I want to know about a book explaining easily the fundamentals of optics(not geometric).
I'm not a student who studys physics or optics but grad student studying laser spectroscopy(single molecule fluorescence spectroscopy). Are there any books matching me?
something called "wavevector, k"
I have a question about something called "wavevector, k".
What is it? Is that the direction of propagation of light? or something else?
Please explain easily. Thank you in advance.
I'm wondering what the diffraction limited spot is.
When a laser(CW) is used to excite a fluorescent single molecule, the fluorescence from a single molecule is shown in the CCD camera. The size of fluorescence molecule is determined by Airy Disc which comes from diffraction...
Why do you ask me like that?
I'm just curious about what the + and - sign of wavefunction stand for.
I know if there is a change of sign, at that point there is a node.
But basically I want to know the meaning of the sign.
I have a question about the sign of Schrodinger equation in particle in a box.
What's the meaning of the sign (like -, +) of wavefunction in particle in a box?
Can anybody explain that?
What you're saying is that the wavepacket has more or less localized energy at the average position even though the wavepacket is composed of lots of different momenta and for the wavefuction I can consider it like the excited state of paticle in a box. Right?
Am I understood?
I have a trouble understanding QM.
What's the difference between wavepacket and wavefunction?
Can we use a wavepacket for a particle in a box?
Please reply to this questions.
Thank you in advance.
Thanks again, Ken G.
"However, if you look at some incompatible measurement, like position, then an energy eigenstate for a particle in a box is still a "wavepacket" in regard to a subsequent position measurement."
From this, you mean I need different kind of wavefunctions for each...
Thank you for your reply.
I understand the reason why we use the wavepacket is there are undefined momenta in a quantum system. So since the wavepacket is composed of different momentum, it can describe the quantum system. Is that your saying, right?
Here's the another question. Then, if...
I'm doing FRAP(fluorescence recovery after photobleaching)
Diffusion coefficient is what I wanna calculate.
t:halftime of recovery fluorescence
w:radius of the focused circular laser beam at the e^(-2) intensity
f : correction factor for the amount of bleaching