I am doing some research on the different kinds of capacitors.

Here is my brief understanding of the use cases for each kind of capacitor:

Aluminum Electrolytic: Filtering low frequency, high current signals (such as rectified line voltage.)

  1. low ESR at low frequencies (100Hz), therefore high ripple current rating
  2. Easy to manufacture large capacitance values with high voltage ratings

Aluminum Polymer: Filtering high frequency, high current signals

  1. Low ESR at high frequencies (100KHz) means high ripple current rating
  2. Easy to manufacture large capacitance values with high

Ceramic: Bypass/noise filtering capacitor

  1. Low ESR and good frequency response across broad frequency range
  2. Small package sizes available

Tantalum: [USE CASE]

  • 3
    \$\begingroup\$ When you need more capacitance than a ceramic but better frequency response than an electrolytic. I would not consider 100kHz high frequency. That's pretty darn low. Just barely high enough that you may get away with using only polymer caps for switching converters. \$\endgroup\$
    – DKNguyen
    Commented Mar 27, 2022 at 3:29
  • \$\begingroup\$ Can you give an example? When would you need such a high capacitance AND good frequency response? \$\endgroup\$ Commented Mar 27, 2022 at 3:32
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    \$\begingroup\$ 1-10uF used to be difficult to find, expensive, or non-existent in ceramic caps so the only choice was tantalum. There isn't as much as a need for them as there once was. They also don't suffer from piezo effects or DC bias like most ceramic dielectrics. You also need to differentiate between actual signal filtering and power supply filtering. There's a difference because in signal filtering you need to preserve signal integrity and the filter needs to have stable performance and not introduce artifacts like piezo. In power supply filtering (or decoupling) you can be a lot looser. \$\endgroup\$
    – DKNguyen
    Commented Mar 27, 2022 at 3:59
  • 2
    \$\begingroup\$ I’m voting to close this question because this is clearly a homework question. We aren't here to do your basic reading for you. \$\endgroup\$
    – Graham
    Commented Mar 27, 2022 at 14:28
  • 4
    \$\begingroup\$ @graham if you didn't know the answer to the question, you could just say that... \$\endgroup\$ Commented Mar 27, 2022 at 17:15

3 Answers 3


Let’s start with some of the advantages of tantalum capacitors

  1. They have relatively good stability across frequency, voltage, and temperature range compared to electrolytic and ceramic capacitors
  2. They don’t have the piezoelectric properties that you’ll find in ceramic capacitors which makes them vibrate, sometimes causing audible noise.
  3. If used under proper conditions, tantalum capacitors can be highly reliable.
  4. Tantalum capacitors can have a high density of capacitance.

This leads to the following four use cases:

  1. Applications that require high stability.
  2. Applications that require no buzzing or other piezoelectric artifacts from the capacitors.
  3. Applications that require high reliability.
  4. Applications that require a high capacitance in a small form factor.

Tantalum capacitors are typically used where more than one of these apply.

A note on number 3:

Many engineers are averse to using tantalum capacitors because one of their failure modes is short circuit which can cause fires (or even in some cases explosions!). If the designer however considers this and accounts for it by reducing the stress on the capacitor both in normal function and considering the possible failure modes of other parts in the circuit, the probability of this type of failure is very small. Reducing stress includes keeping ripple currents, temperatures, and voltages well below the rated values.

You may find it interesting that despite the exciting failure mode for solid tantalum capacitors, even NASA allows them to be used on their spacecraft which are supposed to be about as reliable as something can be. They do however have steep requirements on their use cases: voltage must be derated 50%, and they must have at least 0.1 ohm ESR per volt or 1 ohm, whichever is greater, for grade 2 applications (see NASA’s EEE-INST-002 “Instructions for EEE Parts Selection, Screening, Qualification, and Derating”).

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    \$\begingroup\$ The other negative is tantalum is considered a 'conflict mineral' where the mining and sale is used to fund military action. \$\endgroup\$
    – Kartman
    Commented Mar 27, 2022 at 5:34
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    \$\begingroup\$ Molded polymer tantalum capacitors can be used at medium pressures. I've tested surface mount versions to 600 bars (about 8,700 psi), and routinely use them at 400 bars. I would assume they are also useful in vacuum. You can use molded polymer tantalum capacitors in fluid environments. In the above environments, AL electrolytic capacitors will fail. \$\endgroup\$
    – qrk
    Commented Mar 31, 2022 at 6:41

I would note that there are actually two very different types of tantalum capacitors, and information about one is not applicable to the other.

NASA did extensive research on wet tantalum capacitors which are not the same thing as the widely available SMD tantalum capacitors and anything said about wet tantalum capacitors is irrelevant to the more familiar ones you are probably talking about.

The primary usage case for the commercial plastic encapsulated SMD or plastic dip leaded tantalum capacitors we're probably all familiar with really comes down to two things:

  • When you need a lot of capacitance in the smallest volume possible. Tantalum capacitors 3 times the theoretical volumetric efficiency of the next best capacitor type for this, aluminum electrolytic. In practice, the margin is actually even more. Case in point: the sintered nugget of tantalum inside a 220uF 6.3V capacitor is only 1.6 cubic millimeters (0.0016mL). The plastic packaging itself takes up most of the space, not the actual capacitive element.

  • When you need longevity. Tantalum capacitors don't suffer dielectric degradation when stored discharged for too long like aluminum electrolytics will, nor do they dry out like aluminum electrolytic capacitors do (and they do sometimes very quickly if they get hot, most standard aluminum electrolytic capacitors are only rated for 2000h of service life at 85C).

Tantalum capacitors, simply put, have the highest volumetric efficiency of any capacitor type currently available, and when used correctly, will continue to work for a very long time even in high ambient temperatures.

As a designer, those are really the only two reasons one might choose to use them in modern designs. The polymer versions of them, while expensive, have excellent combinations of high capacitance, and ripple current capability in a small space, while tolerating constant heat much better than any other type of polymer capacitor. However, the often relatively high ESR of the cheaper standard types are actually often an advantage as it will limit in-rush current (which, with other capacitor types such as ceramic, even just 10uF can cause voltage spikes of 20-40V due to the brief inrush current and a power cable's self inductance), or helps to stabilize certain LDO Voltage regulators.

For many, they are often the quintessential lazy design choice. They're small, I know they will be good enough where they need to be good, and bad enough where they need to be bad, to be fairly safe to put in one or two spots in a design and be confident that they won't cause any unexpected problems ( unlike ceramic capacitors for example).

That said, they do have some disadvantages. And because of careless design, actually have a somewhat deserved reputation for being unreliable and having a propensity for fire.

Have you heard of thermite? It is a powder made of (at least) iron oxide and aluminum. It is flammable, but has a very high ignition temperature beyond what most flames can achieve, making it relatively safe and an important industrial tool. When ignited however, it burns incredibly hot - hitting 2500 °C or more. It is an reduction-oxidation reaction, with the oxygen in the iron oxide forming aluminum oxide and precipitating pure elemental (and definitely molten) iron.

Tantalum capacitors are typically constructed using tantalum metal and manganese dioxide, which will happily undergo this same kind of reduction-oxidation reaction as thermite. They need only reach the ignition temperature (which is much lower, around 900 °C) to release a ton of thermal energy evidenced by a jet of flame that briefly shoots out of the capacitor.

This kills the capacitor.

So this can happen in a vacuum, under water, really anywhere you didn't want fire, tantalum capacitors can, if used improperly, ensure you have fire there anyway!

The issue is that they are very sensitive to reverse voltage bias and can tolerate very little and not for very long before the layer of tantalum pentoxide serving as the dielectric barrier will fail, resulting in a short. Now factor in how the ESR is probably an ohm or a few, and you now have that value resistor connected directly across the power rails of your device.

Now recall that the pellet is probably quite small, like 1.6mm cubed for a 220uF capacitor as mentioned earlier. It will have no issues hitting 900 °C.

enter image description here

For this reason, you must be very careful to ensure that tantalum capacitors won't ever see any reverse bias. This can be done through careful design and often at even more cost by adding other components designed to protect the capacitor from reverse bias. If this is done correctly, then tantalum capacitors can last a very long time.

Wet tantalum capacitors are very different beasts and have a liquid electrolyte made of sulfuric acid inside. These are very expensive, prohibitively so, limiting their use to very specific applications, usually aerospace. They can be made to withstand higher voltages than commercial solid tantalum capacitors, and have even higher volumetric efficiency than solid tantalum's already impressive specs in the same.

They also have very different failure modes, they can dry out (but are usually hermetically sealed to prevent this - but it can still a problem). There is a NASA document that very thoroughly investigates them, but none of that information can be applied to the more familiar solid tantalum capacitors.


I've never used Ta caps so far. IMO, they are essentially Al polarized caps, but with higher density, higher price, higher ESR, potentially higher durability.

If you need none of these, an Al electrolytic cap will be better.

  • \$\begingroup\$ Tantalum capacitors have lower ESR compared to electrolytic capacitors \$\endgroup\$ Commented Nov 15, 2023 at 5:54
  • \$\begingroup\$ @bunker89320 Tantalum caps are electrolytic capacitors. Compared to Al, last time I checked most had higher ESR. There is some spread between manufacturers perhaps, so you might also find some with lower ESR (for the same capacitance), but regardless they are useless when you need a "low ESR" capacitor. \$\endgroup\$
    – tobalt
    Commented Nov 15, 2023 at 6:42

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