Question

A mass spectrometer is a device for separating particles of different masses from a mixture. For...

A mass spectrometer is a device for separating particles of different masses from a mixture. For example, the technology is used to investigate qualitative and quantitative changes within thousands of biologically active components such as proteins, lipids and metabolites. A mass spectrometer consists of three sections:

  • The accelerator
  • The velocity selector
  • The magnetic chamber

(1) Accelerator (acc): In the accelerator, there is only an uniform Electric field due to a potential difference Vacc across two vertical plates separated from a distance dacc. This E-field, Eacc, accelerates the charged particles. The charge emerges from the vertical plates with a speed v.

Skecth the situation describing the accelerator.

What are the EQUATIONS defining:

  • the E-field between the plates, Eacc
  • the acceleration acting on the charge, charge.acc
  • the position as the charge travels, charge.pos
  • the velocity as the charge travels, charge.v

(2) Velocity Selector (sel): In the velocity selector, there are two uniform fields: an Electric field, Esel, and a Magnetic field, Bsel, perpendicular to each other. Only the charges with a specific speed will be able to move undeflected between the two horizontal plates.

Sketch the situation describing the velocity selector.

What are the EQUATIONS defining:

  • the E-field between the plates, Esel
  • the electric force acting on the charge
  • the magnetic force acting on the charge
  • the total force acting on the charge, Fsel
  • the acceleration on the charge, charge.acc
  • the position as the charge travels, charge.pos
  • the velocity as the charge travels, charge.v
  • the momentum of the charge from velocity, charge.momentum

(3) Magnetic Chamber (cham): In the magnetic chamber, there is only an uniform magnetic field, Bcham. Once the undeflected charges reach the chamber, they will rotate in the field until they hit a detector.

Sketch the situation describing the magnetic chamber.

What are the EQUATIONS defining:

  • the force acting on the charge, Fmag
  • the momentum of the charge from the force, charge.momentum
  • the velocity as the charge travels, charge.v
  • the position as the charge travels, charge.pos
  • How can you find the radius of curvature from the above information?

Look at this: simulation

Singly charged positive ions (m = 5.80E-26 kg) are introduced into a mass spectrometer. The ions are first accelerated by the electric field established by placing a potential difference Vacc = 20.0 V across the vertical plates distanced by 2.0 cm. Next, they pass through the horizontal plates of a velocity selector, Vsel = 52.5 V spaced by 1 cm and placed in a uniform magnetic field, Bsel = 0.500 T (-k). Finally they enter a region where a uniform magnetic field of Bcham = 0.200 T (+k) exists.

Sketch the whole situation.

Determine the following:

a) The speed of ions entering the velocity selector.

b) What must be the direction of Esel for the ions to be undeflected?

c) The radius of curvature of the ions in the B-chamber.

Science   Advanced-Physics   
0 0
Add a commentTranscribed image text
Next >

Homework Answers

Answer #1

0 0
Know the answer?
Your Answer:

Post as a guest

Your Name:

What's your source?

Earn Coins

Coins can be redeemed for fabulous gifts.

Log In

Sign Up

Not the answer you're looking for?
Ask your own homework help question
Similar Questions
A mass spectrometer is a device for separating particles of different masses from a mixture. For...
A mass spectrometer is a device for separating particles of different masses from a mixture. For example, the technology is used to investigate qualitative and quantitative changes within thousands of biologically active components such as proteins, lipids and metabolites. A mass spectrometer consists of three sections: The accelerator The velocity selector The magnetic chamber (1) Accelerator (acc): In the accelerator, there is only an uniform Electric field due to a potential difference Vacc across two vertical plates separated from a...
Consider the mass spectrometer shown schematically in the figure below. The magnitude of the electric field...
Consider the mass spectrometer shown schematically in the figure below. The magnitude of the electric field between the plates of the velocity selector is 2.60  103 V/m, and the magnetic field in both the velocity selector and the deflection chamber has a magnitude of 0.0300 T. Calculate the radius of the path for a singly charged ion having a mass m = 2.48  10-26 kg
Consider the mass spectrometer shown schematically in the figure below. The magnitude of the electric field...
Consider the mass spectrometer shown schematically in the figure below. The magnitude of the electric field between the plates of the velocity selector is  2.40 * 10 3  V/m, and the magnetic field in both the velocity selector and the deflection chamber has a magnitude of 0.0400 T. Calculate the radius of the path for a singly charged ion having a mass m= 6.34  * 10 -26 kg. a. 0.718 b. 0.236 c. None of the given answers d. 0.401 e. 0.594
You have a Bainbridge Mass Spectrometer with an electric field in the velocity selector of 1.20...
You have a Bainbridge Mass Spectrometer with an electric field in the velocity selector of 1.20 x 105 V/m and a magnetic field in both regions of 0.600 T. A stream of singly charged ions from a pure source (i.e.-all the atoms are the same type of element) move in a semicircular arc and strike the recording plate 1.46 m from the opening in the magnetic field chamber. Determine the mass of the ions. Given the fact that the mass...
Consider the following apparatus for measuring the charge per mass (q/m) ratio of the proton. This...
Consider the following apparatus for measuring the charge per mass (q/m) ratio of the proton. This apparatus employs the same physics as in mass spectrometers. It consists of a pair of plates that accelerate a beam of protons starting from rest at the left-most plate to a speed of 1 x 107 m/s, followed by a velocity selector set to only pass this speed, and a final set of deflector plates. (a) The left side of the accelerator plate is...
A point charge q is moving in uniform electric field (E0 in the z-direction) and uniform...
A point charge q is moving in uniform electric field (E0 in the z-direction) and uniform magnetic field (B0 field in the x-direction). (i) What is the force acting on the charge particle? Find equations of motion for the charge particle. (ii) Assume that initially the charge is placed the origin and has initial velocity (E0/2B0) in the y-direction. Determine position and velocity of the charge particle as a function of time. (iii) Find the trajectory of the particle and...
Design a mass spectrometer to distinguish between isotopes of Carbon (C112 and C14). The first stage...
Design a mass spectrometer to distinguish between isotopes of Carbon (C112 and C14). The first stage is an ion gun in which carbon is blasted into a gas form and ionized to a +e charge. An electric field ejects a collimated beam of mixed C12 and C14 isotopes into a velocity filter with average energy 500eV. In the design, there should be access to a 1T magnetic field you can use for both your velocity filter and detector regions. In...
To use a mass spectrometer we first need to ionize the incoming particles, so we do...
To use a mass spectrometer we first need to ionize the incoming particles, so we do the following. First there is a particle of known charge q = 2 |e|, entering the left side of the velocity selector, which has a voltage of 884V between the plates, a plate separation of d = 1cm, and a magnetic field of Bin = 2T. This particle then enters the region of a second magnetic field of B0,in = 0.5T, and moves in...
A proton, with mass 1.67 × 10-27 kg and charge +1.6 × 10-19 C, is sent...
A proton, with mass 1.67 × 10-27 kg and charge +1.6 × 10-19 C, is sent with velocity 7.1 × 104 m/s in the +x direction into a region where there is a uniform electric field of magnitude 730 V/m in the +y direction. What are the magnitude and direction of the uniform magnetic field in the region, if the proton is to pass through undeflected? Assume that the magnetic field has no x-component and neglect gravitational effects. Draw a...
Consider a particle of charge q = 1.2 C and mass m = 1.2 kg passing...
Consider a particle of charge q = 1.2 C and mass m = 1.2 kg passing through the region between a pair of infinitely long horizontal plates separated by a distance d = 1.5 m with a uniform electric field strength E = 38 N/C directed in the downwards direction (-y direction). The particle begins moving horizontally with an initial velocity of v = 35 m/s from a position halfway between the plates. How far in meters are the plates?...
ADVERTISEMENT
Need Online Homework Help?

Get Answers For Free
Most questions answered within 1 hours.

Ask a Question
ADVERTISEMENT