02:05 <B0101> hmmm interesting, in a simulation, Al ions @ 30 KeV displace quite a number of Silicon atoms from the target, but none of the Al ions actually replace the displaced Si atoms...

02:11 <B0101> so, I assume we need to get to the MeV range to get actual implantation?

02:11 <glowplug> Megavolts?

02:12 <B0101> yup

02:13 <azonenberg> Hundreds of keV might be enough

02:13 <azonenberg> In any case, diffusion is much easier to do at home

02:13 <glowplug> We don't need that technology for ~405nm and larger devices though correct?

02:14 <azonenberg> just coat the ion source onto the surface of the wafer and heat up to 1000C or so

02:14 <azonenberg> glowplug: 405 is rather optimistic

02:14 <azonenberg> i'd shoot for a micron

02:14 <azonenberg> with 5 and 10 as stepping stones

02:14 <azonenberg> And no, you dont need implantation for large devices

02:14 <azonenberg> diffusion is fine

02:14 <glowplug> I have solved quite a few problems today.

02:16 <glowplug> One major problem is with the glass linear encoders I am curious if you have some insight.

02:17 <glowplug> I can get 5 micron accuracy for $200 per axis.

02:17 <glowplug> Its gets unrealistically expensive after that.

02:19 <glowplug> If I can get 1 micron cuts in a glass strip I can handle the optics / electronics. So what I'm trying to do is get the strip outsourced and DIY everything else.

02:20 <glowplug> The reason for the linear encoder is real-time antibacklash compensation. Without it the repeat accuracy of the machine wont be ~1 micron it would probably be far worse.

02:27 <glowplug> Also by $200 per axis I mean $200 per linear encoder not counting any other parts. That price really need to drop to keep the machine cost reasonable.

02:45 <glowplug> http://bit.ly/Yh11Ud

02:54 <glowplug> Oh right I was supposed to remind you about the wiki page. Haha