Quantum Physics: Heinsburg Uncertainty

AI Thread Summary
The discussion centers on calculating the minimum duration of a laser pulse using Heisenberg's uncertainty principle. The initial approach involved converting the wavelength of the laser light to energy and determining the uncertainty in energy based on a 1% deviation. The correct formula for uncertainty, ΔEΔt ≥ hbar / 2, was emphasized, and the calculation for Δt was clarified. It was noted that the final answer should reflect the minimum duration of the pulse, requiring the subtraction of the uncertainty from the calculated duration. The importance of using the correct constants and understanding the relationship between energy and wavelength was also highlighted.
200physics
Messages
2
Reaction score
0

Homework Statement


A laser produces light of wavelength 540 nm in an ultrashort pulse. What is the minimum duration of the pulse if the minimum uncertainty in the energy of the photons is 1.0%?


Homework Equations


ΔEΔt ≥ hbar / 2


The Attempt at a Solution


Now I tried a couple ways here:

1. Using Vx = hbar / 2*Pi*elemental charge*0.010%*d giving me 11.7 m/s but soon realized that seemed wrong.
2. Since the uncertainty in energy is 1.0%, i tried substituting it in as ΔE but my end result was wrong.

To be honest, I may be overthinking this one but I am kinda stumped as to where to go from here. I greatly appreciate your time!

Thank you!
 
Physics news on Phys.org
Is Heinsburg a town in Germany?
 
Well first you convert wavelength to energy using

E=h\dfrac{c}{\lambda}

Then you know what the precise energy of the pulse is supposed to be. But the energy is known to deviate by at least 1% from this value, so you calculate this deviaton by taking 1% of what you get from the energy-wavelength relation.

That 1% is your uncertainty in energy, \Delta E.

What's left then is just plug in \Delta E to Heisenberg's uncertainty and calculate \Delta t.
 
So going through the process,

E = (6.626*10^-34) * (3.0 x 10^8 / 5.40 x 10^-7) = 3.68 * 10^-19

Then taking 1% of it = 3.68 x 10^-21

Then plugging it into Δt = h / 2*Pi*3.68 x 10^-21 = 2.86 x 10^-14

I tried this and it was marked wrong, could my units be off or am I again using the wrong formula?

Thanks again everyone =D

EDIT: Yeah I mispelled the title by quite a bit
 
Last edited:
I am never sure about what constant should be used in Heisenberg's uncertainty. Anyways, in your relevant equations part, you use hbar/2 but in your solution h/2pi = hbar, so your missing a "1/2".

Another thing is that the result of these calculations is Δt, uncertainty in time (duration).What you are being asked for, is the minimum duration of the pulse.

Pulse duration could be given by \tau\pm\Delta t and in this case you're asked for \tau-\Delta t.
 

Thread 'Errors and significant figures'

I multiplied the values first without the error limit. Got 19.38. rounded it off to 2 significant figures since the given data has 2 significant figures. So = 19. For error I used the above formula. It comes out about 1.48. Now my question is. Should I write the answer as 19±1.5 (rounding 1.48 to 2 significant figures) OR should I write it as 19±1. So in short, should the error have same number of significant figures as the mean value or should it have the same number of decimal places as...
View full post »
Thread 'Calculation of Tensile Forces in Piston-Type Water-Lifting Devices at Elevated Locations'

Thread 'Calculation of Tensile Forces in Piston-Type Water-Lifting Devices at Elevated Locations'

Figure 1 Overall Structure Diagram Figure 2: Top view of the piston when it is cylindrical A circular opening is created at a height of 5 meters above the water surface. Inside this opening is a sleeve-type piston with a cross-sectional area of 1 square meter. The piston is pulled to the right at a constant speed. The pulling force is(Figure 2): F = ρshg = 1000 × 1 × 5 × 10 = 50,000 N. Figure 3: Modifying the structure to incorporate a fixed internal piston When I modify the piston...
View full post »
Thread 'A cylinder connected to a hanging mass'

Thread 'A cylinder connected to a hanging mass'

Let's declare that for the cylinder, mass = M = 10 kg Radius = R = 4 m For the wall and the floor, Friction coeff = ##\mu## = 0.5 For the hanging mass, mass = m = 11 kg First, we divide the force according to their respective plane (x and y thing, correct me if I'm wrong) and according to which, cylinder or the hanging mass, they're working on. Force on the hanging mass $$mg - T = ma$$ Force(Cylinder) on y $$N_f + f_w - Mg = 0$$ Force(Cylinder) on x $$T + f_f - N_w = Ma$$ There's also...
View full post »

Similar threads

How do I calculate Heisenburg's Uncertainty Principle?
Replies
16
Views
2K
Finite quantum well, multiple choice question
Replies
3
Views
2K
Harmonic Oscillator violating Heisenberg's Uncertainity
Replies
8
Views
1K
B Energy-time uncertainty relation for a volume and macroscopic objects?
Replies
2
Views
370
Calculate the minimum uncertainty
Replies
5
Views
8K
Single slit with minimum uncertainty
Replies
10
Views
9K
Pulse echo technique to find the distance of the Moon
Replies
19
Views
4K
Heisenberg momentum uncertainty
Replies
4
Views
3K
2 questions--seems simple -- Heisenberg Uncertainty
Replies
2
Views
2K
Heisenberg's uncertainty principle question
Replies
3
Views
7K

Hot Threads

Recent Insights

Back
Top