LASER – PHYSICAL PHENOMENA, APPLICATIONS,
OPTICs/ INFRARED -

LASER - PHYSIKALISCHE EFFEKTE, ANWENDUNGEN, OPTIK/INFRAROT

Zhang S.; Holzapfel, W.

Orthogonal Polarization in Lasers – Physical Phenomena and Engineering Applications*
Wiley 2014 ISBN 978-1-118-34651-8 (Adobe PDF) – ISBN 978-1-118-34652-5 (ePub) – ISBN 978-1-118-34653-2 (MobiPocket) – ISBN 978-1-118-34649-5 (cloth) ; Tsinghua University Press 2014, ISBN 978-7-302-34951-8. 434 pages including Foreword, Preface, Introduction, Index and following four Parts:

Holzapfel, W. ; Zhang S.

Fundamentals of Lasers and Beam Polarizations
Part One of ´Orthogonal Polarization in Lasers´, containing: Rigorous Introduction to Lasers and Beam Polarizations (Main Chapter 1), Basic Physical Effects Inside Lasers (Main Chapter 2), Specific Laser Technologies Applicable for Orthogonally 
Polarized Beam Generation (Main Chapter 3); References.

Holzapfel, W.; Zhang S.

Generation of Orthogonal Laser Polarizations
Part Two of ´Orthogonal Polarization in Lasers, containing: Zeeman Dual-Frequency Lasers and Multifrequency Ring Lasers – Orthogonally Polarized Lasers in Tradition (Main Chapter 4), Matrix Theory of Anisotropic Laser Cavities – A Further Approach to Orthogonally Polarized Dual-Frequency Lasers (Main Chapter 5), Orthogonal Polarization and Frequency Splitting in Birefringent Laser Cavities (Main Chapter 6), Design of Orthogonally Polarized Lasers (Main Chapter 7); References.

Zhang S.; Holzapfel, W.

Nonlinear Behavior of Orthogonally Polarized Lasers
Part Three of ´Orhogonal Polarization in Lasers´, containing: Competition and Flipping Phenomena in Orthogonally Polarized Lasers (Main Chapter 8), Optica Feedback Effects in Orthogonally Polarized Lasers (Main Chapter 9), Semi- classical Theory of Orthogonally Polarized Lasers (Main Chapter 10); References

Zhang S. ; Holzapfel, W.

Applications of Orthogonally Polarized Lasers
Part Four of ´Orhogonal Polarization in Lasers´, containing: Introduction and Background of Applications (Main Chapter11), Measurements of Optical Anisotropies by Orthogonally Polarized Lasers (Main Chapter 12), Displacement Measurement by Orthogonally Polarized Lasers (Main Chapter 13), Force and Pressure Measurement by Means of Photoelastic Nd:YAG Lasers (Main Chapter 14), Measurements via Translation/Rotation of Intracavity Quartz Crystals (Main Chapter 15), Combined Magnetometer/Rate Gyro Transducers by Four-Frequency Ring Lasers (Main Chapter 16), Further Applications of Orthogonally Polarized Lasers (Main Chapter 17), Conclusions of Part Four (Main Chapter 18), References.

Liu W., Zhu J., Holzapfel W., Zhang S.

Differential variation of laser longitudinal modes spacing induced by small intracavity phase anisotropy
Opt. Communication. 282 (8), 1602–1606, 2009

Pfeifer, T.; Holzapfel, W. (editors)

Proceedings of the International Symposium “Photonics in Measurement”
VDI-Berichte 1694, Düsseldorf 2002, ISBN 3-8322-0639-6-X

Neuschaefer-Rube, St.; Holzapfel, W.; Hou, L.

Signal Properties of Monolithic Nd:YAG Lasers. Proceedings of XVI IMEKO World Congress, Sep 25-28, 2000, Vienna, Austria, Vol. II: Education and Training in Measurement and Instrumentation, Photonic Measurement, Micro and Nano Technology, pp. 243-248, ISBN 3-901888-04-7

Holzapfel, W.; Braasch, J. C.; Neuschaefer-Rube, St.

Wavelength determination of semiconductor lasers – precise but inexpensive.
Optical Engineering 34, 5, pp. 1417-1420, (1995)

Holzapfel, W.; Luxem, W.; Settgast, W.

A thermal phase-locked loop for frequency stabilization of internal mirror He-Ne lasers (λ=0.633 μm): Comment
Review of Scientific Instruments 64, 8, pp. 2407-2408 (1993)

Braasch, J.; Holzapfel, W.

Frequency Stabilization of Monomode Semiconductor Lasers to Birefringent Resonators
Electronics Letters 28, 9, pp. 849-850 (1992)

Holzapfel, W.; Luxem, W.; Settgast, W.

Stabilization of Single Frequency Internal Mirror He-Ne Lasers: Comment
Applied Optics 29, 27, pp. 3877-3878 (1990)

Holzapfel, W.

Lasermeßtechnik - Anwendungsbeispiele und Perspektiven
Optik 81, 2, S. 65-76 (1989)

Bolzmann, B.; Holzapfel, W.

Anordnung zur Aufnahme eines Wärmebildes
Deutsche Patentschrift DE 2940536 C2, erteilt 1982; Britische Patentschrift 2.095.069, Französische Patentschrift 2.502.437

Herziger, G.; Holzapfel, W.; Seelig, W.

Verstärkungsfaktor des Laserüberganges 6328 AE einer He-Ne-Gasentladung – Theorie und Experiment
Physikalische Verhandlungen VI, 2, p. 158 (1967)

Herziger, G.; Holzapfel, W.; Seelig, W.

Berechnung und experimenteller Vergleich des Verstärkungsfaktors für den Laserübergang 6328 AE in einer He-Ne-Gasentladung
The Europian Physical Journal (ISSN 1434-601X) 200, p. 103-116 (1967), vormals ´Zeitschrift für Physik´

Herziger, G.; Holzapfel, W.; Seelig, W.

Verstärkung einer He-Ne-Gasentladung für die Laserwellenlänge λL = 6328 AE
The Europian Physical Journal (ISSN 1434-601X) 189, pp. 385-400 (1966), vormals ´Zeitschrift für Physik´

Herziger, G.; Holzapfel, W.; Seelig, W.

Verstärkung der roten Laserlinie 6328 AE durch eine He-Ne-Gasentladung
Phys. Verhandlungen 4, 2, p. 58 (1964)