Fun With Negative Resistance II: Unobtanium Russian Tunnel Diodes

In the first part of this series, we took a look at a “toy” negative-differential-resistance circuit made from two ordinary transistors. Although this circuit allows experimentation with negative-resistance devices without the need to source rare parts, its performance is severely limited. This is not the case for actual tunnel diodes, which exploit quantum tunneling effects to create a negative differential resistance characteristic. While these two-terminal devices once ruled the fastest electronic designs, their use has fallen off dramatically with the rise of other technologies. As a result, the average electronics hacker probably has never encountered one. That ends today.

Due to the efficiencies of the modern on-line marketplace, these rare beasts of the diode world are not completely unobtainable. Although new-production diodes are difficult for individuals to get their hands on, a wide range of surplus tunnel diodes can still be found on eBay for as little as $1 each in lots of ten. While you’d be better off with any number of modern technologies for new designs, exploring the properties of these odd devices can be an interesting learning experience.

For this installment, I dug deep into my collection of semiconductor exotica for some Russian 3И306M gallium arsenide tunnel diodes that I purchased a few years ago. Let’s have a look at what you can do with just a diode — if it’s the right kind, that is.

[Note: the images are all small in the article; click them to get a full-sized version]

3И306M Tunnel Diodes

I bought a set of ten of these military-grade gallium arsenide diodes in 2016 for some experiments with pulse generators. You may also see this part listed as “3I306M,” since the Cyrillic letter “И” corresponds to the English “I.” The TekWiki on has a good page on surplus Russian diodes, as well as good general information on tunnel diodes, especially those used in classic Tektronix oscilloscopes. Some diodes are optimized for use in amplifiers, pulse generators, or for switching circuits. From the 3И306M datasheet (PDF, in Russian), we can glean some information about this particular diode — a switching type — but I found it easier just to measure some of the parameters firsthand using a curve tracer, which generates the I/V characteristic curve for the device.

Tunnel diode waveform shows sharp edges

In the last article, I presented my quick-and-dirty curve tracer, which is nothing more than a signal generator, a 10-Ohm resistor, and an oscilloscope. I also mentioned the problem with that method: that the voltage measurement is corrupted by the current measurement on the scope’s screen. The ideal thing to do is capture the trace data and plot the curve in your favorite graphing software, where you can compensate for the error. This time, that’s exactly what I did, exporting the traces as a CSV file, then generating the plot in python using matplotlib.

As you can see in the curve, the current through the device initially ramps up to around 11 mA with increasing voltage until 150 mV, at which point the current drops abruptly to about 500 uA before increasing again. This is the negative differential resistance (NDR) region, where the current drops with increasing voltage. The interesting thing about this curve is that only two points in this region were captured. Looking at the waveform of the voltage measurement shows what’s going on — the diode is switching on and off at very high speed.

Switching Performance

Tunnel diode switching time test jig – just a couple of BNC connectors soldered together.

This diode was intended for switching, so it makes sense it should generate sharp edges. To get a better look at this, I built a test jig from two BNC jacks soldered closely together: the tunnel diode is soldered across the BNC terminals. With one end connected to a 50-Ohm signal generator and the other to a 50-Ohm terminated oscilloscope, this allows testing of the very fast switching speed of the diode.

Fall time of tunnel diode is less than 1 ns

The switching time of the diode seems independent of the input waveform — when the voltage hits the threshold, the diode switches — so I drove it with a triangle waveform at around 100 kHz. I measured the fall time of the output transitions at under 900 ps, while the rise time was slightly longer at 1.1 ns. That’s pretty impressive for a circuit with only one part (ignoring the signal generator). This could be just the ticket for sharpening up the lazy 100 ns edges on a classic 555 oscillator, if you were into that kind of thing.

The drawback to this circuit, common to all tunnel diode applications, is the low output level: these diodes work at low voltages and currents, so can’t generate powerful outputs.

300 MHz Oscillator

Tunnel diode LC oscillator

While this particular diode may have been intended for switching, it can easily be pressed into oscillator service. Like I did with the transistor circuit in Part I, I built an LC oscillator using this diode as the active element. The negative resistance of the tunnel diode counteracts the positive resistance in the LC tank, causing oscillations to build over time instead of diminishing.

300 MHz oscillator and probe loop

The resonator initially consisted of a single 9 mm loop of copper wire in parallel with a 2 pF capacitor – or so I thought. A 10 nF bypass capacitor handles the return current through the diode, and a 700 mV supply powers the oscillator, although I found that the circuit would continue to oscillate down to 330 mV once started.

This circuit initially oscillated at 295 MHz. When I swapped the 2 pF capacitor for a 1 pF part, and the frequency only went up to 300 MHz, I realized that the capacitance of the diode itself was keeping the frequency low. By calculating the inductance of the wire loop, I was able to estimate the diode capacitance at around 18 pF (the datasheet only says less than 30 pF). This diode capacitance adds to the LC tank capacitance, reducing the resonant frequency.

300 MHz tunnel diode oscillator output

For the same reason, care must be taken when probing a circuit like this. My 10x oscilloscope probe claims to have a 10 pF nominal capacitance, which would have a similar frequency-reducing effect if the circuit were probed directly. Instead, I attached the ground clip to the probe’s tip, forming an inductive pickup loop. Keeping the two loops close together acts like a transformer and gives enough coupling to detect the signal and measure the frequency. Since the coupling is somewhat arbitrary, the amplitude scaling is not calibrated, but changes to the circuit operation — due to changing the power supply for instance — can still be seen.

581 MHz Oscillator

581 MHz tunnel diode oscillator with two components

Not content with 300 MHz, I decided to strip the circuit down to the bare minimum to speed it up. I cut the diode leads short and soldered them directly to those of a 100 pF axial capacitor. In this case, the leads themselves are providing the necessary inductance, resonating with the diode capacitance. Again using a supply voltage of 700 mV, I found the circuit oscillated at 581 MHz. I’m not sure how to make this go any faster using lumped components – maybe someone can suggest a different method in the comments. Cavity resonators?

Output of two-component tunnel diode oscillator at 581 MHz

In any case, I find it amazing that a two-terminal device can form such an oscillator this simply. I also have a much greater appreciation for the designers who worked with these things: preventing unwanted parasitic oscillations in circuits using these diodes must have been a serious consideration. This is also why I haven’t tried to build an amplifier with these diodes (yet). There’s an old adage that the easiest way to build an oscillator is to design an amplifier, and now I’m wondering if this saying really caught on during the tunnel-diode days.

To measure this faster oscillator, I constructed a smaller pickup loop on the end of the oscilloscope probe with a length of bare copper wire. Don’t be fooled by the perfect-looking sine wave shape of the output; it’s a 581 MHz signal measured on a 1 GHz scope, so there’s not enough bandwidth to show many distortions. They may or may not be present, but we can’t tell with this equipment. And, like with the previous oscillator, the random coupling of the probe loop creates an arbitrary amplitude scale, so you can’t compare the outputs of the two circuits.

Hard Lessons

Soldering heat sink can prevent thermal damage

These gallium arsenide diodes are as fragile as they are fascinating. Of the four diodes I used in these experiments, I destroyed two. The first one was simply a matter of applying too much voltage during curve tracing. The best approach is probably to start low — the active region is below 1 V with these devices — and advance slowly. The second casualty was a case of overheating. The datasheet cautions to heat the leads no more than 3 seconds to a temperature not exceeding 260 °C, and to use a heat sink between the diode body and the solder point on the leads. I read this after having overcooked one. I didn’t have the recommended 2 mm wide copper tweezers, but finally made do with a clamp-on aluminum sink I originally bought for soldering germanium components.

The diodes are also static sensitive, and the datasheet ominously warns not to test them with a diode tester. I had already tested one with the diode-test function on a DMM when I read this, and although the diode seems to have survived — at least it was not instantly destroyed — the tester didn’t register the diode in either polarity. So, use the diagram in the datasheet to determine which end is which.

The bottom line: if you play with these diodes, be careful and make sure to buy a few spares.

Whats Next?

So, that wraps up this brief hands-on series about negative resistance devices. Be sure to let us know in the comments if you have first-hand experience with these unusual diodes or similar parts, especially if you can get one to go much faster than 581 MHz. I really want to see one of these things scream.


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