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NORTHWESTERN UNIVERSITY. NSF - PREM - MRSEC. Synthesis and Characterization of Rare Earth Nanomaterials and their Biological and Photonic Applications Dhiraj Sardar Department of Physics University of Texas at San Antonio March 10 and 11, 2011. Outline. Introduction to Rare Earths
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NORTHWESTERN UNIVERSITY NSF - PREM - MRSEC Synthesis and Characterization of Rare Earth Nanomaterials and their Biological and Photonic ApplicationsDhiraj SardarDepartment of PhysicsUniversity of Texas at San AntonioMarch 10 and 11, 2011
Outline • Introduction to Rare Earths • Methods • Important Facilities • Results – Theoretical and Experimental • Potential Applications • UTSA Physics Department -PREM • PREM Students • PREM Publications and Acknowledgements
Introduction to Rare Earths Electron charge distribution in different orbitals for RE ions showing the shielding of 4f electrons by outer 5s and 5p electrons Electronic Configuration (RE3+) : Incomplete inner 4fN orbital : [Xe]4fN5s25p6(N=113) Optical Properties : Strong absorption and fluorescence : Wide range of excitation and emission (UV-VIS-IR) Applications : Lasers, Display, Sensor, Therapy, Biomedical imaging, etc. Energy levels of trivalent rare earths (RE3+ )
Methods • 1. Synthesis • Solvothermal/Hydrothermal • Precipitation • Thermolysis • 2. MorphologyCharacterization • XRD, EDX • SEM, TEM, STEM • AFM • 3. Optical Characterization • Refractive Index • Optical Absorption/Reflection/Scattering • Steady State Emission • Fluorescence Lifetime • Optical Gain • Efficiency(Internal, External, Conversion, Slope) • FTIR/Raman
Important Facilities Laser Research Laboratory Lasers: Argon, Nd:YAG, Ti:Sapphire, Diode (Vis-IR) Cary-14 Spectrophotometer SPEX 1250M Monochromator Cryogenic Cryostat Microscopy Laboratory STEM w/EDX HR-TEM w/EDX AFM Raman XRD JEOL-ARM200F(0.06 nm resolution)
RESULTSSTEM imaging of the Nd3+ distribution Nd3+:Sc2O3 • Blue = Scandium , Red = Oxygen
Theoretical (Judd-Ofelt Formalism) Radiative Process: (Judd-Ofelt Model) Major Nonradiative Processes: 1.Multiphonon relaxation (Amp) 2.Energy transfer between ions (AET) 3.Hydroxyl content/High frequency vibrational groups (AOH) 4.Impurity (Aimp) 4F7/2 AET 4S3/2 4F9/2 4I9/2 4I11/2 Amp 4I13/2 980nm Pump 550nm 650nm 1550nm AOH AET 4I15/2 Er3+ Radiative Quantum Efficiency: Arad=radiative decay rate Anr=nonradiative decay rate
Nd3+:Y2O3 Absorptions from Ceramic and Embedded in Polymers Nd3+:Y2O3 Ceramic Nd3+:Y2O3 in Epoxy Nd3+:Y2O3 in HEMA Polymer embedded samples yield similar spectral features to polycrystalline ceramic sample
RE3+:Y2O3 Emissions from Nanoparticles Nanoparticles Epoxy embedded Eu3+:Y2O3 Nd3+:Y2O3
Comparative Results of Nd3+ in polymer, ceramic, and single crystals • *Internal radiative quantum efficiency • a,b,c Sardar et al., Polymer Internationa (2005), J. Appl Phys. (2004, 2005) • d Kumar et al., IEEE J Quant. Elect.(2006) • E Kaminskii, Laser Crystals, (1996) • f Morrison et al., J.Chem. Phys (1983)
Other RE-Doped Materials and their Potential Applications Transparent Nd:YAG Ceramic Nd:YAG Single Crystal Yb,Er :Phosphate Glass Inset:Pr :Phosphate Glass Eu:Y2O3 :HEMA Polymer YbTm YbEr YbEr YbEr SrS:EuDy Eu Tb Eu2+ Eu:Y2O3 nanoparticles (Homogeneous precipitation) Host: La2O2S Top: 980 nm Ex (10mW) Bottom: 320 nm Ex: Up and Down Conversion (Imaging, Display, Therapy, Sensing, Security, Lighting, etc.)
absorption emission What is so Unique about RE (Nd3+) for Biomedical Applications? • Large Stoke’s shift (~500nm) • & strong emission • Multi-frequency absorption & emission • Long fluorescence lifetimes • Optical properties “independent” of size • Nontoxic
Imaging Application of RE Nanoparticles Present technology: Organic Dyes and Quantum Dots Advantages-Highly Fluorescent Disadvantages-UV excitation causes autofluorescence, reducing S/N ratio -Size tunability is needed for quantum dots for proper excitation -Toxicity of the composition, Photobleaching Color tunable Q dots a b • Live cell (mouse fibroblast) image with green upconversion under 980 nm Exc. • (b) Cell autofluorescence under UV Exc. Confocal image of the 980 nm excited Emissions (550 and 670 nm) from Yb,Er:CaF2 Nanoparticles Autofluorescence After background subtraction Future technology: Rare Earth-doped Nanoparticles Advantages-Highly Fluorescent, wide range of excitation and emission (UV-IR), no autofluorescence, nontoxic, no size requirement, no photobleaching
Photodynamic Therapy with IR Upconversion (IPDT) Advantages: IR Upcoversion, 5 times penetration depth compared to Current UV-X PDT
Advanced Engineering and Technology (AET) Building ($82.5M; December 2009) Physics Department occupies the 3rd floor (over 14,000 sq. ft. of lab space) $11.2M spent by UTSA to Renovate Physics Research Laboratories Thin Films Laboratory (AET) ALD, Laser Deposition Biophotonics Research and Imaging Laboratory (AET) Synthesis Labs (AET) Nanomaterials Nanophotonics and Laser Materials Terahertz Laboratory (AET) Computational Physics Laboratories (AET) Access to the Texas Advanced Computing Center (TACC at UT Austin) Advanced Microscopy Laboratory (Science Building) TEM-STEM, SEM, AFM, Raman Including the most advanced spherical aberration corrected STEM (JEOL ARM 200F) UTSA Physics Department- PREM Tenure-track faculty Total: 13; PREM: 7 6 Minority; 3 Women 2 Hispanic Women 1 African American Woman
UTSA PREM Researchers • Dr. Jianhui Yang (2010) • Dr. Ajith Kumar (2011) • Erik Enrique • Joseph Barrios • Edward Khachatryan • Robert C. Dennis • Brian Yust • Leland Page • Kenneth Ramsey • Madhab Pokrhel • Nathan Ray • Francisco Pedraza • Devraj Sandhu • Jesse Salas • Hector Barron-Escobar • Marcus Najera • Gilberto Cassilas Garcia • Zurab Kereselidze
Published or in Press: Chandra, S.*, Francis Leonard Deepak, J. B. Gruber, and D. K. Sardar, “Synthesis, Morphology, and Optical Characterization of Er3+:Y2O3”, J. Chem. PhysicsC, 114, 874-880 (2010). Burdick, G. W., J. B. Gruber, K. L. Nash, and D. K. Sardar, “Analyses of 4f11 Energy Levels and Transition Intensities Between Stark Levels of Er3+ in Y3Al5O12”, Spectroscopy Letters: 43, 406-422 (2010). Gruber, J. B., G. W. Burdick, S. Chandra*, and D. K. Sardar, “Analyses of the Ultraviolet Spectra of Er3+ in Er2O3 and Er3+ in Y2O3”,J. Appl. Phys., 108, 023109: 1-7 (2010). Chandra,S.*, J. B. Gruber, G. W. Burdick, and D. K. Sardar, “Material Fabrication and Crystal-Field Analysis of the Energy Levels in Er3+ doped Er2O3 and Y2O3 Nanoparticles Suspended in PolymethylMethacrylate”, J. Appl. Pol. Sci. (in Press) (2011). Yang, J. and D. K. Sardar, “One-Pot Synthesis of Coral-Shaped Gold Nanostructures for Surface-Enhanced Raman Scattering”, J. Nano Res. (in Press) (2011). Yang, J., R. C. Dennis*, and D. K. Sardar, “Room-Temperature Synthesis of Flowerlike Ag Nanostructures Consisting of Single Ag Nanoplates”, Mater. Res. Bull. (in Press) (2010). B. Yust*, D. K. Sardar, and A. T. Tsin, "Phase conjugating nanomirrors: utilizing optical phase conjugation for imaging", SPIE Proceedings, Vol. 7908 (In Press) (2011). Francis Leonard Deepak, Rodrigo Esparza, Belsay Borges, X. Lopez-Lozano, Miguel Jose Yacaman, Rippled and Helical MoS2Nanowire catalysts– An aberration corrected STEM study. Catalysis Letters, In Press, 2011. Page, L*, Maswadi, S, Glickman, RD, “Optoacoustic Spectroscopic Imaging of Radiolucent Foreign Bodies”, in Medical Imaging 2010: Ultrasonic Imaging, Tomography, and Therapy, D'hooge, J; McAleavey, SA, Eds., Proc. SPIE, Vol. 7629, pp 7629OE-1 – 7629OE-7, 2010. Maswadi*, S, Glickman, RD, Elliott, WR, Barsalou N,. “Nano-Lisa for In Vitro Diagnostic Applications”, in Photons Plus Ultrasound: Imaging and Sensing 2011, Oraevsky AA, Wang LV, Eds, Proc. SPIE, Vol. 7899, in Press, 2011. Page, L*, Maswadi, S, Glickman, RD, “Identification of Radiolucent Foreign Bodies in Tissue Using Optoacoustic Spectroscopic Imaging”, in Photons Plus Ultrasound: Imaging and Sensing 2011, Oraevsky AA, Wang LV, Eds., Proc. SPIE, Vol. 7899, in Press, 2011. Francis Leonard Deepak, G. Casillas-Garcia*, H. Barron*, R. Esparza and M. Jose-Yacaman, New Insights into the structure of Pd-Au nanoparticles as revealed by aberration-corrected STEM”, in Press, 2011 V. H. Romero, W. Egido, Z. Kereselidze*, C. M. Valdez, .E. Michaelides, X. G. Peralta, M. Jose-Yacaman, F. Santamaria. Neurons preferentially internalize goldnanostars with strong and precise photothermal properties. Submitted to Nanomedicine NBM, 2011. X. G. Peralta, “Plasmon modes for terahertz detection: Terahertz Plasmon modes in grating coupled double quantum well field effect transistors”, released by LAP Lambert Academic Publishing (2010-08-30) - ISBN-13 : 978-3-8383-9371-1 (2010). Wilmink, G. J., Rivest, B. D., Roth, C. C., Ibey, B. L., Payne, J. A., Cundin, L. X., Grundt, J. E., Peralta, X., Mixon, D. G. and Roach, W. P. , “In vitro investigation of the biological effects associated with human dermal fibroblasts exposed to 2.52 THz radiation”. Lasers in Surgery and Medicine, n/a. doi: 10.1002/lsm.20960, 2011. J. Antunez-Garcia, S. Mejia-Rosales, E. Perez-Tijerina, J. M. Montejano-Carrizales and M. Jose –Yacaman. “Coallescence and collision of gold nanoparticles”. Materials, 4: 368-379, doi:10.3390/ma4020368, 2011. 16 Published, 4 other papers submitted, and 11 more under preparation All Publications Acknowledge NSF-PREM Support: Grant No. DMR-0934218 PREM Publications (2010-11)