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References

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2. Arora, C. L. (2013). "38. Photoelectric Effect". B.Sc. Practical Physics (21st ed.). Ram Nagar, New Delhi, India: S. Chand Publishing. p. 393. ISBN 81-219-0909-0. Alkali metals like sodium, potassium, and cesium emit electrons even when visible light falls on them, whereas zinc, cadmium, etc. are sensitive only to ultra-violet light.
3. Asimov, Isaac (1966). "4. Electrons Within Atoms". Understanding Physics (Volume III): The Electron, Proton, and Neutron. United States: New American Library. p. 54. ISBN 978-0451626349. When Hertz was experimenting with radio waves during the 1800s, he found that he could elicit a spark from his radio-wave detector more easily if light fell upon the metal points giving out the spark.
4. Wheaton, Bruce R. (1978). "Philipp Lenard and the Photoelectric Effect, 1889-1911". Historical Studies in the Physical Sciences. 9: 299–322. doi:10.2307/27757381. ISSN 0073-2672. Philipp Lenard discovered in 1902 that the maximum velocity with which electrons leave a metal plate after it is illuminated with ultra violet light is independent of the intensity of the light.
5. "The Nobel Prize in Physics 1921 | Summary". nobelprize.org. Nobel Foundation. The Nobel Prize in Physics 1921 was awarded to Albert Einstein "for his services to Theoretical Physics, and especially for his discovery of the law of the photoelectric effect."
6. Verma, H. C. (2013). "42. Photoelectric Effect and Wave–Particle Duality". Concepts of Physics (Volume 2). New Delhi, India: Bharati Bhawan Publishers & Distributors. p. 356. ISBN 8177092324. Threshold wavelength and threshold frequency depend on the metal used.
7. "Photoelectric effect". Encyclopædia Britannica. Retrieved January 21, 2021. Consideration of these unexpected behaviours led Albert Einstein to formulate in 1905 a new corpuscular theory of light in which each particle of light, or photon, contains a fixed amount of energy, or quantum, that depends on the light's frequency.
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12. "Hans Lippershey". Encyclopædia Britannica. Retrieved January 18, 2021. Hans Lippershey, [...] spectacle maker from the United Netherlands, traditionally credited with inventing the telescope (1608).
13. Stark, Glenn. "Early particle and wave theories | Light". Encyclopædia Britannica. Retrieved January 18, 2021. In La Dioptrique (1637), French philosopher-mathematician René Descartes described light as a pressure wave transmitted at infinite speed through a pervasive elastic medium. The prominent English physicist Robert Hooke studied diffraction effects and thin-film interference and concluded in Micrographia (1665) that light is a rapid vibration of any medium through which it propagates. In his Traité de la Lumière (1690; "Treatise on Light"), the Dutch mathematician-astronomer Christiaan Huygens formulated the first detailed wave theory of light, in the context of which he was also able to derive the laws of reflection and refraction. The most prominent advocate of a particle theory of light was Isaac Newton. [...] He struggled with a formulation of the nature of light, ultimately asserting in Opticks (1704) that light consists of a stream of corpuscles, or particles.
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36. Enders, Felicity Boyd. "Coefficient of determination". Encyclopædia Britannica. Retrieved January 17, 2021. More specifically, R^2 indicates the proportion of the variance in the dependent variable (Y) that is predicted or explained by linear regression and the predictor variable (X, also known as the independent variable).
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