Problem 4.3: Determine charge to mass ratio of unknown particle 2 ++ X х x x х X X X X x х X х х Χ Χ Χ Χ Χ Χ Χ Χ х х X х

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Please answer question A and B
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Problem 4.3: Determine charge to mass ratio of unknown particle 2 ++ X х x x х X X X X x х X х х Χ Χ Χ Χ Χ Χ Χ Χ х х X х х х Χ Χ Χ х х х х x х X х х х x x X х х Х x x x x x B = 0.1 T X X X х х х x х х х х х х X X X X X х X X X X X Х x x х х х х х X x х х х х x x x x x х x x X X X X X X X X collision Electric field = 100 kV / m Set value and play The animation shows a charged particle traveling first through a region where there are electric and magnetic fields. You can change the value of the electric field (between 0 and 200 kV/m). The magnetic field is 0.1 T in that region as well as the region to the right where there is no electric field (position is given in mm, 10-3 m). Restart. a. What is the velocity of the particle as it passes through the region of crossed electric and magnetic fields? b. What is the charge to mass ratio of this particle (it is not an electron)?
Physlet® Quantum Physics An Interactive Introduction O.Preface I. Introduction II. Special Relativity III. Need for a Quantum Theory Problem 4.3: Determin + + + X х x x Home » The Need for a Quantum Theory » From Blackbody to Bohr Chapter 4: From Blackbody to Bohr # Sections Problems 4.1: What is the temperature of the object? 4.2: Rank the objects according to their temperatures 4.3: Determine charge to mass ratio of unknown particle 4.4: Determine the charge on a drop in the Millikan Oil Drop Apparatus 4.5: Find the distance of closet approach in Rutherford Scattering 4.6: Determine the charge of the nucleus in a Rutherford Scattering Experiment 4.7: A Bohr atom undergoes a transition 4.8: Energy level transitions matched with spectral lines 4.9: Identify the absorption spectrum of hydrogen
Χ Χ Χ Χ Χ Χ Χ Χ Χ Χ Χ х х x x x x x x x x x x x х X x x x x X х х х x x х х x x x х х x x X X X X х B = 0.1 T X X X X X X Х х х x x х х х х x x х х x x x x x x x X х x x x x X х X X x x X х x x х x х х х x x x x x x X X X x х +0.2 ,-2 collision Electric field = 50 kV / m Set value and play
C +++ X х X X X X X x x x x х X x x *X X X X X X X X X X X X x x x x x х x x x x х х x x x x х х х x x x х X х B = 0.1 T Χ Χ Χ x x х х х х Х х х X X х X х х X X X X X X х X X X х х х X х X х х x x X X х х x x x x x x X X X X +4.8 ,-2 collision Electric field = 100 kV / m Set value and play
1 Ic IC 16 х + + X X X X X X X x x x x X X X X X X X X х X х X х X X X х X х X х X х XX х х X X X X х х X X X X X B = 0.1 T X X X X х K х X x х X x х x x X X X х X X X X х X х х х х X X X X х х X X X X X Х x x X X X X x x х +10.4 , -35.2 collision Electric field = 150 kV / m Set value and play
Χ Χ Χ Χ Χ Χ Χ Χ Χ Χ Χ х Χ Χ Χ Χ Χ Χ Χ Χ Χ x x х X X X x x x Х х х X х х х x х х Χ Χ Χ х х Х Χ Χ Χ Χ х B = 0.1 T X X X X X X х х x x х х х X X х х х X X х Х х х x x х х X X х х х X х х x x х х х х X X X X X X X X X X collision +5.4 , +2 Electric field = 200 kV / m Set value and play