Power Scaling of Enhancement Cavities for Nonlinear Optics [electronic resource] /by Ioachim Pupeza.
by Pupeza, Ioachim [author.]; SpringerLink (Online service).
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BookSeries: Springer Theses, Recognizing Outstanding Ph.D. Research: Publisher: New York, NY : Springer New York, 2012.Description: X, 96p. 35 illus., 32 illus. in color. online resource.ISBN: 9781461441007.Subject(s): Physics | Optical materials | Physics | Quantum Optics | Laser Technology, Photonics | Optical and Electronic Materials | Optics, Optoelectronics, Plasmonics and Optical DevicesDDC classification: 535.15 Online resources: Click here to access online | Item type | Current location | Call number | Status | Date due | Barcode |
|---|---|---|---|---|---|
| MAIN LIBRARY | QC173.96-174.52 (Browse shelf) | Available |
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| QA370-380 From Fourier Analysis and Number Theory to Radon Transforms and Geometry | QA241-247.5 Ramanujan's Lost Notebook | QB1-991 In Search of William Gascoigne | QC173.96-174.52 Power Scaling of Enhancement Cavities for Nonlinear Optics | HB135-147 Risk and Portfolio Analysis | QA71-90 Applications of Mathematics and Informatics in Military Science | RC434.2-574 Autism and the Brain |
Theoretical Background -- Objectives of the Experiment and Technological Challenges -- Experimental Setup and Results -- Outlook.
Enhancement cavities are passive optical resonators in which continuous-wave laser radiation or pulses of a frequency comb are coherently overlapped, allowing for a power and intensity scaling of up to several orders of magnitude. A prominent application is the table-top generation of bright, laser-like radiation in spectral regions where direct laser action is inefficient or not available at all, via intracavity nonlinear optical processes. However, to exploit the full capacity of this technique further progress is needed. This thesis covers central problems of enhancement cavities, such as finding limitations in scaling the circulating power, measuring cavity parameters with high accuracy, tailoring transverse modes and coupling out radiation generated in the cavity. Unprecedented intracavity laser powers were demonstrated, surpassing previous results by an order of magnitude. As an application, harmonics of the fundamental 1040-nm radiation up to the 21st order are generated. Besides reporting these fine experimental results, the thesis provides an excellent introduction into the physics of enhancement cavities, supported by more than 140 references.
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