I flunked out of graduate school twice, in Physics. (I discuss this in my statement about Attention Deficit Disorder.) While I was there, I was working on organic dye lasers, which are amusing but rather messy devices. I designed and built several flashlamp-pumped ones (perhaps as many as a dozen), but all of them left something to be desired.
Perhaps partly for this reason, and almost certainly partly for other reasons, I became involved again in designing and building lasers on an amateur basis over a decade ago. Toward the end of the 1980s, a friend (Doug Humphrey) suggested that I start a mailinglist about them, which I did. Later, Doug took over the list for a while; later still, if I remember correctly, he handed it over to Dave McGuire, who is still running it. You can subscribe by sending the customary type of message to <majordomo@neurotica.com>. If that's mysterious, send a message to me and I'll explain what you need to do.)
After building several nitrogen lasers, including one that lased nitrogen at room pressure (nontrivial, as those who have tried it can attest), I got back to thinking about flashlamp-pumped organic dye lasers. Eventually I produced a flashlamp-driver design that I could build with nothing more than a Dremel Moto-Tool, because that was about the only machine-tool I had access to. Granted, it used a commercial spark gap as a switch (there are, after all, limits to what one can do with hand tools, though it's possible that one might make a decent switch for 30,000 volts, given the right materials and enough time).
This is what it looks like (click the little image if you want to see a bigger one; the large image is just under 100kB):
Not, perhaps, very pretty, and maybe not portrayed as clearly as I'd hope; but nonetheless, effective: this particular design eliminates the major shortcoming that plagued all of my earlier drivers. In fact, it exploded the first two flashlamps I tried to use in it, in two shots apiece, at just below the lowest rated voltage of the switch. (Sigh... at least it validated my conjecture that it would be relatively fast...) I was forced to resort to capillary lamps (you can see the lamp up toward the top, in the rear), which slow down the discharge considerably. Even slowed down, however, it works well enough to lase fluorescein or Rhodamine 6G with only the reflectance of the end-windows of the dye cell for feedback: no external mirrors are required. (Those who have tried this particular trick can tell you that it, too is not entirely trivial.) I have, just recently, acquired a reasonably fast oscilloscope (Tektronix 7904, with 7A19 vertical and 7B92/7B92A horizontal plugins, all out of date and all representing the joys of surplussage), and I hope to make some measurements of the risetime and pulsewidth of this device in the not-too-distant future.
This lamp driver is a grossly asymmetric version of what Papadopoulos and Serafetinides (see the reference at the end of this page) call a doubler circuit, but might more formally be described as an LC inversion circuit. The main store is a Maxwell capacitor that is rated 0.089 microfarad at 75 kV (The tall white thing just right of center in the photo), and the secondary store is a pair of 3.6 nanofarad barium titanate ceramic "doorknob" capacitors in series, so they add up to 1.8 nanofarads (the two darkish red cylindrical objects below the spark gap switch, which is the white cylindrical object on the left side of the Maxwell cap). That represents a ratio of almost 50:1. The smaller capacitor serves mainly to initiate conduction in the spark gap very thoroughly, which abruptly overvolts the flashlamp, turning it on very firmly. It is possible that the doorknob/switch side of this circuit "rings down" somewhat to a negative voltage, thus turning the lamp on even harder than the power supply voltage (typically about 30kV) otherwise would; I don't yet know. That was certainly my intention; measuring it, however, is another story. It is not trivial to instrument these things!
The doorknobs are on the right, with the bleeder resistor (not shown) across them (there's a tiny "pickoff" resistor, also not shown, at the bottom of the bleeder chain, to make it possible to check the charging voltage); the spark gap switch is just to the left of them; the arrows pointing at each other near the top represent the flashlamp; and the Maxwell is on the left. The charging inductor (the blue toroid with the red windings on it, just to the right of the Maxwell cap in the photo) is across the lamp, at the very top of the drawing. (The red and green Christmasy-looking wires looping across the photo are the trigger connections to the switch, only one of which is shown in the schematic. I think I've got the switch upside down in the drawing, btw -- the trigger electrode is on the lamp side, not the ground side. Please forgive the roughness.)
I took care to locate the spark gap physically between the doorknobs and the Maxwell, in order to minimize the inductance associated with the lamp circuit. As I say, this device blew up the first two lamps I put into it, an indication that it is fairly fast. (Lamp lifetime is inversely related to the peak power of the applied pulses. If you jam a large enough amount of energy through a lamp in a short enough time, the lamp envelope ceases to exist as a unified structure. Ahem.)
I have embarked on this craziness yet again: I'm about to build another nitrogen laser. This one is for a project, about which more later. It, too, is a modification of the doubler circuit, this time a balanced one that drives a small "peaker" capacitor, which in turn drives the discharge. I'm writing a little article about it, with some discussion of how nitrogen lasers work, their history, and why I chose this particular design strategy. (I may eventually append or link that article to this page.)
Sometimes I wonder why I do these things; in the past, I have built them because... well, because I wanted to see whether I could, because I've always been fascinated by fluorescence and by ultraviolet light, and because there is something very odd about a pulse of light that is only about as long as a broomstick, or a laser that is tunable across a substantial fraction of the visible spectrum, as some dye lasers are.
Mind you, my friend Sarah Green has generated pulses of light that are considerably shorter than the thickness of aluminum foil. But that's a very special thing indeed, and I won't go into it here. It is done with smoke and mirrors. (...Well, actually, dyes and mirrors and gratings and I don't know what-all.)
As I say, the laser I'm about to build is a tool, but that isn't usually the case; or perhaps it would be better to say that I typically use them as generalized learning instruments. You can learn quite a bit from a broomstick, if you pick your broomstick carefully.
Nitrogen lasers, at least small ones, aren't very hard
to design or construct, but there is a lot of
misinformation about them out there. (If you want, you
can
read my rant
about that.)
A. D. Papadopoulos and A. A. Serafetinides, "Characteristics of Doubling Circuits Used in Gas Laser Excitation: Application to the N2 Laser", IEEE Journal of Quantum Electronics, volume 26 number 1, January 1990, pages 177 to 188
(If you are interested in this general topic there are
several other references at the end of my little
nitrogen laser rant, and I can provide even more
citations if you send me an email message.)
almost-a-mailto: jon (at) bazilians (put the period here) org
Last modified: Sat May 19 00:27:06 PDT 2001