Lord_Sidious said:
ΔxΔp ≥ \frac{h}{4\pi}
Since Δx=ct for a photon
What is meant by
t in this equation? The meaning of Δ
x is the uncertainty in the position of the particle. But, photons do not have a defined position.
Lord_Sidious said:
... and Δp=(mv_{f}-mv_{i})
Then ct(mv_{f}-mv_{i}) ≥ \frac{h}{4\pi}
Since mv=\frac{h}{\lambda}
Again, Δ
p is the uncertainty in momentum, not the change of momentum equal to final - initial momentum. Furthermore, the momentum of the photon is not calculated by the non-relativistic formula p = m v. However, your last formula (in this quotation) is correct, if you ignore the intermediate result m v, that you never use after that.
Lord_Sidious said:
You have ct(\Delta\lambda)^{-1}h ≥ \frac{h}{4\pi}
You have made a mistake here. If momentum is calculated by the De Broglie relation p = h/\lambda, then, an
uncertainty in wavelength Δ
λ implies, by the
error propagation formula:
<br />
\Delta p = \left\vert \frac{d p}{d \lambda} \right\vert \, \Delta \lambda = h \, \frac{\Delta \lambda}{\lambda^2}<br />
Lord_Sidious said:
Planck's constant cancels, move the c over \lambda, \frac{c}{\lambda}=f
Planck's constant does cancel. However, because your previous formula was incorrect, so is this one. The corrected version is obtained by going from wavelength to frequency via the error propagation formula:
<br />
c \, t \, \frac{\Delta \lambda}{\lambda^2} \ge \frac{1}{4 \pi}<br />
<br />
\lambda = \frac{c}{f}, \ \Delta \lambda = \left \vert \frac{d \lambda}{d f} \right\vert \, \Delta f = \frac{c \, \Delta f}{f^2}<br />
<br />
c \, t \, \frac{\frac{c \, \Delta f}{f^2}}{\frac{c^2}{f^2}} \ge \frac{1}{4 \pi}<br />
<br />
t \, \Delta f \ge \frac{1}{4 \pi}<br />
This is the same as your final answer:
Lord_Sidious said:
This leaves you with t\Deltaf ≥ \frac{1}{4\pi}
Dimensional analysis checks. Is this correct and is there any use to this equation?
t ≥ (4\piΔf)^{-1}
but the method by which you derived it is incorrect.
