Pulsed Laser Deposition

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Robert W. Eason - One of the best experts on this subject based on the ideXlab platform.

  • Dataset for Engineering of thin crystal layers grown by Pulsed Laser Deposition
    2016
    Co-Authors: James A. Grant-jacob, Stephen J Beecher, J I Mackenzie, Tina L. Parsonage, Ping Hua, David Shepherd, Robert W. Eason
    Abstract:

    Data associated with SPIE Photonics Europe Proceedings paper "Engineering of thin crystal layers grown by Pulsed Laser Deposition".

  • Pulsed Laser Deposition of YIG and Ti:sapphire
    2011
    Co-Authors: A. Sposito, Timothy C. May-smith, Robert W. Eason
    Abstract:

    Pulsed Laser Deposition (PLD) is a versatile film growth method that has been proven successful in the growth of Ti:sapphire and garnets for Laser applications.

  • Pulsed Laser Deposition of thin films applications led growth of functional materials
    2006
    Co-Authors: Robert W. Eason
    Abstract:

    SECTION I. 1. Pulsed Laser Deposition of Complex Materials: Progress Towards Applications (D. Norton). SECTION II. 2. Resonant Infrared Pulsed Laser Ablation and Deposition of Thin Polymer Films (D. Bubb & R. Haglund). 3. Deposition of Polymers and Biomaterials Using the Matrix Assisted Pulsed Laser Eveporation (MAPLE) Process (A. Pique). 4. In situ Diagnostics by High Pressure RHEED during PLD (G. Rijnders & D. Blank). 5. Ultra-fast Laser Ablation and Film Deposition (E. Gamaly, et al.). 6. Cross-beam PLD: Metastable Film Structures from Intersecting Plumes (A. Gorbunoff). 7. Combinatorial Pulsed Laser Deposition (I. Takeuchi). 8. Growth Kinetics During Pulsed Laser Deposition (G. Rijnders & D. Blank). 9. Large Area Commercial Pulsed Laser Deposition (J. Greer). SECTION III. 10. Coating Powders for Drug Delivery Systems Using Pulsed Laser Deposition (J. Talton, et al.). 11. Transparent Conducting Oxide Films (H. Kim). 12. ZnO and ZnO-related Compounds (J. Perriere, et al.). 13. Group III Nitride Growth (D. O'Mahony & J. Lunney). 14. Pulsed Laser Deposition of High-Temperature Superconducting Thin Films and Their Applications (B. Schey). 15. DLC: Medical and Mechanical Applications (R. Narayan). 16. Pulsed Laser Deposition of Metals (H. Krebs). SECTION IV. 17. Optical Waveguide Growth and Applications (R. Eason, et al.). 18. Biomaterials: New issues and Breakthroughs for Biomedical Applications (V. Nelea, et al.). 19. Thermoelectric Materials (A. Dauscher & B. Lenoir). 20. Piezoelectrics (F. Cracium & M. Dinescu). 21. Ferroelectric Thin Films for Microwave Device Applications (C. Chen & J. Horwitz). 22. Films for Electrochemical Applications (M. Montenegro & T. Lippert). 23. Pulsed Laser Deposition of Tribological Coatings (A. Voevodin, et al.). SECTION V. 24. Laser Ablation Synthesis of Single-wall Carbon Nanotubes: The SLS Model (A. Gorbunoff & O. Jost). 25. Quasicrystalline Thin Films (P. Willmott).

  • Pulsed Laser Deposition of Thin Films: Applications-Led Growth of Functional Materials - Pulsed Laser Deposition of thin films : applications-led growth of functional materials
    2006
    Co-Authors: Robert W. Eason
    Abstract:

    SECTION I. 1. Pulsed Laser Deposition of Complex Materials: Progress Towards Applications (D. Norton). SECTION II. 2. Resonant Infrared Pulsed Laser Ablation and Deposition of Thin Polymer Films (D. Bubb & R. Haglund). 3. Deposition of Polymers and Biomaterials Using the Matrix Assisted Pulsed Laser Eveporation (MAPLE) Process (A. Pique). 4. In situ Diagnostics by High Pressure RHEED during PLD (G. Rijnders & D. Blank). 5. Ultra-fast Laser Ablation and Film Deposition (E. Gamaly, et al.). 6. Cross-beam PLD: Metastable Film Structures from Intersecting Plumes (A. Gorbunoff). 7. Combinatorial Pulsed Laser Deposition (I. Takeuchi). 8. Growth Kinetics During Pulsed Laser Deposition (G. Rijnders & D. Blank). 9. Large Area Commercial Pulsed Laser Deposition (J. Greer). SECTION III. 10. Coating Powders for Drug Delivery Systems Using Pulsed Laser Deposition (J. Talton, et al.). 11. Transparent Conducting Oxide Films (H. Kim). 12. ZnO and ZnO-related Compounds (J. Perriere, et al.). 13. Group III Nitride Growth (D. O'Mahony & J. Lunney). 14. Pulsed Laser Deposition of High-Temperature Superconducting Thin Films and Their Applications (B. Schey). 15. DLC: Medical and Mechanical Applications (R. Narayan). 16. Pulsed Laser Deposition of Metals (H. Krebs). SECTION IV. 17. Optical Waveguide Growth and Applications (R. Eason, et al.). 18. Biomaterials: New issues and Breakthroughs for Biomedical Applications (V. Nelea, et al.). 19. Thermoelectric Materials (A. Dauscher & B. Lenoir). 20. Piezoelectrics (F. Cracium & M. Dinescu). 21. Ferroelectric Thin Films for Microwave Device Applications (C. Chen & J. Horwitz). 22. Films for Electrochemical Applications (M. Montenegro & T. Lippert). 23. Pulsed Laser Deposition of Tribological Coatings (A. Voevodin, et al.). SECTION V. 24. Laser Ablation Synthesis of Single-wall Carbon Nanotubes: The SLS Model (A. Gorbunoff & O. Jost). 25. Quasicrystalline Thin Films (P. Willmott).

C. H. Woo - One of the best experts on this subject based on the ideXlab platform.

  • Monte Carlo simulation of Pulsed Laser Deposition
    Physical Review B, 2002
    Co-Authors: P M Lam, Shen Jung Liu, C. H. Woo
    Abstract:

    Using the Monte Carlo method, we have studied the Pulsed Laser Deposition process at the submonolayer regime. In our simulations, dissociation of an atom from a cluster is incorporated. Our results indicate that the Pulsed Laser Deposition resembles molecular-beam epitaxy at very low intensity, and that it is characteristically different from molecular-beam epitaxy at higher intensity. We have also obtained the island size distributions. The scaling function for the island size distribution for Pulsed Laser Deposition is different from that of molecular-beam epitaxy.

R W Eason - One of the best experts on this subject based on the ideXlab platform.

  • ytterbium doped garnet crystal waveguide Lasers grown by Pulsed Laser Deposition
    Optical Materials Express, 2017
    Co-Authors: Stephen J Beecher, James Grantjacob, Jake J Prentice, R W Eason, D P Shepherd, J I Mackenzie
    Abstract:

    The growth of a range of crystal garnets by Pulsed Laser Deposition is presented. As a result of optimization of the fabrication process, films can now be grown with optical quality approaching that of bulk material. To demonstrate this, we present Laser performance from a Yb:YAG film with 70% slope efficiency and >16 W of output power. In addition, we present the first Pulsed Laser Deposition of Laser quality Yb:GGG and Yb:YGG. Watt-level Laser performance is achieved for these two gallium garnets and routes to further performance improvements and potential applications of these films are discussed.

  • an 11 5 w yb yag planar waveguide Laser fabricated via Pulsed Laser Deposition
    Optical Materials Express, 2016
    Co-Authors: James A Grantjacob, Stephen J Beecher, D P Shepherd, Tina L. Parsonage, Ping Hua, J I Mackenzie, R W Eason
    Abstract:

    We present details of the homo-epitaxial growth of Yb:YAG onto a oriented YAG substrate by Pulsed Laser Deposition. Material characterization and initial Laser experiments are also reported, including the demonstration of Laser action from the 15 µm-thick planar waveguide generating 11.5 W of output power with a slope efficiency of 48%. This work indicates that under appropriate conditions, high-quality single-crystal Yb:YAG growth via Pulsed Laser Deposition is achievable with characteristics comparable to those obtained via conventional crystal growth techniques.

Stephen J Beecher - One of the best experts on this subject based on the ideXlab platform.

  • ytterbium doped garnet crystal waveguide Lasers grown by Pulsed Laser Deposition
    Optical Materials Express, 2017
    Co-Authors: Stephen J Beecher, James Grantjacob, Jake J Prentice, R W Eason, D P Shepherd, J I Mackenzie
    Abstract:

    The growth of a range of crystal garnets by Pulsed Laser Deposition is presented. As a result of optimization of the fabrication process, films can now be grown with optical quality approaching that of bulk material. To demonstrate this, we present Laser performance from a Yb:YAG film with 70% slope efficiency and >16 W of output power. In addition, we present the first Pulsed Laser Deposition of Laser quality Yb:GGG and Yb:YGG. Watt-level Laser performance is achieved for these two gallium garnets and routes to further performance improvements and potential applications of these films are discussed.

  • Dataset for Engineering of thin crystal layers grown by Pulsed Laser Deposition
    2016
    Co-Authors: James A. Grant-jacob, Stephen J Beecher, J I Mackenzie, Tina L. Parsonage, Ping Hua, David Shepherd, Robert W. Eason
    Abstract:

    Data associated with SPIE Photonics Europe Proceedings paper "Engineering of thin crystal layers grown by Pulsed Laser Deposition".

  • an 11 5 w yb yag planar waveguide Laser fabricated via Pulsed Laser Deposition
    Optical Materials Express, 2016
    Co-Authors: James A Grantjacob, Stephen J Beecher, D P Shepherd, Tina L. Parsonage, Ping Hua, J I Mackenzie, R W Eason
    Abstract:

    We present details of the homo-epitaxial growth of Yb:YAG onto a oriented YAG substrate by Pulsed Laser Deposition. Material characterization and initial Laser experiments are also reported, including the demonstration of Laser action from the 15 µm-thick planar waveguide generating 11.5 W of output power with a slope efficiency of 48%. This work indicates that under appropriate conditions, high-quality single-crystal Yb:YAG growth via Pulsed Laser Deposition is achievable with characteristics comparable to those obtained via conventional crystal growth techniques.

P M Lam - One of the best experts on this subject based on the ideXlab platform.

  • Monte Carlo simulation of Pulsed Laser Deposition
    Physical Review B, 2002
    Co-Authors: P M Lam, Shen Jung Liu, C. H. Woo
    Abstract:

    Using the Monte Carlo method, we have studied the Pulsed Laser Deposition process at the submonolayer regime. In our simulations, dissociation of an atom from a cluster is incorporated. Our results indicate that the Pulsed Laser Deposition resembles molecular-beam epitaxy at very low intensity, and that it is characteristically different from molecular-beam epitaxy at higher intensity. We have also obtained the island size distributions. The scaling function for the island size distribution for Pulsed Laser Deposition is different from that of molecular-beam epitaxy.

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