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Bravus
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Trapping dust particles in a Paul trap, in air, at 50 Hz (similar to Winter & Ortjohann, 1991).
Gravity compensation is achieved using a DC voltage across top and bottom electrodes.
Given the features of the trap, the charge-to-mass ratio of the trapped particle can be calculated as follows:
<br /> \frac{Q}{M} = \frac{z_0^3Ω^2ΔV_z}{4V_{ac}^2Δz_F}<br />
where Q = charge (C), M = mass (kg), z0 is half the height of the trap (m), Ω = frequency (rad/s), Vz = applied compensation voltage (V), Vac = is the amplitude of the oscillating trapping potential (V) and zF = displacement of the particle from the trap centre (m).
OK, so that allows me to find the ratio of charge to mass, by varying the compensation voltage and measuring changes in the 'sag' from the centre of the trap. I'm not sure it allows me to separately determine the mass and charge, though...
As I'm writing this it occurs to me that graphing ΔVz vs ΔzF will give me intercepts that might be relevant...
Will keep thinking on it myself, and share any fruits if I make progress, but thought I'd turn your collective minds loose on it too...Reference
H Winter and H W Ortjohann. Simple demonstration of storing macroscopic par-
ticles in a "Paul trap". American Journal of Physics, 59(9):807-813, May 2004.
5
Gravity compensation is achieved using a DC voltage across top and bottom electrodes.
Given the features of the trap, the charge-to-mass ratio of the trapped particle can be calculated as follows:
<br /> \frac{Q}{M} = \frac{z_0^3Ω^2ΔV_z}{4V_{ac}^2Δz_F}<br />
where Q = charge (C), M = mass (kg), z0 is half the height of the trap (m), Ω = frequency (rad/s), Vz = applied compensation voltage (V), Vac = is the amplitude of the oscillating trapping potential (V) and zF = displacement of the particle from the trap centre (m).
OK, so that allows me to find the ratio of charge to mass, by varying the compensation voltage and measuring changes in the 'sag' from the centre of the trap. I'm not sure it allows me to separately determine the mass and charge, though...
As I'm writing this it occurs to me that graphing ΔVz vs ΔzF will give me intercepts that might be relevant...
Will keep thinking on it myself, and share any fruits if I make progress, but thought I'd turn your collective minds loose on it too...Reference
H Winter and H W Ortjohann. Simple demonstration of storing macroscopic par-
ticles in a "Paul trap". American Journal of Physics, 59(9):807-813, May 2004.
5
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