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<table style="width:100%" class="tblblue"><tr><td class="hdrl">&nbsp;Elliott Sound Products</td>
<td align="right" class="hdrr">AN-018&nbsp;</td></tr></table>

<center><h1>Ultra-Low Leakage Diodes</h1>
<small>Rod Elliott (ESP)</small></center>

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<b>Description</b>
<p>It's not all that often that you need a diode with ultra-low reverse leakage.&nbsp; A typical 1N4148 diode has a reverse leakage of between 1 and 1.5G&Omega; (at 25&deg;C) with a reverse voltage of 10V, and this is sufficient for most common applications.&nbsp; Of course, you can buy diodes that are fully specified for low leakage.&nbsp; The BAS716 is rated for 5nA reverse current at 75V, which works out to 15G&Omega;.&nbsp; The BAS454A is better still, with 1nA reverse leakage at 125V (125G&Omega;).&nbsp; This increases to 500nA at a junction of 125&deg;C (only 125M&Omega;) - it's highly temperature dependent (as with <i>all</i> diodes).&nbsp; You may find that some specialised types are rather expensive and/ or difficult to get from your local supplier.&nbsp; You will need to run your own tests, using the technique described in <a href="an016.htm" target="_blank">AN-016</a> to measure leakage resistance.</p>

<p>For these tests, I would normally use a test voltage of 10V, but I used a voltage of 25V because that made it a little more likely that I'd be able to measure something - however small.&nbsp; As it transpired, it made no difference if I'd used 10V or 25V (25V is at or below the collector-base or gate-source breakdown voltage for the BJTs and JFETs I tested).&nbsp; This was because the leakage was so low that I was unable to measure anything - even at the higher voltage.&nbsp; My bench meter has an input impedance of 11M&Omega;, so if I measure 1mV, the current through the meter is 9.09pA (Ohm's law).</p>

<p>Provided you have low current requirements, the collector-base junction of an ordinary bipolar transistor is very good indeed.&nbsp; I tested a number of BC546 transistors, and was unable to measure <i>any</i> reverse leakage (and my bench meter can (theoretically) resolve to 0.1mV).&nbsp; It didn't matter if the supply was connected or not, the meter steadfastly showed &plusmn;0.0002 (normal digit uncertainty for my multimeter).&nbsp; Even if I <i>did</i> manage get a reading of 10mV on my meter, that still represents a leakage resistance of 25G&Omega;!&nbsp; However, I was unable to measure <i>anything !</i>&nbsp; When the transistor was heated I was able to measure some leakage current, but it was (literally) too hot to touch before leakage exceeded 1nA (25G&Omega;).</p>

<p>The drawing shows both a BJT (bipolar junction transistor) and a JFET (junction FET) used as diodes, with the diode symbols showing the polarity.&nbsp; The use of 'K' for cathode is standard nomenclature in case you were wondering, because 'C' is reserved for the collector of a transistor.&nbsp; However, the use of 'K' predates transistors, and has been used for as long as I can remember.</p>

<p class="t-pic"><img src="an018-f1.gif" border="1" alt="Figure 1" /><br />Figure 1 - NPN Transistor And N-Channel JFET As Low Leakage Diode</p>

<p>It's not uncommon to see JFETs specified for very low leakage diodes, but they usually aren't quite as good as a bipolar transistor.&nbsp; I tested a couple of 2N5459 JFETs (no longer available, but I had them in my parts drawer), and 'measured' a leakage current of about 45pA (~550G&Omega;).&nbsp; I say 'measured' in quotes because the value was so low, and I had to estimate the actual voltage displayed.&nbsp; However, this leakage increased very rapidly with heat, and it was no better than a 1N4148 even at a 'comfortable' temperature (I was unable to measure it, but I'd guess around 50&deg;C).</p>

<p>Note that the maximum current is low (equal to the peak base current of the transistor or gate current for a JFET), so this technique is only suitable for currents that are typical in 'signal level' circuits.&nbsp; The emitter and base of a BJT can be joined or not - it made no difference in the tests I performed, but I wouldn't be happy having a terminal floating in a very high impedance circuit.&nbsp; In general, the current should be no more than about 10mA (continuous), but short-term pulses with higher current will (probably) do no harm.&nbsp; I would be very reluctant to use a transistor or JFET at more than 25mA peak.&nbsp; The requirement for ultra-low leakage is common in sample-and-hold circuits, especially if the hold period is more than a few milliseconds.</p>

<p>The other thing that must be considered is the junction capacitance, as that affects the switching speed.&nbsp; A BC546 has a typical value of 3.5pF, with a maximum of 6pF (10V between collector and base), while the two low-leakage diodes quote around 2-4pF, with recovery times of 0.3 to 3&micro;s (which is pretty slow - a 1N4148 has a reverse recovery time of 4ns, almost an order of magnitude faster).&nbsp; This figure is not quoted for any transistor's collector-base junction, but can be assumed to be somewhat slower than a 1N4148, but faster than most low-leakage diodes.</p>

<p>Analog Devices show a diode-connected transistor in the OP77 datasheet, as part of a peak detector.&nbsp; They specified a 2N930, but there's no reason to expect that to be any better than the BC546 devices I tested.&nbsp; The collector cutoff current (collector to base voltage will be specified) is usually shown in datasheets as a 'worst case' value, and most will be far better than claimed.&nbsp; Leakage currents in the pA (pico-amps) range are common&nbsp;... at room temperature.&nbsp; Leakage current increases exponentially as temperature is raised, so expecting good performance at elevated temperatures is unwise.</p>

<p>Note that if you use any of these techniques, the circuitry should be on Teflon (PTFE) standoffs or wired in 'mid-air'.&nbsp; Even PCB leakage can seriously degrade the total resistance, and this may make your circuit no better than a common 1N4148 diode if you aren't very careful with the layout.</p>


<hr /><a id="ref"></a><b>References</b>
<p>Datasheets ...</p>
<ol>
	<li>BAS45A Low Leakage Diode
	<li>BAS716 Low Leakage Diode
	<li>BC546 Transistor
	<li>2N5459 JFET
	<li>OP77 Opamp
</ol>

<p>Some info can also be found on the Net, but there are many conflicting opinions and not much real information.</p>


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<tr><td class="t-wht"><a id="copyright"></a><b>Copyright Notice.</b>&nbsp; This article, including but not limited to all text and diagrams, is the intellectual property of Rod Elliott, and is &copy; 2019.&nbsp; Reproduction or re-publication by any means whatsoever, whether electronic, mechanical or electro-mechanical, is strictly prohibited under International Copyright laws.&nbsp; The author (Rod Elliott) grants the reader the right to use this information for personal use only, and further allows that one (1) copy may be made for reference.&nbsp; Commercial use is prohibited without express written authorisation from Rod Elliott.</td></tr>
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