The magnetic field has a strength of B= 0.15T and the detector is located a distance of 0.16m from the ion source This means the ions travel in a circle of radius 0.08m.
A singly ionized atom of unknown mass moves at a speed of 2.07 x 10^4 m/s through the magnetic field. Determine the magnetic force acting on the ion.
Determine the mass of the ion
What is the value of the potential difference
The magnetic field has a strength of B= 0.15T and the detector is located a distance...
A singly charged ion of unknown mass moves in a circle of radius 12.5 cm in a magnetic field of 9.0 T. The ion was accelerated through a potential difference of 7.0 kV before it entered the magnetic field. What is the mass of the ion? ___kg
How does changing the magnetic field strength in a magnetic sector mass spectrometer affect which ions reach the detector? answers are: increase in magnetic field strength = ions with larger m/z reaching the detector, increase in magnetic field strength = ions with smaller m/z reaching the detector, or decrease in magnetic field strength = ions with larger m/z reaching the detector How does changing the accelerating voltage in a magnetic sector mass spectrometer affect which ions reach the detector? answers...
A proton, traveling with a velocity of 3.1 × 106 m/s due east, experiences a magnetic force that has a maximum magnitude of 6.6 × 10-14 N and direction of due south. What are the magnitude and direction of the magnetic field causing the force? If the field is up, then enter a number greater than zero. If the field is down, then enter a number less than zero. An α-particle has a charge of +2e and a mass of...
The electric field between the plates of the capacitor shown in
the figure below is 1.12 !105 N / m and the applied magnetic field
is everywhere 0.54T. Once leaving the electric field region, a
stream of singly ionized selenium ions moves in a circular path
with a radius of 31cm in the magnetic field. (a) Copy the figure
below onto your paper, and draw in the electric field corresponding
to the given situation, as well as the electric force...
Can you please help me these two problems. thanks
7.-11 points CJ10 21.P.017 My Notes Ask Your Teacher when beryllium 7 ions m 1.165 x 10-26 kg) pass through a mass spectrometer, a uniform magnetic field of 0.3481 T curves their path directly to the center accelerating potential difference, what magnetic field should be used to send beryllium 10 ions m-1 663 10 26 kg) to the same location in the detector? Both types of ions are singly ionized q-+e...
+V 0V Detector The picture above shows part of a mass spectrometer that can be used to measure molecular charge-to-mass ratios. A charged molecule (orange circle) is ionized and accelerated through an electric potential difference into a region with a uniform magnetic field. Here the magnetic field points out of the screen. The field makes the positively charged molecules undergo circular motion as shown. By adjusting the voltage difference between the plates, one can change the radius of curvature of...
1. Suppose that an ion source in a mass spectrometer produces doubly ionized gold ions -25 potential difference of 1.30 kV. Then, a 0.440 T magnetic field causes the ions to follow a circular path. Determine the radius of the path.
Suppose that an ion source in a mass spectrometer produces doubly ionized gold ions (Au2+), each with a mass of 3.27 × 10-25 kg. The ions are accelerated from rest through a potential difference of 2.20 kV. Then, a 0.530-T magnetic field causes the ions to follow a circular path. Determine the radius of the path.
Suppose that an ion source in a mass spectrometer produces doubly ionized gold ions (Au^2+), each with a mass of 3.27*10^(-25) kg. The ions are accelerated from rest through a potential difference of 1.10 kV. Then, a 0.490 T magnetic field causes the ions to follow a circular path. Determine the radius of the path.