Polymer capacitors gained popularity in the 2000s. They have been used primarily in electronic equipment where high performance and reliability are essential. Key applications include computer motherboards, medical, aerospace, consumer and industrial electronics, and automotive electronics. In automotive electronics, polymer hybrid capacitors are booming. AEC-Q200s are used in engine control units, infotainment systems, and other critical components that require a stable power supply and high reliability.
Polymer technology
Polymer capacitors are a subset of electrolytic capacitors. The term “electrolytic capacitors” is derived from the use of an electrochemically formed oxide film on the electrode surface, which acts as a dielectric. Various metals, including aluminum (Al), tantalum (Ta), niobium (Nb), titanium (Ti), zirconium (Zr), hafnium (Hf), and others, can form a thin, highly insulating oxide. However, only three metals – aluminum, tantalum, and niobium – are currently in practical use.
The oxide film formed on the surface of the electrode becomes an electrical insulator and functions as a dielectric only when the electrode on which it is formed serves as the anode. Therefore, electrolytic capacitors are, in principle, polarity capacitors.
There are two main types of polymer capacitors – aluminum electrolyte and tantalum capacitors – which will be discussed in the next sections. Conductive polymers are also used in aluminum capacitors to replace the wet electrolyte. These capacitors have a much lower equivalent series resistance (ESR) and do not dry out over time. The main applications of polymer capacitors are in DC-DC conversion/decoupling and automotive power distribution applications.
Aluminum electrolytic capacitors
Aluminum electrolytic capacitors are polarized capacitors in which the anode and cathode are made of aluminum. They can have either a wet electrolyte, a solid conductive polymer, or a hybrid (wet and solid conductive polymer) electrolyte. If these capacitors are polarized, they should not be used in the presence of reverse bias.
In aluminum electrolytic capacitors, both electrodes are made of aluminum. The aluminum anode is separated from the wet electrolyte by an oxide layer, which is a paper foil saturated with the wet electrolyte. Different types of electrolytes enhance oxidation, operate at higher temperature ranges, and absorb gases that may form internally. The other aluminum plate, which serves as the cathode, is also present. The robustness of the anode aluminum foil depends on whether the capacitor must withstand higher voltages.
The construction of the polymer capacitor is strikingly similar. It consists of an anode and a cathode, both made of aluminum foil. The dielectric is a layer of aluminum oxide (Al2O3) that acts as an insulator between the anode and the conductive polymer. A non-conductive layer (paper, film, or other insulating material) is placed between the conductive polymer, forming two layers of conductive polymer. Finally, a drying and aging process of up to eight hours is performed.
Hybrid aluminum polymer capacitors combine the characteristics of both traditional aluminum electrolytic capacitors and polymer capacitors, taking advantage of each type. The dielectric is a mixture of liquid electrolyte and conductive polymers. The liquid electrolyte helps improve performance at lower frequencies and increases overall capacitance.
Self-healing process maintains performance and extends service life
Small defects such as pinholes, microcracks, or areas of dielectric breakdown can form in the Al oxide layer due to electrical stress, thermal cycling, or mechanical strain. These defects create pathways for leakage current that can degrade capacitor performance. When a defect causes an increase in leakage current, the localized area around the defect heats up. The conductive polymer layer reacts to this heat. The heat can cause the polymer to temporarily lose its conductivity in the localized area, effectively isolating the defect. The heat also promotes regeneration of the alumina dielectric layer at the defect site. This can occur by oxidation of the exposed aluminum at the defect site, where the aluminum reacts with oxygen (often from the polymer or the environment) to form new alumina. The combined effect of polymer reaction and oxide regeneration seals the defect and restores dielectric integrity. As the defect is sealed, the leakage current decreases and the capacitor resumes normal operation. In hybrid capacitors, the presence of the liquid electrolyte enhances the self-healing process by allowing the aluminum oxide layer to reform more efficiently. Both types of capacitors rely on these self-healing mechanisms to maintain performance and extend service life.
The key drivers for various aluminum polymer capacitors are listed in Table 1.
Table 1: Key drivers of various aluminum polymer capacitors
| Key drivers | Aluminum wet electrolytic capacitors | Aluminum polymer capacitors | Hybrid capacitors |
| Lifetime | Decreasing the temperature by 10 °C doubles the lifespan | Lifetime increases tenfold when the temperature drops by 20 °C | It is calculated in the same way as for the electrolytic wet capacitor |
| Derating voltage | Derating is not required, but may increase lifespan; wet electrolytic capacitors can operate at 70% to 80% of the rated voltage, while hybrid and solid electrolytic capacitors can operate at 80% to 90% of the rated voltage | ||
| Rating voltage | Rating voltages of up to 450 V; high-voltage aluminum electrolytic capacitors available with ratings that can reach or even exceed 600 V | Rating voltages of up to 63 V, versions with up to 100 V available; trend is toward higher voltage ratings
| Versions with rating up to 125 V available |
| DC BIAS | No DC-BIAS influence | ||
| ESR | Typical ESR down to 20 mΩ; trend toward decreasing ESR | Ultra-low ESR, down to 5 mΩ | Between wet and solid, ESR about 11 mΩ |
| Ripple current | Not the best capability; electrolytic capacitors cannot withstand very high ripple currents | Very good ripple capability due to low ESR | Good capability |
| Vibration | Good performance under vibrations | Aluminum electrolytic capacitors with solid polymer are more rigid and less capable of absorbing vibration, making them more susceptible to mechanical damage in high vibration environments. Some manufacturers offer reinforced series designed to withstand high vibration. | |
| Temperature | Max. temperature up to 105 °C, versions with max. temperature up to 125 °C available
| Max. temperature up to 125 °C | Trend to increase temperature up to 150 °C to extend lifetime |
| Capacitance stability vs. temperature and frequency | Poor high-frequency characteristics; capacitance drops significantly at 20 kHz; sensitive to temperature changes | Better high frequency performance; stable capacitance over a range of frequencies; capacitance drops significantly at 1 MHz; good temperature characteristics | |
| Leakage current | Electrolytic aluminum capacitors exhibit a higher leakage current compared to other technologies such as MLCC and plastic capacitors. The leakage current of an electrolytic capacitor is typically specified by the manufacturer and can be calculated using the empirical formula:
Manufacturers’ data sheets provide accurate information on leakage current, although the exact formula and constants may vary from manufacturer to manufacturer | ||
Tantalum electrolytic capacitors
Tantalum capacitors are polarized capacitors that use a solid electrolyte such as manganese dioxide (MnO₂) or conductive polymer. However, care should be taken when applying reverse bias to this type of capacitor. The most notable properties of tantalum include high ductility, high corrosion resistance, high melting point (3,020 °C), high heat and wear resistance, and high biocompatibility. Tantalum capacitors can replace MLCC (multilayer ceramic capacitor) capacitors in certain applications, subject to specific application criteria.
Solid tantalum capacitors
Solid tantalum (Ta) capacitors use manganese dioxide as the cathode due to its self-healing properties. When defects occur in the dielectric, it becomes non-conductive. The tantalum is separated from the manganese dioxide by an oxide layer called tantalum pentoxide (Ta₂O₅). When this layer is reduced, the manganese dioxide oxidizes the tantalum, forming a new oxide layer. As a result, these capacitors exhibit exceptional reliability with virtually infinite life.
The self-healing process can potentially release oxygen, which in extreme cases can lead to combustion. Nevertheless, tantalum capacitors are well suited for applications that require operation at higher temperatures.
In these capacitors, the conductive surface area significantly affects the capacitance (directly proportional), while the dielectric thickness inversely affects the capacitance. Despite their thinness, tantalum capacitors are robust (dielectric breakdown: 470 V/mm), allowing for relatively high voltage applications.
Table 2: Comparison of dielectric thickness between tantalum (Ta) and MLCC capacitors
VR | Dielectric thickness (nm) | |
Ta | MLCC | |
2 | 20.7 | 600 |
4 | 27.6 | 600 |
6 | 36.8 | 600 |
Table 2 illustrates a comparison of dielectric thickness between Ta and MLCC capacitors. Notably, MLCC capacitors require a larger surface area and size to achieve high capacitance due to their thicker dielectric.
Tantalum solid conductive polymer
Conductive polymers began replacing MnO₂ in tantalum capacitors in the mid-1990s due to the higher conductivity of these polymers, which results in a significantly lower equivalent series resistance (ESR). The transition from MnO₂ to conductive polymers offers several notable advantages, one of which is the self-healing mechanism.
If a dielectric breakdown occurs during operation (resulting in a short circuit or leakage path), the high current density at the defect site causes localized heating. This heat causes the conductive polymer to oxidize, rendering it non-conductive and effectively sealing the defect. This oxidation restores the insulating properties, preventing further failure and allowing the capacitor to continue operating. Notably, these capacitors are considered safer because their self-healing process does not generate oxygen, minimizing the risk of inflammation, as shown in Fig. 2. The main applications are DC-DC voltage rail converters. The key drivers of different tantalum capacitors are listed in Table 3.
Table 3: Key drivers of different tantalum capacitors
| Key drivers | Tantalum MnO2 | Tantalum polymer |
| Derating voltage | Requires a derating voltage of approx. 50% | 10% applied voltage lower than 10 V 20% applied voltage higher than 10 V |
| Frequency behavior | Do not perform well at high frequencies; capacitance drops significantly at 10 kHz. | Good characteristics at high frequencies, especially around 100 kHz; if performance at 1 MHz is required, MLCCs are the best choice |
| Wear out mechanism / lifetime | Unlimited lifetime without aging | The cathode material wears out due to moisture and oxidation. As a result, the components will gradually degrade over time. The only way to prevent this degradation is to use hermetic packaging |
| Capacitance volume and energy density efficiency | Maximize capacitance per volume and energy density; achieve higher capacitance in smaller volumes and at higher voltages than other technologies | |
ERS, ripple current and leakage current
| The polymer has a significantly lower ESR than MnO₂, allowing it to handle high ripple current. However, both tantalum polymer and MnO₂ have higher leakage currents than other technologies. Tantalum capacitors are not suitable when low leakage current is essential for maximum battery performance | |
| Robustness and piezo noise | Do not crack when bent, similar to; no piezo noise | |
Weaknesses of tantalum polymer
Tantalum polymer capacitors offer several advantages over traditional electrolytic capacitors, making them desirable for various applications. However, they do have some drawbacks and cannot be used in all scenarios.
The use of polymer capacitors is not recommended for frequencies approaching or exceeding 1 MHz, temperatures exceeding 150 °C, or where maximum battery life depends on low leakage current.
Polymer capacitors are not suitable if the voltage is greater than 48 V DC, the application requires ultra-low ESR (<< 4 mΩ), low capacitance (<0.68 µF), or reverse bias.
Conclusion
Polymer capacitors offer low ESR, high stability and reliability, high ripple current handling, improved safety, enhanced low voltage performance, and better frequency characteristics. The use of polymer capacitors in electronic circuits improves performance, reliability, and durability, making them a popular choice in modern electronics.
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