FIGURE P29.64 shows a mass spectrometer, an analytical instrum...

Question

FIGURE P29.64 shows a mass spectrometer, an analytical instrument used to identify the various molecules in a sample by measuring their charge-to-mass ratio q/m. The sample is ionized, the positive ions are accelerated (starting from rest) through a potential difference ∆V, and they then enter a region of uniform magnetic field. The field bends the ions into circular trajectories, but after just half a circle they either strike the wall or pass through a small opening to a detector. As the accelerating voltage is slowly increased, different ions reach the detector and are measured. Consider a mass spectrometer with a 200.00 mT magnetic field and an 8.0000 cm spacing between the entrance and exit holes. To five significant figures, what accelerating potential differences ∆V are required to detect the ions (a) O₂⁺ (b) N₂⁺ and (c) CO⁺? See Exercise 29 for atomic masses; the mass of the missing electron is less than 0.001 u and is not relevant at this level of precision. Although N₂⁺ and CO⁺ both have a nominal molecular mass of 28, they are easily distinguished by virtue of their slightly different accelerating voltages. Use the following constants: 1 u = 1.6605 x 10⁻²⁷ kg, e = 1.6022 x 10⁻¹⁹ C.

Accepted Answer

Hi, everyone. Let's take a look at this practice problem dealing with mass spectrometer. This problem, a mass spectrometer has been configured with a magnetic field strength of about 100 milles along with an ran entrance exit hole spacing measuring approximately seven centimeters. What would be the necessary delta V acceleration potential difference required for detecting ch four ions. The atomic masses are C is equal to 12 atomic mass units. H is equal to 1.0078 atomic mass units. The electrons missing mass is neg negligible at this precision since it's less than 0.001 atomic mass units. The following constants should be used during the calculations. Q is equal to 1.6022 multiplied by 10 to the negative 19 columns. And the atomic mass unit is equal to 1.66 05, multiplied by 10th of the negative 27 kg. Well, the problem were given a diagram of what was described in the question. We're also given four possible choices as our answers. Choice A is 37 volts. Choice B is 1.5 multiplied by 10 to the two volts. Choice C is 3.6 multiplied by 10 to the two volts. And choice D is 1.0 multiplied by 10 to the three volts. Now, we're ultimately asked to calculate what our delta v potential difference should be. And so for this, we're actually going to use conservation of energy. And here we're gonna have the work done by the accelerating potential and that's going to be Q multiplied by delta V and that's gonna be equal to our kinetic energy, which is gonna be one half M little V squared. Now, we're given the charge since we're told that the ion has just a single positive charge. So it's just gonna be the 1.6 multiplied by 10 to the negative 19 columns. We're looking for delta V and we don't know what the mass is. However, we can use the chemical formula to calculate what the mass is. Let's start there. They'll have m gotta be equal to. And here I'm going to have to add together the mass of the carbon, which is the 12 atomic mass units. Then I'll add to that four multiplied by the mass of a hydrogen atom which is just one atomic mass unit. And I'm gonna actually want this in kilograms. So I'm gonna multiply this um sum by the conversion factor of 1.66 multiplied by 10 to the negative 27 kg divided by one atomic mass unit. So when I plug this values in my calculator, I get M is going to be equal to 2.66 multiplied by 10 to the negative 26 kg. So now I have a mass deal. The other unknown in my equation is going to be my speed, the little V. And for this, we're going to have to recall our formula or the radius of the circular motion or a charged particle moving in a magnetic field to recall that R is equal to M multiplied by little V divided by QB where R here is gonna be the radius of the circular motion. M is gonna be the mass of the particle. B is gonna be the speed of the particle. Q is the charge of the particle and B is our magnetic field strength. So I'm gonna solve this for little V. We'll have lovi is equal to UBR divided by M and I know the charge, I know the magnetic field, I know what the radius is since I know the separation distance between the entrance and exit holes and I just calculated the mass. So we're going to do is take this formula for the speed, the lowercase V and plug it back into our conservation of energy equation. So we'll have Q multiplied by delta V is equal to one half M. And in place of the little V, we wanna have the quantity of QBR divided by M. That quantity is gonna be squared. So at this point we can solve for the delta V, we have delta V is equal to, I will have Q since I'll have Q squared. And I'll divide that by Q when I bring the Q in the left hand side over. So I'll just have a single factor of Q and that gets multiplied by the quantity of BR and that quantity is squared and this gets divided by two M. And so one of the factors of M and the denominator gets canceled by the M and the newer. So at this point I can plug in values. So we'll have delta V is equal to the charge. That's just gonna be um the 1.6 multiplied by 10 to the negative 19 columns. And this is going to be multiplying the quantity or the strength of my magnetic field that was 100 mill tla so divide that by a hun 1000 to get it into teslas. So that's gonna be 0.1 teslas. And then this is going to get multiplied by the radius of our motion circular motion. And here we're told that the separation distance between the entrance and exit holes is um seven centimeters. So that's going to be when I convert that into meters by dividing by 100 it's gonna be 0.07 m, that's gonna be twice my radius. So I'll need to divide that by two. And then that whole product, the magnetic field and the radius that gets squared. And then I'm dividing now by the quantity of two multiplied by the mass, which we calculated earlier, which is the 2.66 multiplied by 10 to the negative 26 kg. So since I have just numbers on the right hand side of that equation, I can plug them into my calculator. And I'll get that delta V is equal to 37 volts. And here I just kept two significant figures and we look at my answer choices, this corresponds to answer choice. A. So just to recap quickly what we've done, we started off by studying the work done by the accelerating potential equal to the kinetic energy of the particle. We then used the chemical formula to find the mass of the particle. And then we also used the, our formula for the radius of the circular motion for a charged particle moving inside a uniform magnetic field. And we use that to calculate the speed of the particle. And so once we combined the speed back into our um work and connect energy formula and included the mass that we calculated, we are able to calculate our change in potential. So I hope that this has been useful. And I'll see you in the next video.

Key Concepts

Charge-to-Mass Ratio (q/m)

Acceleration through Potential Difference (∆V)

Magnetic Field and Circular Motion

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