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Up-Conversion Luminescence from Ln (Ho , Pr ) Ions Doped BaCl Particles via NIR Light of Sun Excitation 2
Hong Jia, Zhongli Liu, Lamei Liao, Yanhong Gu, Chaoliang Ding, Jianguo Zhao, Weiying Zhang, Xiaoke Hu, Xun Feng, Zhi Chen, Xiaofeng Liu, and Jianrong Qiu J. Phys. Chem. C, Just Accepted Manuscript • DOI: 10.1021/acs.jpcc.8b02434 • Publication Date (Web): 16 Apr 2018 Downloaded from http://pubs.acs.org on April 16, 2018
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Up-Conversion Luminescence from Ln3+(Ho3+, Pr3+) Ions Doped BaCl2 Particles via NIR Light of Sun Excitation Hong Jiaa,* b, Zhongli Liua, Lamei Liaoa, Yanhong Gua, Chaoliang Dinga, Jianguo Zhaoa, Weiying zhanga, Xiaoke Hua, Xun Fenga, Zhi Chenc*, Xiaofeng Liub, and Jianrong Qiub*, c a
College of Physics and Electronic Information & Henan Key Laboratory of Electromagnetic
Transformation and Detection, Luoyang Normal University, Luoyang 471934, China. b
State Key Laboratory of Silicon Materials, Department of Materials Science and
Engineering, Zhejiang University, Hangzhou 310027, China. c
State Key Laboratory of Luminescent Materials and Devices, and Guangdong Provincial
Key Laboratory of Fiber Laser Materials and Applied Techniques, South China University of Technology, Guangzhou 510641, China.
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ABATRACT: Generation of visible photons by upconverting materials under excitation by the near infrared part of sunlight is very attractive for complete utilization of solar energy. Visible upconversion luminescence is efficiently generated in BaCl2: Ln3+ (Ho3+ or Pr3+) particles via excitation with broadband near infrared part of sunlight. We observed greatly enhanced photocurrent response from the thin film hydrogenated amorphous silicon solar cell covered with the upconversion layer of BaCl2: Ho3+ phosphor, which demonstrates a prospective application for near-infrared photoresponse devices.
■ INTRODUCTION Upconversion materials doped with lanthanide ions are expected to find potential applications in area of biomarkers, color display and photovoltaics (PV)1-12. Attaching an UC layer at the rear face of a PV device is very promising for enhancement of power conversion efficiency (PCE)13-17. However, the reported efficiencies of these UC-enhanced solar cell efficiencies demonstrated only small improvement and these early experiments
merely served as
proof-of-principle demonstration. This problem is due to the fact that the efficiency of UC is very low, and the excitation spectral region is very narrow due to the 4f-4f transition nature of RE ions compared to the solar spectrum18-21. This problem could be solved by the use of broadband UC materials, which however are rare. Recently, Zou et al19. showed that using cyanine dye molecule enabled a broadband excitation of NaYF4 nanoparticles codoped with Yb3+ sensitizers and Er3+ activator ions by energy transfer between dye and Yb3+ ions. However, indirect excitation through heterogeneous energy transfer suffers competitive energy loss; what's more, the poor photostability of dyes hinders their application for long-term solar irradiation. Alternatively, Broadband NIR photons excited visible-NIR UC by combination of the absorption bands of different RE ions through core-shell nanofabrication22. However, it's hard to fully harvest the solar energy with continuous energy distribution due to the discrete characteristic absorptions of RE ions. In addition, heterogeneous doping will inevitably suffer detrimental energy transfer among RE ions. To improve the upconverted emission efficiency required by practical applications, another approach is to use
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multi-wavelength excitation. Blue-green UC laser has been achieved by two-color (two NIR light) pumping23, and especially, Ho3+ doped UC materials have promised for enhancement of UC luminescence under multi-wavelength excitation24-26. It’s therefore feasible to use this new strategy to realize broadband excited UC, aiming at the complete utilization of solar energy. However, Up to now, in most of the proof-of-concept experiments, UC materials and their application are commonly investigated using monochromatic lasers with high power densities. The use of non-coherent light source to generate UC emission from Ho3+ or Pr3+ions doped materials and the simulation of a hybrid cell combining such UC materials in a close-to-reality working conditions remains a tremendous challenge.
Figure 1: Schematic representation of the PV-UC cells for measurement of NIR photoresponse. Herein, UC luminescence of BaCl2: Ho3+/BaCl2: Pr3+ phosphor powders which give bright UC luminescence under excitation of concentrated incoherent broadband NIR sunlight are systematically investigated. We further demonstrate the use of BaCl2: Ho3+ powder as a rear face of solar cell application for NIR light harvest (Figure 1). The rational design is briefly sketched in Figure 1. The BaCl2: Ho3+ particles as a upconverter layer absorb and convert the NIR sunlight to visible luminescence by UC processes, and then visible light
was
reflected and efficiently reabsorbed by hydrogenated amorphous silicon (a-Si:H) solar cells and produces photoelectrons. The a-Si:H solar cells respond to the spectral range from 380 to 750 nm27. The back contact is a transparent conducting material which serves as the electrode
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and permits the incoherent broadband NIR sunlight to excite the UC layer. This new simple and effective methodology may facilitate the application of UC materials in NIR photo-detectors and solar cells.
■ EXPERIMENTAL METHODS Stoichiometric amounts of 99.99% purity PrC13, 99.99% purity BaCl2, 99.99% purity HoC13 and 99.5% NH4Cl (molar ration HoC13 : NH4Cl = 1 : 24) were uniform mixed in high purity Ar gas, and then transferred into a covered cylinder glassy crucible and heated in tubular furnace under the protection of Ar. The furnace was heated to 950 °C and kept and this temperature for 1.5 h, and then the furnace was cooled down slowly to room temperature. BaCl2: Ho3+ phosphor was fabricated by this solid state reaction method28. The crystal structures of the as-synthesized powders were studied by X-ray diffraction (XRD) on a X’Pert PRO X-ray diffractometer (PANalytical, Netherland) using Cu Kα (λ = 1.5418 Å) radiation. Diffuse reflectance spectra (DRS) were recorded using a Cary 5000 UV-Vis-NIR spectrophotometer (VARIAN, USA) equipped with a double out-of-plane Littrow monochromatic using BaSO4 as a standard reference. The luminescence property of the samples were investigated by a high-resolution spectrofluorometer (Edinburgh Instruments FLS920) equipped with a 500 W solar simulator (NBeT, OSR500, China) as excitation source. Long pass (LP) filters (800 nm and 1000 nm) were used to cut off the short wavelength lights of the simulated sunlight source and short pass (SP) filters 990 nm were used to cut off the long wavelength lights of the simulated sunlight sour, which are purchased from Andover Co. USA). The sunlight was focused to a cross section of about 0.25 cm2 using an optical lens. Photocurrent responses of the PV-UC device were measured using an IM6ex electrochemical workstation (Zahner, Germany).
■ RESULTS AND DISCUSSION Figure 2a shows the XRD patterns of the BaCl2: 15mol%Ho3+ and BaCl2: 5mol%Pr3+ samples. The positions and intensities of diffraction peaks match well with the orthorhombic phase of
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BaCl2 (JCPDS NO. 01-72-1388) and no other phase can be identified. It is means that there is no structural change of the orthorhombic phase after doping with Ho3+ or Pr3+ in BaCl2. The SEM images of BaCl2: 15%Ho3+ and BaCl2: 5%Pr3+ show similar morphologies with micron-scale particle size (Figure S7).
The sharp absorption bands around 900 nm, 1157 nm
and 1610 nm are observed in Figure 2b, which is due to the intraconfigurational f-f transitions of Ho3+ from the 5I8 ground state to the 5I5, 5I6 and 5I7 excited states, respectively. The a-Si:H solar cells don't directly respond to NIR photons above 800 nm. Since Ho3+ ion has remarkable absorption bands at around 900 nm, 1157 nm and 1610 nm, the corresponding NIR photons might be efficiently converted to visible light emissions which can be absorbed by the a-Si:H solar cells for the generation of photocurrent.
Figure 2: (a) XRD patterns for samples of BaCl2: 15 mol%Ho3+ and BaCl2: 5 mol% Pr3+; (b) Absorption spectrum of BaCl2: Ho3+ phosphor. Figure 3 shows the UC emission spectra of BaCl2: Ho3+ under excitation of concentrated incoherent NIR light of sunlight (wavelength λ > 800 nm). The UC emissions around 658 nm, 546 nm and 489 nm are attributed to the 5F5→5I8, 5F4→5I8, and 5F2→5I8 transitions of Ho3+, respectively. Clearly, the UC luminescence of the BaCl2: Ho3+ particles strongly depends on the doping concentration of Ho3+ ions. The UC emission intensity reaches a maximum value when Ho3+ ions concentration is 15%. When the Ho3+ ions concentration increases from 0.3% to 28%, more Ho3+ ions become available to furnish the excitation light and result in the
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higher UC emission intensity by ion-ion energy transfer. If the concentration of Ho3+ ions further increased, the emission intensity decreases gradually, this may be ascribed to the concentration-dependent quenching. The dependences of the luminescence intensity of BaCl2: 15 mol%Ho3+ phosphor under NIR light of sunlight (wavelength λ > 800 nm) are presented in Figure 4. The slopes for red (658 nm), green (546 nm) and blue (489 nm) are 0.77, 0.71 and 0.59, respectively. Due to the use of broadband excitation, the slope values are much smaller than the results obtained by single wavelength excitation26, in which the number of photons involved in the UC process is close to observed slopes. The energy transfer mechanism under NIR light of sunlight (wavelength λ > 800 nm) excitation in the BaCl2: 15 mol%Ho3+ phosphor was depicted in Figure 5. The main emissions around at 658 nm may be explained by three main process. The Ho3+ ions after absorption at a 1157 nm photon are promoted first to its excited state (5I6)
and
then to 5F4, 5S2 states though absorb another 1157 nm photon.
The Ho3+ ions in 5F4, 5S2 states then relax to 5F5 states and then to the ground states 5I8, giving the red emissions. Another process is that the Ho3+ ions in 5I6 relax to 5I7 first, and then go to F5 states before finally decay to the ground states (5F5→5I8). In the third process, the Ho3+
5
ions absorb a 900 nm photon and being excited to the 5I5 states and then to the 5F5 states by absorption a 1610 nm photon, afterwards relax to the5I8 state. The green emission comes from the transition of Ho3+ ions between the 5F4, 5S2 state to the ground states (5I8 ) and the blue luminescence is associated with the F2→5I8 transitions. Both of the green and blue emissions are the result the sequential absorption of a 900 nm photon (to the 5I5 state), and an 1157 nm photon (to the 5F2 state). Whereas the cross relaxation between the 5I7→5I6 and 5F4, 5S2 →5F5 of Ho3+ ions contribute to the red UC luminescence. In order to confirm the process of energy transfer, we investigate the UC emission intensity of BaCl2: Ho3+ under excitation by incoherent NIR light (from sunlight) for wavelength 990 nm> λ > 800 nm and λ > 990 nm, respectively (Figure S1 and Figure S3). It is strange that the UC emission around 546 nm is absent under excitation of at wavelength from 800 nm to 990
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nm compared with the spectrum recorded at excitation wavelength of λ > 800 nm. Meanwhile, the UC emission around 486 nm disappeared and the emissions around 765 nm arise at the excitation at wavelength λ > 990 nm. The energy level diagrams of Ho3+ ion involving possible UC processes were shown in the Figure S2 and Figure S4. These results are regarded as the evidences for the energy transfer process (Figure 5).
Figure 3: UC emission spectra of BaCl2: Ho3+ under excitation of by NIR part (wavelength > 800 nm) of sunlight.
Figure 4: Power dependence of UC intensity of BaCl2: 15%Ho3+ measured at 658, 546 nm and 489 nm, respectively.
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Figure 5: shows the energy level diagrams of Ho3+ ion involving possible UC processes. In order to prove the Ln3+ ions doped BaCl2 can generate UC emissions under excitation by broad NIR light from the sun, we optimize the UC emission properties of BaCl2: Pr3+ phosphor and found that
BaCl2: 5%Pr3+ exhibits strongest red UC emission upon excitation
of concentrated incoherent NIR sunlight with wavelength λ > 800 nm (Figure S5). The absorption spectrum of the BaCl2: 5%Pr3+ shows four major peaks located at 850 nm, 980 nm, 1460 nm, 1596 nm, 2000 nm and 2190 nm, which are attributed to the 1G4→3P1+1I6, 3H4→1G4, H4→3F4,3H4→3F3, 3H4→3F2 and 3H4→3H6 transitions of Pr3+ ions, respectively. Possible
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energy level diagrams of Pr3+ ion involving UC processes excitation of incoherent NIR(wavelength λ > 800 nm) from sunlight are depicted in Figure S8. The Pr3+ ions are first excited to the 3P1+1I6 states through multiple ways under excitation by broad NIR light, and then produce UC emissions around 470 nm, 537 nm, 610 nm and 636 nm by transitions of 3P
1+
1I → 3H , 3P → 3H , 3P +1I → 3H , 3P +1I → 3F of 6 4 0 4 1 6 6 1 6 2
Ho3+, respectively. On the other hand,
Pr3+ ions can be also excited to the 1D2 states and then relax to the 3H4 level by phonon-assisted process to give the red emission around 610 nm. The presence of these absorption bands results in the absorption of NIR part of sunlight and the results also suggest that UC emission can be also generated by sunlight excitation in other Ln3+ doped UC
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materials as long as NIR absorption lines are present. As an immediate application of the sunlight generated UC, the BaCl2: Ln3+ phosphor powders are attached to the rear surface of an a-Si: H thin film solar cell for the examination of NIR photoresponse. As depicted in Figure 6, a weak short-circuit current density (Jsc) of 0.1 mA/cm2 is observed when the thin film a-Si: H solar cell is covered with BaCl2 powder, while bare thin film a-Si:H solar cell only shows feeble photoresponse tailing towards 800 nm. Nevertheless, the Jsc of the thin film a-Si: H solar cell coupled with the BaCl2: Ho3+ (15 mol%) and BaCl2: Pr3+ (5 mol%) phosphors strikingly jumps to 0.25 mA/cm2 and 0.16 mA/cm2, respectively. This result demonstrates that the spectral response of the a-Si: H solar cell to incoherent broadband NIR sunlight can be greatly enhanced by using the BaCl2: Ln3+ phosphor due to its highly efficient UC emission. This study is predicted to be of general interest for potential applications in NIR photoresponse devices.
Figure 6: Photocurrent response of a-Si: H solar cell coupled with and without BaCl2: Ho3+ (15mol%)
and BaCl2: Pr3+ (5mol%) phosphor on the rear face of the cell at an applied
potential of 0 V under irradiation of concentrated incoherent NIR sunlight with wavelength λ > 800 nm with 60 s sunlight on/off cycles.
■ CONCLUSION In summary, we have showed that UC emissions of BaCl2: Ho3+ phosphor can be efficiently
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generated by excitation with
incoherent NIR sunlight at wavelength λ > 800 nm, and
explained the related mechanisms of upconversion luminescence. In addition, we demonstrated the notable photoactive current generation from an industrial a-Si: H solar cell attached with the BaCl2: Ln3+ (Ho3+ or Pr3+) and phosphor layer excited by NIR part of sunlight (λ > 800 nm). This new strategy of excitation under incoherent broadband NIR sunlight will open a new avenue towards the applications of upconversion materials in NIR light harvesting devices.
■ ASSOCIATED CONTENT Supporting Information UC emission spectra of BaCl2: Ho3+ under excitation by NIR part (990 nm>wavelengthλ> 800 nm) of sunlight (Figure S1); Energy level diagrams of Ho3+ ion involving possible UC process under excitation of incoherent NIR(990 nm>wavelengthλ> 800 nm) from sunlight (Figure S2); UC emission spectra of BaCl2: Ho3+ under excitation of incoherent NIR(wavelengthλ> 990 nm) from sunlight (Figure S3); Energy level diagrams of Ho3+ ion involving possible UC processes excitation of incoherent NIR(wavelengthλ> 990 nm) from sunlight (Figure S4); UC emission intensity of BaCl2: Pr3+ under excitation of incoherent NIR (wavelengthλ> 800 nm) from sunlight (Figure S5); Absorption spectrum of BaCl2: Pr3+ phosphor (Figure S6); Energy level diagrams of Pr3+ ion involving possible UC processes excitation of incoherent NIR(wavelengthλ> 800 nm) from sunlight (Figure S7); (a) SEM image of BaCl2: 15%Ho3+ and BaCl2: 5%Pr3+ (Figure S8).
■ AUTHOR INFORMATION Corresponding Authors *E-mail:
[email protected] or
[email protected] ( H. Jia). *E-mail:
[email protected] or
[email protected] and Fax: +86 020-87113646 ( J. Qiu). *E-mail:
[email protected] ( Z. Chen).
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Notes The authors declare no competing financial interest.
■ ACKNOWLEDGMENTS This work was financially supported by the National Natural Science Foundation of China (Grants 61404071, 61575091, 61675094, 51132004, 51072054 and 51102209) and the National Basic Research Program of China (2011CB808100), the Natural Science Foundation of Henan Province of China (162300410201), the Henan Provincial Department of Science and Technology Research Project (162102210303), the Fundamental and Cutting-edge Technology Research Program of Henan Province (152300410218), the Key scientific research projects of Henan Province (Grants 16A140014 and 16A140016), the Program for Young Teachers of Higher School in Henan Province (2013GGJS-153), Sponsored by Program for Science and Technology Innovation talents in University of Henan Province (16HASTIT044).
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