Good catch, I add archive links to everything, but doing it by hand right now, so sometimes I miss them.
Sorry about that.
Planning on writing a script or something to handle archiving.
yeah ;) i have a sweet spot for it because of the graphics for the map, heh
trek, if we are talking about classics (i’m still not good at it), but I grew up with MUDs, so those are my favorites. i got to play a little zork in the BBS days, and Legend of the Red Dragon.
Hmm, LORD might have been my favorite of all time, if I had to pick one terminal-ish game.
edit: i’ll have to check out atc, btw, i havent played it yet
lol we still play some old UNIX games at SDF every now and then, but we’re not all graybeards either
I will definitely wait until i see that there are actually 0 replies after a day before I reply to anything science related.
I dont feel welcome here and good bye.
Thank you for that
I gave the OP the benefit of the doubt that it didnt know where to look in the article for the description of the image.
Will stop trying to help, sorry.
It helps those that know how to read the text… It clearly states that those are Pr-Pr dumbbells in the PrScO3 lattice that you are seeing. Also, you should be seeing some O-Sc-O triplets, but I didn’t look for them.
This is a picture of a crystal of a molecule made up of three different types of atoms.
I’m too tired to help you more, right now, sorry.
“The high–spatial resolution phase image of Fig. 2A is borne out by quantitative analysis. In real space, the Pr–Pr dumbbells with a separation of only 59 pm are resolved with a contrast of 63% (Fig. 2B), which is better than the 73% contrast for two point objects separated at the Rayleigh criterion. Therefore, the Rayleigh resolution of the image is much better than 59 pm. Nevertheless, the exact resolution can be determined only after considering the finite atomic size instead of assuming point objects (28). We can also resolve the O–Sc–O triple atom projections, even though the light O atoms are only 63 pm (26) from the heavier Sc atoms “
They are looking at a crystal lattice of PrScO3
Certainly a viable technique.
Ironically? Nay, purposefully.
Andor only gets better and better - savor it like a fine wine, scotch, cigar, chocolate, or delicacy - don’t binge it
https://en.wikipedia.org/wiki/Long-range_Wi-Fi
:D
I’ll see if i can find something specifically about what you are asking, but I would be surprised if anyone has taken the time to try to bounce WiFi. The wavelength might not be amenable to bouncing, as it is such a high frequency signal. If I recall correctly, there is a relatively narrow range of wavelength that will actually bounce back to earth off of the atmosphere.
edit: https://radiojove.gsfc.nasa.gov/education/activities/iono.html