Tantalum - Polymer Capacitors

Part Number	Description / PDF	Quantity
T540B107M003BH8510WAFL KEMET	CAP TANT POLY 100UF 3V 1411	0
T540D477M003AH8705WAFL KEMET	CAP TANT POLY 470UF 3V 2917	0
T540D687K003BH87057280 KEMET	CAP TANT POLY 680UF 3V 2917	0
T541X108M003DH8705 KEMET	CAP TANT POLY 1000UF 3V 2917	0
M551B507K025AS KEMET	CAP TANT POLY 500UF 25V CHAS MNT	0
T550B256M100TH4252 KEMET	CAP TANT POLY 25UF 100V AXIAL	0
T540D107K016AH85057280 KEMET	CAP TANT POLY 100UF 16V 2917	0
T541X686K030DH8610 KEMET	CAP TANT POLY 68UF 30V 2917	0
T551B206M060AT4251 KEMET	CAP TANT POLY 20UF 60V AXIAL	0
T521B475M035ATE150 KEMET	CAP TANT POLY 4.7UF 35V 1411	0
T540B107K004CH8610WAFL KEMET	CAP TANT POLY 100UF 4V 1411	0
T520V157M004ATE025 KEMET	CAP TANT POLY 150UF 4V 2917	0
T540B476K006AH8710WAFL KEMET	CAP TANT POLY 47UF 6.3V 1411	0
T525D107M010ATE055 KEMET	CAP TANT POLY 100UF 10V 2917	1313
T540D687M003CH87057610 KEMET	CAP TANT POLY 680UF 3V 2917	0
T540D687K003BH8505 KEMET	CAP TANT POLY 680UF 3V 2917	0
T540B336K010AH85107610 KEMET	CAP TANT POLY 33UF 10V 1411	0
T540D477M003CH8505WAFL KEMET	CAP TANT POLY 470UF 3V 2917	0
T541X337K016AT8620 KEMET	CAP TANT POLY 330UF 16V 2917	0
T541X687K004BT8505 KEMET	CAP TANT POLY 680UF 4V 2917	0

Tantalum - Polymer Capacitors

1. Overview

Tantalum polymer capacitors are a type of electrolytic capacitor utilizing conductive polymer as the electrolyte and tantalum metal as the anode. Compared to traditional liquid-electrolyte tantalum capacitors, they offer lower equivalent series resistance (ESR), higher thermal stability, and longer operational lifespan. Their ability to deliver stable capacitance in compact packages makes them critical components in modern electronics for power management, noise filtering, and energy storage.

2. Main Types and Functional Classification

Type	Functional Features	Application Examples
Solid Polymer Electrolyte	Ultra-low ESR (<10m ), high ripple current tolerance	High-frequency DC-DC converters
Hybrid Polymer-Electrolyte	Combines polymer and liquid electrolyte for cost-performance balance	Consumer electronics power supplies
High-Voltage Polymer	Rated voltage >25V with enhanced dielectric strength	Industrial motor drives

3. Structure and Composition

Typical construction includes:

Anode: Sintered tantalum pellet with porous structure
Dielectric: Thin Ta₂O₅ layer formed via anodization
Electrolyte: Conductive polymer (e.g., PEDOT:PSS) coating
Cathode: Graphite/silver layered termination

The porous anode structure maximizes surface area while the polymer electrolyte provides solid-state reliability.

4. Key Technical Specifications

Parameter	Significance
Capacitance Range: 10 F - 1000 F	Determines energy storage capacity
Rated Voltage: 2.5V - 50V	Defines maximum operational voltage
ESR: <20m typical	Impacts power efficiency and thermal performance
Leakage Current: <0.01C*V	Affects battery-powered device standby consumption
Operating Temperature: -55 C to +125 C	Ensures reliability in harsh environments

5. Application Fields

Consumer Electronics: Smartphone power management modules
Automotive: Engine control units (ECUs) and ADAS systems
Industrial: Programmable logic controllers (PLCs)
Medical: Portable diagnostic equipment power filtering
Telecom: 5G base station RF amplifiers

6. Leading Manufacturers and Products

Manufacturer	Product Series	Key Features
Vishay	T55 Series	2000 hours life at 105 C
AVX	TACMIC	Military-grade vibration resistance
KEMET	A700 Series	Automotive AEC-Q200 qualified

7. Selection Guidelines

Key considerations:

Capacitance-voltage (CV) product must exceed circuit requirements by 20%
ESR requirements for high-frequency noise suppression
Package size constraints (e.g., 3216 vs 7343)
Temperature derating: Reduce rated voltage by 30% at 125 C
Failure mode analysis for safety-critical applications

8. Industry Trends

Emerging developments include:

Nano-structured polymer electrolytes enabling 30% higher capacitance density
Low-flammability materials for EV battery management systems
Embedded capacitor technology for 5G RF modules
AI-driven accelerated life testing methods

Market demand is projected to grow at 6.2% CAGR through 2030, driven by automotive electrification and IoT device proliferation.