The division and bending of green and red semiconductor laser light at the same time
Author(s)
Remzi Yıldırım
ABSTRACT
In this experimental study, the laser light was split and bended using a specially designed glass lenses at the same time. This process has been done at the atmospheric pressure and room temperature conditions. During the experiments, the semiconductor laser as a source of green and red laser diode is used. In addition, polari- zation, magnetic field, electric field or any other auxiliary materials and systems which affect laser light are not used to bend the laser light. Only transparent glass lenses that are designed specially are used in the experimental study.
In this experimental study, the laser light was split and bended using a specially designed glass lenses at the same time. This process has been done at the atmospheric pressure and room temperature conditions. During the experiments, the semiconductor laser as a source of green and red laser diode is used. In addition, polari- zation, magnetic field, electric field or any other auxiliary materials and systems which affect laser light are not used to bend the laser light. Only transparent glass lenses that are designed specially are used in the experimental study.
Cite this paper
Yıldırım, R. (2011) The division and bending of green and red semiconductor laser light at the same time. Natural Science, 3, 889-894. doi: 10.4236/ns.2011.310114.
Yıldırım, R. (2011) The division and bending of green and red semiconductor laser light at the same time. Natural Science, 3, 889-894. doi: 10.4236/ns.2011.310114.
References
[1] Brown, K. (2009) Relativity on reflectivity. Cambridge, London. [2] Goca, N. (1996) Optics. Culture Press, Erzurum. [3] Ghatak, A. (1986) Optics. Tata McGraw Hill, New Delhi. [4] Hecth, E. (2002) Optics. 4th Edition, Addison Wesley, Boston. [5] Yariv, A. (1989) Quantum electronics. 3th Edition, John Wiley and Sons, New York. [6] Verdeyen, J.T. (2000) Laser electronics. Prentice Hall Inc., Upper Saddle River. [7] Weinberg, S. (1983) The discovery of subatomic particle. Luis Weinberg and Weinabet Weinberg Trust, Cam- bridge. [8] Greene, B.R. (1999) Superstrings hidden dimensions, and the quest for the ultimate theory. Norton, New York. [9] Weinberg, S. (1992) Dreams of a final theory. Pantheon, New York. [10] Kane, G. (2000) Supersymmetry/squarks, photinos, and the unveiling of the ultimate laws of nature. Parseus Books Group, New York. [11] Greene, B. (2009) Fabric of cosmos. Penguin Press Science, New York. [12] Feynman, R. (1988) QED: The strange theory of light and matter. Princeton University Press, Princeton. [13] Hoddeson, L., Brown, L., Riondan, M. and Dressen, M. (1997) The rise of standart model. Cambridge University Press, Cambridge. doi:10.1017/CBO9780511471094 [14] Witten, E. (2001) Is supersymmetry really broken? hep-th/9409111, IASSNS-HEP-94-72. [15] Di S.R. Notes on the conceptual of supersymmetry. Stony Brook, N. State Uni. ITP-SB-8878, New York. [16] Feynman, R. (1988) Superstrings: A theory of everything? Cambridge University Press, Cambridge. [17] Nambu, Y. (1985) Quarks frontiers in elementary particle physics. World Scientific Pub. Co. Pte. Ltd, Singapore City. [18] Raman, V.C. (1999) Nobel lectures. Physics 1922-1941, Elsevier Publishing Company, New York. [19] Higgs, P.W. (1964) Broken symmetries and the masses of gauge bosons. Physical Review Letters, 13, 508-509. doi:10.1103/PhysRevLett.13.508 [20] Higgs, P.W. (1964) Broken symmetries massless particles and gauge fields. Physical Letters, 12, 132-133. doi:10.1016/0031-9163(64)91136-9
[1] Brown, K. (2009) Relativity on reflectivity. Cambridge, London. [2] Goca, N. (1996) Optics. Culture Press, Erzurum. [3] Ghatak, A. (1986) Optics. Tata McGraw Hill, New Delhi. [4] Hecth, E. (2002) Optics. 4th Edition, Addison Wesley, Boston. [5] Yariv, A. (1989) Quantum electronics. 3th Edition, John Wiley and Sons, New York. [6] Verdeyen, J.T. (2000) Laser electronics. Prentice Hall Inc., Upper Saddle River. [7] Weinberg, S. (1983) The discovery of subatomic particle. Luis Weinberg and Weinabet Weinberg Trust, Cam- bridge. [8] Greene, B.R. (1999) Superstrings hidden dimensions, and the quest for the ultimate theory. Norton, New York. [9] Weinberg, S. (1992) Dreams of a final theory. Pantheon, New York. [10] Kane, G. (2000) Supersymmetry/squarks, photinos, and the unveiling of the ultimate laws of nature. Parseus Books Group, New York. [11] Greene, B. (2009) Fabric of cosmos. Penguin Press Science, New York. [12] Feynman, R. (1988) QED: The strange theory of light and matter. Princeton University Press, Princeton. [13] Hoddeson, L., Brown, L., Riondan, M. and Dressen, M. (1997) The rise of standart model. Cambridge University Press, Cambridge. doi:10.1017/CBO9780511471094 [14] Witten, E. (2001) Is supersymmetry really broken? hep-th/9409111, IASSNS-HEP-94-72. [15] Di S.R. Notes on the conceptual of supersymmetry. Stony Brook, N. State Uni. ITP-SB-8878, New York. [16] Feynman, R. (1988) Superstrings: A theory of everything? Cambridge University Press, Cambridge. [17] Nambu, Y. (1985) Quarks frontiers in elementary particle physics. World Scientific Pub. Co. Pte. Ltd, Singapore City. [18] Raman, V.C. (1999) Nobel lectures. Physics 1922-1941, Elsevier Publishing Company, New York. [19] Higgs, P.W. (1964) Broken symmetries and the masses of gauge bosons. Physical Review Letters, 13, 508-509. doi:10.1103/PhysRevLett.13.508 [20] Higgs, P.W. (1964) Broken symmetries massless particles and gauge fields. Physical Letters, 12, 132-133. doi:10.1016/0031-9163(64)91136-9