Zenith Console, Model 10-S-464

I really should stop doing this.

Zenith Console, Model 6-S-52

I got it home.

Heathkit V-7 Vacuum Tube Voltmeter

I bought this cute little guy for $10.  It's a vacuum tube voltmeter.  It can measure AC and DC voltages up to 1500 Volts, and can also measure resistance.

Eico 950B Capacitor Tester - and bridge circuit explained

I mentioned earlier that I had purchased a Capacitor Tester from an online auction, in this post.

Zenith K526W - Update #2

The vacuum tubes finally arrived.  According to the seller, all of the vacuum tubes tested good.  I've no reason to doubt that.  Tubes fail less frequently than the power cord or capacitors.  If anything, a failed capacitor usually takes out a tube.

Zenith K526W - Update

The original post on the Zenith is Here:

Nuclear Imaging - X rays

Nuclear imaging is the process of viewing the internals of a human body by using the body's own nuclear properties, injected or ingested radioisotopes, and/or by using external radiation sources.

The earliest known and most commonly used type of nuclear imaging is done by using X-rays.  Although X-rays are not exactly "nuclear", they are ionizing electromagnetic radiation, so I will discuss them.  X-rays are produced in vacuum tubes, although not just any vacuum tube will do the trick.

The earliest vacuum tubes, called Geissler Tubes, used gas at a mild vacuum, and were similar in nature to modern neon lights.  Different gases would yield various colors.  Handling the glass envelope would cause the tube to glow brightest at the point where it was being touched.

Below, sketches of various Geissler Tubes, used mainly for amusement in the late 19th century.  All images courtesy of Wikipedia.

The Crookes Tube was another vacuum tube, but built with a different structure and improved vacuum.  This tube was a highly evacuated glass tube with a cathode, an anode, and a flight path for electrons (although this was not understood at the time).  The anode was set off to one side of the tube, and very high DC voltage was applied to the tube.

Below, a Crookes Tube.  Negative voltage is applied at left, making this the cathode (electron emitter).  Positive voltage is applied at bottom, making this the anode (electron collector).  A thin piece of metal in the shape of the Maltese Cross is suspended in the middle, in order to cast a shadow at the end of the tube.

Because this tube had very few gas molecules in it, and because the voltage was so high, a heated tungsten emitter was not necessary to cause current flow from the cathode to the anode.  So for this reason the Crookes Tube is called a "Cold Cathode" tube.

What occurs inside a Crookes Tube is the elecrons leave the emitter, pulled by the very high DC voltage between emitter and collector.  The traces of gas remaining in the tube are struck by these high-energy electrons, and are stripped of their electrons as well.  All the traces of gas inside the tube are ionized (thus the glow).  Electrons move from the emitter at such high speed that their momentum prevents them from going directly to the collector.  Instead they fly right past the collector, and either impact a piece of metal suspended inside the tube, or impact the glass tube wall.  In this respect, a Crookes Tube might be considered the forerunner of the Cathode Ray Tube (CRT) screen. 

Crookes Tubes were laboratory curiousities for about 20 years, because nobody understood what invisible rays were casting the shadow on the front end of the tube.  Clearly the metal object was blocking something from reaching the other end of the tube!  These rays were called "Cathode Rays", and eventually JJ Thompson proved that the "Cathode Rays" were negatively charged particles, which eventually received the name "electron".  Until that time, the atom was thought to be the smallest known piece of matter, and nobody understood that electricity was the flow of electrons.

Crookes tubes have another important aspect besides generating an electron shadow image.  They also produce X-rays.  X-rays were discovered and researched by Wilhelm Röntgen in 1895. Röntgen and many other scientists at the time were experimenting with Crookes Tubes.  While many scientists noticed that photographic plates fogged in the vicinity of Crookes Tubes, only Röntgen realized that penetrating radiation was being generated. By the way, Crookes Tubes are readily available on Ebay.

Below, the world's first Radiograph (X-ray picture) of the hand of Anna Bertha, Röntgen's wife.

At voltages over about 5000 volts, Crookes Tubes create X-rays in a process called "Bremsstrahlung".  Sorry, I have no idea how to pronounce that :).  What the word means is "Braking Radiation", which is not very difficult to understand.

At 5000 volts, the electron is moving at about 20% of lightspeed.  (It's easy to understand why it doesn't make the bend to directly reach the anode!!!)  At 20% of lightspeed, the electron smacks into the metal object or the glass envelope of the Crookes tube and comes to a stop.  What becomes of all that kinetic energy?  X-rays!

Here we get into the realm of special relativity; the 5000 (or more) volts between the emitter and collector have added speed to our elctrons.  This increase in speed also increases their mass, and this increase in mass can be calculated.  When the electon moving at 20% of light speed comes to rest, this mass it gained is immediately lost and converted (E=mc^2) to energy, in the form of X-rays.  The higher the voltage used between the emitter and collector, the more energetic the X-rays.

And so just as kinetic energy removed by slowing down a vehicler is converted to heat energy in the brakes, the kinetic energy of the electron is also converted.  And yes, a vehicle traveling at high velocity has slightly more mass than one at rest.  To be measureable, this mass increase would probably have to be taken at some fraction of light speed. :)

From Wiki:
The medical applications of X-rays created the first practical use for Crookes tubes, and workshops began manufacturing specialized Crookes tubes to generate X-rays, the first X-ray tubes. The anode was made of a heavy metal, usually platinum, which generated more X-rays, and was tilted at an angle to the cathode, so the X-rays would radiate through the side of the tube. The cathode had a concave spherical surface which focused the electrons into a small spot around 1 mm in diameter on the anode, in order to approximate a point source of X-rays, which gave the sharpest radiographs. These cold cathode type X-ray tubes were used until about 1920, when they were superseded by the hot cathode Coolidge X-ray tube.



Below, a Crookes X-Ray Tube.  Note that the target anode is at an angle, to direct X-rays off to the right side of the tube.  The small object to the right of the cathode is to replenish gas in the tube as it ages.  Crookes tubes reguire a slight amount of gas to function.


Modern tubes use heated cathodes, which utilizes thermionic emission to generate electron flow.  They also have water-cooled anodes, to prevent the electron beam from warping or vaporizing portions of the anode. 



Below is an electrical diagram of a modern X-ray tube.  "Uh" is the circuit for heating the tungsten emitter (C).  "Ua" is the high voltage circuit used to create the electron beam that will generate the X-rays.  Win and Wout are water cooling for the anode (A).


Below, a modern X-ray tube.  Note the thinner section of glass where the X-rays leave the tube.  Looks a little scary to me...


The vast majority of X-ray radiography uses old-fashioned photographic techniques:  A cellulose plastic sheet which is coated with silver-halide emulsion is exposed to X-rays and developed by washing the exposed silver off the sheet.  In early days, a sheet of glass coated with emulsion was used.  Currently a plastic sheet with sensitive coating on both sides is used.  Coating both sides  increases the sensitivity of the film, thereby reducing the X-ray exposure required.



Modern X-ray radiography is replacing film with digital sensors.  The advantages of digital detectors are higher sensitivity (and so reduced exposure), immediate processing so that the shot (angle, contrast) can be re-imaged if necessary, chemical processing is eliminated, and digital enhancements can be used to improve the quality of the initial image.



Another X-ray imaging technique used early on was the Fluoroscope.  The patient would be placed between the X-ray source and a fluorescent screen.  The screen would glow like a TV, with the image of the inside of the patient.  This provided a physician with the exciting ability to see inside a patient in real-time!  The downside was heavy X-Ray exposure, both for the patient and the physician.



Below, a sketch of a doctor using a fluoroscope to remove a bullet from a WW1 soldier.  An unshielded Crookes X-ray tube is beneath the patient!


Amusingly, fluoroscopes were manufactured for use in shoe sales.  An X-ray source was built into a box which the customer stood on.  The salesman would then use the fluoroscope to check for fit.

Happily we now can use digital imaging techniques rather than requiring the use of fluorescent screen.  These are far more sensitive to X-rays than phosphorescent coatings on glass, and of course, require less exposure of the patient to ionizing radiation.



Below, a modern fluoroscope.  The machine has the ability to take snap-shots at adjustable intervals, eliminating the need for continuous X-ray exposure.

One of the techniques used in X-ray radiography (both in fluoroscope and X-ray film), is the use of liquids that are opaque to X-rays, called "contrast agents".  Barium Sulfate is an edible (?) cocktail containing the X-ray opaque element Barium.  When the Barium has been consumed and coated the lining of the patient's stomach and intestines, an X-ray image can be made.  This will clearly show the outline of the patient's gastro-intestinal tract, as the barium will absorb X-rays, blocking them from reaching the film/detector.
 

An X-ray of a normal stomach and lower intestine in a patient.  Note how the Barium Sulfate has made the internal organs more opaque to X-rays than even bone.

Likewise, contrast agents can be injected into the bloodstream, and an X-ray shot taken, in a process called Angiography.


Below, an X-ray image of a patient's veins near the rear base of the skull, taken with contrast agents injected into the bloodstream.

 

CT scans (Computer Tomography) is an impressive blend of the old technology of X-rays with the new technology of digital imaging.  By taking X-ray "slice" images at various angles, it is possible to use a computer to combine these images and build a three-dimensional image of the inside of the body.



The down-side to CT scanning is that many, many X-ray images must be taken to render a three dimensional image, and so exposure levels are quite high for this imaging technique.  I would need to have a very good reason to undergo a CT scan.



Next up:  PET scans.  And I am not talking about scanning dogs and cats!

Nuclear Research Reactors - The MK 4 Experiments *UPDATED*

I was a reactor operator at General Atomics in the late 1980's.  General Atomics then operated two swimming-pool type TRIGA reactors.  The first was a MK IV reactor that was the bread and butter of the reactor division of the company.  It had two long-running experiments, one of which piggy-backed on the primary one.

Below, a TRIGA reactor similar to the one I operated.  Yes, it glows just like that!

The primary experiment that the MK IV was used for was in-core thermionic cell testing.  The goal of testing the thermionic cells was to determine the longevity of these unique devices. 

What the heck is a thermionic cell?  In order to explain, we need to understand how a basic vacuum tube works.

Below is a diagram of a vacuum tube called a diode.  It has two elements inside the glass tube (the circle).  These elements are called the cathode and the anode.  I prefer to call them an emitter and a collector.  In this diagram, the bottom emitter is heated by an electrical current, labeled "Filament Supply".  So - there is a short electrical loop completely dedicated to heating the spiral-wound filament, which is made of tungsten.  Tungsten is chosen because it ejects electrons when heated.  This process is called "Thermionic Emission"

Next, voltage is applied at the right side of the diagram, to put a positive charge on the Anode (collector), and a negative charge on the cathode (emitter).  This causes electrical current to flow from the emitter at the bottom, to the collector at the top, just like it were a piece of copper wire.

Current will not flow in the other direction if the voltage on the right is reversed though, because the anode is not a heated piece of tungsten, ready to fling electrons out.  This is the simplest vacuum tube around.  It is called a diode, and it only lets current pass in one direction, from cathode (emitter) to anode (collector).

So with this understanding of a basic vacuum tube, let's see if we can figure out a thermionic cell.

Suppose in our drawing above, we crank up the power provided by "Filament Supply", so the tungsten emitter is really blasting electrons out.  Next, we put the emitter in the center of the vacuum tube, and the collector encircles it, so that no matter what direction the electrons go, the anode (collector) will capture them.  This process is called thermionic conversion.  You heat the cathode hot enough and it kicks out electrons, and now you have DC current from cathode (emitter) to anode (collector).  On the right side of our drawing above, you could power a light bulb with this current.

The clever part of thermionic conversion is you get DC power without the need for a boiler, steam turbine, generator, condenser, pumps, etc, etc.  It's a pretty simple and elegant arrangement.

In a nuclear thermionic cell, the emitter is a small thimble of uranium that is coated with tungsten.  Around the emitter is a slightly larger collector.  The assembly is placed in a reactor.  Fission begins in the uranium, which in turn heats the tungsten coating.  The tungsten ejects electrons, and current flows in the thermionic cell.  Even a tiny thermionic cell can generate 1KW of low-voltage but high amperage power.

Below:  A top-down cutaway of a nuclear thermionic cell.  The cathode is made from tungsten-coated enriched uranium and inserted into a reactor.

If you had enough of these devices in a single small reactor core, you could easily get a Megawatt of power.  This would be perfect to launch into orbit as a power supply for your space laser, plasma weapon, or coil gun to shoot down incoming nuclear missiles - and in fact the project was funded by the Department of Defense through the Strategic Defense Initiative (aka the "Star Wars" Program).

The MK IV reactor was run round the clock in order to put reactor hours on the thermionic devices, to see how they would hold up, year after year. 

We had some other people who wanted to use the MK IV reactor's spare neutrons, and run their "experiment" alongside the thermionic experiment.  These guys were jewelers.  That's right, they made jewelry.  I don't think the jewelers had the income stream to keep the reactor running 24-7, so it was good that they could use the opportunity provided by the government's experiment.

This is where I learned about gemstone color enhancement.  Improving the appearance of gemstones goes back to ancient times, when emeralds would be soaked in oil to hide their fractures.  Nowadays though, a generic stone like topaz can be made beautiful by irradiation. 

The stones were packed into canisters and placed in dry Cadmium-lined tubes (to provide fast neutron flux only).  Even with fast neutron flux, due to trace impurities in the stones, they become radioactive during the process.  The jewelers would come in once a week and rotate the stones using remote tools, so that the stones would be irradiated from all sides.  After the stones were cooked, they would be removed from the reactor, but left on a shelf well below the water level, because they were quite radioactive, fresh out of the core.

 It would take quite a while for the radioactivity to die off enough for the stones to be released to the public.  The jewelers probably had 5-10 million dollar's worth of inventory stacked out in cheap sheet-metal lockers at a given time, waiting for the activity to fade. 

 Here is a raw uncut, uncolored topaz, as you would find it in nature.  Not impressive.

Below is a cut natural topaz.  Nice clarity and cut, but I am not a fan of pee-yellow gemstones, and most others aren't either.

 Below is a Topaz that has been irradiated with fast neutrons.  This color is called "London Blue", or "Swiss Blue", and is actually about the color of Windex glass cleaner.

Below is a Topaz that has been irradiated by fast neutrons, and afterwards been irradiated by an electron beam provided by a linear accelerator.  I like this color better, and the jewelers started producing these after a while.  I helped install a used linear accelerator in the underground bunker.

 Below is the "Sky Blue" color you get when you irradiate a topaz with pure gamma rays from a Cobalt-60 source.  Pretty.  Also no neutrons, no radioactivity.  You can wear it the next day.

As always, fascinating stuff!

****UPDATE****

An interested anonymous commenter has graciously done a lot of homework and helped out with content on the Gemstone Color Enhancement process.  Thank you for that!

Here is a great link for a layman explaining how the various color shifts are achieved

Here is a cool research paper with experiments showing gemstone color changes with dose

Some early (1981) irradiated topaz stones were released before the radioactivity had died down

A nice long-form explanation of topaz color enhancement

Lastly, the link where all the above links (and many more) Can be found:

All very cool information!  Thanks again Anon commenter :)