism for populating the 4F9/2 from the 4S3/2; a non-MPR mechanism was proposed earlier,8 but it has not been considered important since then. This mechanism involves two sequential energy transfers between Er3+ and Yb3+. The first step is a well-known cross-relaxation (CR) energy transfer from Er3+ in the 4S3/2 excited state (4S3/24I13/2) to Yb3+ in the ground state (2F5/22F7/2),9 resulting in the excitation of Er3+ 4I13/2 and Yb3+ 2F5/2. The subsequent step is an energy back transfer from the Yb3+ (2F5/22F7/2) excited by the CR to Er3+ in the 4I13/2 state (4F9/24I13/2) to promote the excitation of Er3+ 4F9/2. Hence, the CR can be divided into two parts: one is followed by the energy back transfer, CRB, and the other is not followed by the energy back transfer, CRNB. The Yb3+-induced green emission quenching of Er3+ by the CR has been widely recognized.9,10 However, the population of the 4F9/2 by the CRB from the 4S3/2 has rarely been studied or valued in both photoluminescence (PL) and upconversion luminescence (UCL).

In this article, we report an observation of the CRB in cubic Y2O3: Er3+, Yb3+. We find the CRB can be more efficient than MPR and can even make a major contribution to the red UCL. To the best of our knowledge, this is the first time that the CRB has been found to be important to the red emission both in the PL and UCL of the Er3+–Yb3+ system.

Materials and methods

Sample preparation

The cubic Y2O3:0.002Er3+, xYb3+ (x=0, 0.04, 0.1, 0.2, 0.3) samples were prepared by the normal firing precursor method.2 The firing precursor is more favorable to achieve uniform and highly crystallized samples than the traditional solid-state reaction. The starting aqueous solutions, Y(NO3)3,Yb(NO3)3, and Er(NO3)3, with corresponding mole ratios were mixed and stirred vigorously to form a homogeneous solution. The samples were obtained after being dried at 100 °C for 6 h and then calcined at 1600 °C for 6 h. The expression of Y2O3:0.002Er3+, xYb3+ in the present paper means the formula Y2−0.002−xEr0.002YbxO3. The low Er3+ and high Yb3+ concentrations applied in this work were used to achieve a real ETU system and suppress the interaction among Er3+ ions for simplifying the ETU processes.

Spectroscopy measurements

Steady state PL and UCL spectra were measured using an EI-FS920 fluorimeter with a xenon lamp as an excitation source for PL and a CW 980 nm laser diode as an excitation source for UCL. The decay curves of PL and UCL were detected using a Triax 550 spectrometer (Jobin-Yvon) and recorded by a Tek-tronix digital oscilloscope (TDS 3052), while a 10 ns pulsed laser with tunable wavelengths from an optical parametric oscillator pumped by a Nd:YAG laser (spectra-physics, GCR 130) was used as an excitation source. In energy level lifetime measurements, the excitation wavelengths were tuned to 520 nm for Er3+ 4S3/2, 650 nm for Er3+ 4F9/2 and 4I11/2, 1480 nm for Er3+ 4I13/2 and 980 nm for Yb3+ 2F5/2. The lifetime is defined as the area under the decay curve with normalized initial intensity. The UCL spectra under pulse excitation at 980 nm were detected using a USB4000 spectrometer (Ocean Optics), which gives the time-integrated intensities.

Results and discussion

Observation of the CRB in PL

Figure 1 shows PL spectra of Y2O3:0.002Er3+, xYb3+ under 520 nm excitation of Er3+ 2H11/2, which can rapidly relax to the 4S3/2 due to their proximity in energy. One can observe that the red (660 nm) to green (560 nm) emission intensity ratio (R/G) increases considerably with increasing x. A similar result upon Er3+ 4F7/2 excitation with 488 nm was also observed in Y2O3:Er3+, Yb3+ nanocrystals,11 and an interaction between two excited Er3+ ions (4F7/24F9/2 and 4F9/24I11/2)7 was considered the main excitation mechanism of the red-emitting 4F9/2 state. In the present work, the 4F7/2 is not excited and the Er3+ concentration is low, so the above mechanism is not feasible. We found through experimentation that the R/G ratio remains unchanged if La3+ or Lu3+is doped instead of Yb3+, indicating that the 4S3/24F9/2 MPR rate hardly changes with rare earth doping. Therefore, we attribute the Yb3+-induced R/G increase to the effect of CRB, which benefits from well-matched energy level structures between Er3+ and Yb3+, as sketched in the insert to Figure 1. The CRB may take place within the same Er3+–Yb3+ pair, meaning that the Yb3+ ion excited by the CR transfer from Er3+ transfers its energy back again to the same Er3+ ion. The CRB rate in this case is independent of excitation densities, similar to the MPR. If the CRB takes place not within the same Er3+–Yb3+ pair, i.e., the excitation energy of Yb3+ is not retransferred to the same Er3+ but transferred to any other Er3+ ion in the 4I13/2 state, then the CRB rate in this case is dependent on the concentration of the other Er3+ ions and thus dependent on excitation densities. Therefore, the CRB may become important only at high excitation densities. In the present work, the Yb3+-induced R/G increase can be observed under weak 520 nm excitation using a grating monochromator with a xenon lamp. We found that the enlarged R/G ratio in the presence of Yb3+ is independent of excitation densities using the xenon lamp as an excitation source. Based on the CRB models mentioned above, we consider that the CRB takes place within the same Er3+–Yb3+ pair in the samples in this work.

Figure 1
figure 1

PL spectra upon 2H11/2 excitation at 520 nm. The green emission intensities are normalized, and the red ones (620–700 nm) are magnified 10 times. The insert shows the energy level diagram with the CR and CRB processes. CR, cross-relaxation; PL, photoluminescence.

Time evolutions of PL are measured for distinguishing the CRB from the MPR, as shown in Figure 2. With increasing x, the appreciable shortening of the 4S3/2 lifetime (τ4) (Figure 2a) is due to the CR,9,10 and the small shortening of the 4F9/2 lifetime (τ3) (Figure 2b) is due to weak coupling12 of Er3+ 4F9/24I15/2 with Yb3+ 2F5/22F7/2. In the time evolution of the red emission after the 4S3/2 is populated (Figure 2c), we find that the samples containing Yb3+ appear to undergo a fast build-up process, unlike the Yb3+-free sample that appears as a normal slow rising edge.13 Accordingly, the time evolution patterns in the presence of Yb3+ shown in Figure 2c are the combined patterns of the fast build-up component and the slow build-up component. If one normalizes the initial emission intensity of the fast build-up component (Figure 2c) and denotes the total area under the time evolution curve by T3, the proportion of the emitted red photons by the fast build-up component of the total emitted red photons can be calculated by τ3/T3. This proportion is found to be consistent with the proportion of the increment in the R/G ratio (Table 1), written as α=1−(τ3/τ3,0)(R/G)0/(R/G), where the subscript 0 identifies the case of x=0 and (τ3/τ3,0)(R/G)0 is the R/G ratio contributed only by MPR in the presence of Yb3+. The result indicates that the CRB is a fast process. Accordingly, there must be a fast CR. However, a corresponding fast decay of the green emission is not detected (Figure 2a). We thus deduce that the fast green emission may be completely quenched by the fast CR. This deduction is further evidenced in the following section.

Figure 2
figure 2

Time evolutions of the green and red emissions.

Table 1 PL data used to identify the CRB process in Y2O3:0.002Er3+, xYb3+

Efficiency of the CRB in PL

After the 4S3/2 is populated upon 520 nm excitation, the 4S3/2 undergoes depopulation by radiative transition, MPR, CRNB and CRB, with respective efficiencies of ηr4, ηMPR43, ηCRNB and ηCRB. Figure 3 shows the comparison of PL spectra under 520 nm excitation with that under 650 nm excitation of the 4F9/2. Here, the red intensity under 650 nm excitation is normalized to that under 520 nm excitation. Under 520 nm excitation, one can find that the green intensity decreases rapidly with increasing x, followed by simultaneous intensity enhancement of Er3+ 4I13/24I15/2 emission at 1530 nm and Yb3+ 2F5/22F7/2 emission at 1040 nm compared to that under 650 nm excitation. The feature is an explicit indication of the CRNB process. In the absence of Yb3+, the Er3+ 4I11/24I15/2 emissions for both 520 nm and 650 nm excitations can be observed at 1000 nm; they coincide because the population of 4I11/2 by 4S3/24I9/2, 4I11/2 radiative transitions for 520 nm excitation is very small with respect to that from the 4F9/2 by cascade MPR. In the presence of Yb3+, the Er3+ 4I11/24I15/2 emission is too weak to be identified, and instead, the Yb3+ emission is dominant. This is due to a highly efficient energy transfer from Er3+ 4I11/2 to Yb3+ 2F5/2,14 which is also evidenced by the very weak 1530 nm emission of Er3+ under 650 nm excitation. In addition, one may find that the Yb3+ emission intensities decrease with increasing x in the x range of 0.1–0.4 for 520 nm excitation. The decline is due to concentration quenching because the critical concentration of Yb3+ was observed to be 7.36% in the Y2O3 host.15

Figure 3
figure 3

Comparison of PL spectra upon 2H11/2 excitation at 520 nm with that upon 4F9/2 excitation at 650 nm. The red emission intensity under 650 nm excitation is normalized to that under 520 nm excitation. The red emission intensities (600–700 nm) are magnified 20 times. PL, photoluminescence.

We evaluate ηr4, ηMPR43, ηCRNB and ηCRB based on the observed increase in the Er3+ 1530 nm emission, Yb3+ 1040 nm emission and Er3+ R/G ratio for 520 nm excitation. Considering the distinct increment (I1i1) in 1530 nm emission intensity in the presence of Yb3+, one may also observe a small increase for x=0. The small increase is attributed to the feeding by the 4S3/24I13/2 radiative transition, which has a big branch ratio (β=0.27).16 Hence both the CRNB and the 4S3/24I13/2 radiative transition contribute to the increase. Regarding the experimentally observed x-independent 4I13/2 lifetime, we have, as described in Supplementary Equations (S1)–(S4)

where Ii and ii are emission intensities from the ith state of Er3+ upon 520 nm and 650 nm excitations, respectively. These emission intensities on the right side of Equation (1) are dependent on x.

For the increment (Idid) in Yb3+ emission intensity, the CRNB is the only contributor, while the rest intensity (id) is populated by quasi-resonant energy transfer from Er3+ 4I11/2 with a transfer efficiency close to 1 due to the high Yb3+ concentration. The 4I11/2 can be populated from the 4F9/2 via the 4I9/2 by cascade MPR with an efficiency of almost 100%, regarding a very short 4F9/2 lifetime (approximately 20 μs) compared with its radiative lifetime (600 μs).16 As a result, the population of the 4F9/2 by the MPR and the CRB from the 4S3/2 finally and completely reaches the 4I11/2. Hence, the excitation source of the rest Yb3+ emission is the MPR and the CRB from the 4S3/2. Then, we have

where the subscript d denotes Yb3+.

The red emission is populated by MPR and CRB from the 4S3/2, so the R/G ratios simply satisfy

Using Equations (1)–(3) with ηr4+ηMPR43+ηCRNB+ηCRB=1, we calculated the efficiencies, as shown in Figure 4a. We obtained ηMPR43/ηr4=2.08, which yields ηr4=32% for cubic Y2O3:Er3+. The measured green PL intensities (square) follow the tracks of ηr4 well, but it decreases faster than τ4 with increasing x (Table 1). This feature further implies the existence of an undetected fast decay in the green emission, as indicated in the above section, like the case of the Perrin model.17 We may consider an ‘active sphere’ centered at an Er3+ ion so that its green emission can be completely quenched by a Yb3+ ion located within the sphere through the CR. If the number of the effective cation sites within the sphere is n, the fraction (f) of Er3+ ions that have no Yb3+ in the sphere satisfies the binomial distribution: f=(1−x/2)n. Considering that the green luminescence yield (I4 or ηr4) can be regarded as the area under its decay curve including the undetected fast component, then f can be obtained either by (I4/I4,0)(τ4,0/τ4) or (ηr4/ηr4,0)(τ4,0/τ4) from the decay picture of the green emission containing a fast component with a lifetime close to 0 and a slow one with a lifetime of τ4, weighted by 1−f and f, respectively, as described in Supplementary Fig. S1 and Equation (S5).

Figure 4
figure 4

(a) Area graph for efficiencies of various processes for depopulating the 4S3/2 state in Y2O3:0.002Er3+, xYb3+ under 520 nm excitation. The measured green emission intensities are also shown (squares). (b) Comparison of experimental and theoretical dependence of f on x. The experimental data are obtained by (I4/I4,0)(τ4,0/τ4) (circle) or (ηr4/ηr4,0)(τ4,0/τ4) (filled circle).

In cubic Y2O3, there are two Y sites with respective C3i and C2 symmetries. The C3i has an inversion center on this site; the 4f–4f transition of a rare earth ion is forbidden. Therefore, only the C2 site is effective. A C2 site has four of the first nearest C2 sites, four of the second nearest C2 sites and six of the next nearest C2 sites. The fitting results point to n=8, as shown in Figure 4b, indicating that the green emission of an Er3+ can be completely quenched only by an Yb3+ located in the nearest site of the Er3+ ion. As a result, the nearest Er3+–Yb3+ pairs exhibit completely quenched green emission and produce the undetected fast decay of the green emission. As we have observed, the CRB is a fast process; thus, the CRB takes place only within the nearest Er3+–Yb3+ pairs. Of course, the occurrence of a fast CRNB is also expected in the nearest Er3+–Yb3+ pairs. Accordingly, the distant Er3+–Yb3+ pairs can only perform the slow CRNB to reduce τ4. In Figure 4a, over 30% of the CR is the CRB upon 520 nm excitation, and the CRB becomes more important than the MPR for populating the red-emitting state from the green state as x≥0.1. The efficient CRB benefits from the nearest Er3+–Yb3+ pairs that can compete with the energy transfer from the Yb3+ ions excited by the CR to other Yb3+ ions outside the pairs. The nearest Er3+–Yb3+ pair ensures that the CRB takes place within the pair because the energy back transfer from Yb3+ to other Er3+ undergoes a longer interaction distance due to the low Er3+ concentration used in this work. Hence, no dependency of the CRB on excitation densities is observed in the present work. The Perrin model, like CRB, may be governed by the exchange mechanism described by Inokuti and Hirayama.17

In CRB, the CR transfer from Er3+ (4S3/24I13/2) to Yb3+ (2F5/22F7/2) and the back transfer from Yb3+ (2F5/22F7/2) to Er3+ (4F9/24I13/2) suffer from an energy mismatch of 1700 cm−1 and 1500 cm−1, respectively, which is more than twice as large as the cutoff phonon energy of 600 cm−1 in Y2O3. The performance of the energy transfers thus requires emission of two or three phonons to make up for the large energy mismatch. In spite of requirement of several phonons, the high Yb3+ concentration and the nearest Er3+–Yb3+ pairs make the transfers efficient.

Effect of the CRB on UCL

Figure 5 shows the UCL spectra for Y2O3:0.002Er3+, 0.1Yb3+ upon pulse and CW infrared (980 nm) excitations. For comparison, its PL spectrum is also presented. The phenomenon11,18,19,20 that the R/G ratio in PL is much less than that in UCL is evident. Ignoring the CRB, it was naturally deduced from the phenomenon that the ETU from 4I13/2 makes the major contribution to the red UCL.18,19 If the CRB is operative, the above deduction could be possibly invalid because of the following reasons: the nearest Er3+–Yb3+ pairs can be preferentially excited to the Er3+ 4S3/2 state by two sequential energy transfers from Yb3+ in ETU, as shown in the insert to Figure 5. Meanwhile, the CRB enables the nearest Er3+–Yb3+ pairs to only have a red emission in the visible spectral region. In the PL measurement, however, each Er3+ ion has the same probability to be excited to the 4S3/2 state by ground state absorption. Based on the analysis above, a much smaller R/G ratio of PL than that of UCL is still achievable if the CRB makes the major contribution to the red UCL. In other words, the observation of a much smaller R/G ratio for PL than for UCL cannot exclude the major role of the 4S3/2 state in populating the red-emitting state in the upconversion of the Er3+–Yb3+ system. In our experiment, the PL and UCL temporal behaviors of Y2O3:0.002Er3+, 0.1Yb3+ (Figure 6) demonstrate that the 4F9/2 is populated mainly from 4S3/2 in ETU, as analyzed below.

Figure 5
figure 5

UCL spectra upon CW and upon pulse 980 nm excitations as well as a PL spectrum for Y2O3:0.002Er3+, 0.1Yb3+. The green emission intensities are normalized. The CW excitation density is as low as 50 mW cm−2. The insert is the diagram of ETU processes for the Er3+–Yb3+ system. ETU, energy transfer upconversion; PL, photoluminescence; UCL, upconversion luminescence.

Figure 6
figure 6

Time evolutions of the green UCL (560 nm), the red UCL (670 nm), Yb3+ emission (1040 nm) and Er3+ emission (1530 nm) from 4I13/2 after pulse 980 nm excitation for Y2O3:0.002Er3+, 0.1Yb3+. UCL, upconversion luminescence.

From Figure 6, the Yb3+ emission decays exponentially (with a decay time of τd=840 μs), indicating the rapid diffusion limited energy transfer. The decay time of the green UCL is 391 μs, and that of the red is 412 μs. These UCL decay times are much longer than τ4 (66 μs) and τ3 (20.9 μs) (Table 1), exhibiting the typical effect of ETU. Thus, the UCL decay function is mainly determined by the product of the decay functions of the Yb3+ 2F5/2 and Er3+ intermediate states. The green UCL decay time approaches τd/2, reflecting that Er3+ 4I11/2, as the intermediate state for the green upconversion, has the same decay time as Yb3+ 2F5/2 because the two levels are thermally coupled in case of rapid energy transfer between them, as predicated earlier.14 The approximation of the red UCL decay time to the green one indicates that the 4F9/2 is populated mainly from the 4S3/2 under pulse infrared excitation; otherwise, the red could have a decay time close to τd (840 μs) because of the quite long lifetime (τ1=8.4 ms) of the intermediate 4I13/2 state. Now, we want to determine if the 4F9/2 is still populated mainly from the 4S3/2 under CW infrared excitation.

In Figure 5, one may find that the R/G ratio in UCL for CW excitation, (R/G)UCL@CW, is larger than that for pulse excitation, (R/G)UCL@pulse. The smaller (R/G)UCL@pulse arises from the low build-up process of the 4I13/2 state (Figure 6), as described in Supplementary Equation (S10), which slows down the ETU from the 4I13/2 to the 4F9/2 after pulse infrared excitation. Taking the different R/G ratios into account, the percentages of the red component R4, populated from the 4S3/2, and R1, from the 4I13/2, can be evaluated.

If the 4S3/2 and the 4F9/2 states are populated under infrared excitation in ETU, we denote the mean emitting efficiencies of the two states by ηG and ηR, respectively. While the mean depopulating efficiency from the 4S3/2 to the 4F9/2 via MPR and the CRB is denoted by η43, the R/G ratio in UCL is

where ηG, ηR and η43 are unchanged for CW or pulse infrared excitations. In view of the high Yb3+ and low Er3+ concentrations, we assume here the simplest possible model; (i) ETU undergoes the rapid diffusion limited energy transfer from Yb3+ that can be described by an average energy transfer rate; (ii) the ground and excited states absorption of Er3+ is neglected. We also assume the 4F7/2 can rapidly and completely relax down to the 4S3/2 state due to their proximity in energy.

From the diagram of ETU processes inserted in Figure 5, the population flow from the 4I11/2 to the 4F7/2 is Cd5ndn2 and that from the 4I13/2 to the 4F9/2 is Cd3ndn1. Under CW excitation, the population flow is time independent, and thus, R4@CW=ηRη43Cd5ndn2 and R1@CW=ηRCd3ndn1, where Cdi is the coefficient for energy transfer from donor Yb3+ to the ith state of Er3+, and nd and ni are populations of Yb3+ 2F5/2 and Er3+ in the ith state, respectively. Then, the R1/R4 ratio for CW infrared excitation is expressed as

where W21 is the sum of the 4I11/24I13/2 radiative and MPR rates, which satisfies W21n2=n1/τ1 for a steady state excitation.

Under pulse infrared excitation of Yb3+, we detect the upconversion luminescence yield over time. Based on the rate equations for describing ETU in the Er3+–Yb3+ system, as in Supplementary Equations (S7)–(S13), we obtain

From Figure 5, the R/G ratio in UCL for CW excitation is 1.2 times as large as that for pulse excitation,

Combining Equations (4)–(7) with τd=840 μs and τ1=8.4 ms gives (R1/R4)@pulse=0.02 and (R1/R4)@CW=0.22 for Y2O3:0.002Er3+, 0.1Yb3+. These values mean that only 2% of the red UCL is populated from the 4I13/2 and 98% from the 4S3/2 under pulse infrared excitation, and for CW infrared excitation, 18% of the red UCL is populated from the 4I13/2 and 82% from the 4S3/2. The main role of the 4S3/2 in populating the red UCL reflects a strong CRB. Meanwhile, the small contribution of the ETU from the 4I13/2 is partially due to a small value of Cd3/Cd5 that is calculated to be 0.124η43 using Equation (5). In this calculation, a W21 of 218 s−1 is used, which is determined from our measured 4I11/2 lifetime (τ2,0) of 2.73 ms in Y2O3:0.002Er3+ and the reported16 intrinsic 4I11/2 lifetime of 6.03 ms and 4I11/24I13/2 radiative branch ratio of 0.108. The small Cd3/Cd5 ratio is well understood in view of a large energy mismatch (1500 cm−1) in the transfer from Yb3+(2F5/22F7/2) to Er3+(4F9/24I13/2) relating to Cd3, while the energy transfer from Yb3+(2F5/22F7/2) to Er3+(4F7/24I11/2) relating to Cd5 is quasi-resonant.

Obviously, a high Yb3+ concentration and preferential excitation of the nearest Er3+–Yb3+ pairs in ETU can promote the CRB process. Meanwhile, increasing the population ratio of Er3+ 4I11/2 to 4I13/2 is beneficial to ETU from the 4I11/2 to the 4F7/2, and it thus can promote the contribution of the CRB to the red UCL against the ETU from the 4I13/2 to the 4F9/2. Therefore, the host material with low cutoff phonon energy likely has a pronounced CRB process like Y2O3. However, this population ratio is usually reduced in nanomaterials because the 4I11/24I13/2 MPR is strongly enhanced by coupling with OH groups on the large surface of the nanomaterials.21

Conclusions

We observed a pronounced CRB process for populating the Er3+ red-emitting state from its green state in cubic Y2O3:Er3+, Yb3+. We found the CRB can be more efficient than MPR and can even make the major contribution to the red emission in both PL and UCL. The CRB takes place only in the nearest Er3+–Yb3+ pairs, and thus, it is a fast and efficient process at low excitation densities. The present research methods may be applied to a general Er3+–Yb3+ system, and the identification of the importance of the CRB in other material hosts is expected.