![]() A different experiment would have to be carried out. However, the two formulas above could not give either the charge or the mass by itself. Just below are GIFs of each formula.īy carrying out the experiments and measuring the proper values, he could calculate what the charge-to-mass (e/m) ratio was for the cathode ray. Thomson had developed formulas based on the deflection of the cathode ray by the electric field and by the magnetic field. (May 1996: This will be made a link when that section is written.)įor a fuller discussion of the below, please see "The Discovery of Subatomic Particles" by Steven Weinberg. Knowledge of the value of 'e' or of 'm' would be needed to get to the other once you knew e/m, which Thomson did know.Įlsewhere you will find discussion of how the value for 'e,' the charge on the electron was determined. The e/m ratio is important because that is as far as Thomson could get with his cathode ray tubes. Reversing the above figures and using grams rather than kilograms gives a value of 5.686 x 10 -9 g/C. Many textbooks and articles use the m/e ratio, that is the mass-to-charge ratio. Often, books round off the 1.759 portion to 1.76. Usually, grams are used rather than kilograms giving a numerical value of 1.759 x 10 8. Therefore, the modern value for the e/m ratio is 1.759 x 10 11 C/kg. ![]() The modern value for the charge on the electron (to four significant places) is 1.602 x 10 -19 coulombs and the electrons mass is 9.109 x 10 -31 kilograms. The cathode rays bend toward the positive pole, confirming that cathode rays is negatively charged.Į/m ratio stands for charge-to-mass ratio of the electron. Thomson is the first individual to succeed in deflecting the cathode ray with an electrical field. The discovery of this effect in 1855 predates by some ten years the unification of electricity and magnetism by James Clerk Maxwell.Ĥ) Although there was some speculation that the cathode rays were negatively charged, it is not shown to be true by experiment until 1895, just two years before Thomson announces the electron.ĥ) J.J. This showed that the cathode ray carried energy and could do work.ģ) The cathode ray is deflected from a straight line path by a magnetic field, suggesting that the two were related in some way. This showed that the cathode rays traveled in straight lines.Ģ) The cathode ray can push a small paddle wheel up an incline, against the force of gravity. Thomson was awarded the Nobel prize in 1906 for discovering the fundamental particle electron.There were a number of results gathered over the years by cathode ray tube researchers.ġ) If an object is placed in the path of the cathode ray, a shadow of the object is cast on the glowing tube wall at the end.The mass of the electron is 9.1094 x 10 -³¹ kg. With Thomson’s mass to charge ratio and charge on a single electron, Millikan calculated the mass of an electron.According to him, the charge of a single electron was 1.6 x 10 -19 Coulomb. He made use of electrically charged oil droplets to calculate the charge on a single electron. The charge of the electron was determined by an American scientist named Robert Millikan.As a result of Thomson’s experiments, a new model of the atom was later developed to understand the structure of an atom. Thomson’s experiments were recognized and widely accepted and his cathode ray particles were known as electrons.These negatively charged particles are found in every atom.ĭiscovery of Electron: Some Important Points. ![]() The mass of each particle was only equivalent to 1/2000 the mass of a hydrogen atom.Cathode rays are composed of negatively charged particles and they travel in a straight line.The conclusions drawn by Thomson through his experiments were as follows: ![]()
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