WASC Series, Silicon Capacitors

Results:
9
Manufacturer
Series
Size / Dimension
Capacitance
Package / Case
Height
Applications
Features
Operating Temperature
ESL (Equivalent Series Inductance)
Tolerance
Voltage - Breakdown
ESR (Equivalent Series Resistance)
Results remaining9
Applied Filters:
WASC
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ImageProduct DetailPriceAvailabilityECAD ModelFeaturesToleranceCapacitanceOperating TemperatureVoltage - BreakdownESL (Equivalent Series Inductance)ApplicationsPackage / CaseHeightSize / DimensionESR (Equivalent Series Resistance)Series
935148522310-W0T
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Quantity
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PCB Symbol, Footprint & 3D Model
-
-
100 pF
-55°C ~ 150°C
150 V
-
High Stability, Vertical Silicon Cap, Wirebond
Nonstandard Chip
0.005" (0.12mm)
0.010" L x 0.010" W (0.25mm x 0.25mm)
-
WASC
935247520427-T3T
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Quantity
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PCB Symbol, Footprint & 3D Model
-
-
2700 pF
-55°C ~ 150°C
150 V
-
High Stability, Vertical Silicon Cap, Wirebond
Nonstandard Chip
0.010" (0.25mm)
0.020" L x 0.079" W (0.50mm x 2.00mm)
-
WASC
935147521410-T3T
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Quantity
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PCB Symbol, Footprint & 3D Model
-
-
1000 pF
-55°C ~ 150°C
150 V
-
High Stability, Vertical Silicon Cap, Wirebond
0202 (0505 Metric)
0.010" (0.25mm)
0.020" L x 0.020" W (0.50mm x 0.50mm)
-
WASC
935148521410-T3T
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Quantity
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PCB Symbol, Footprint & 3D Model
-
-
1000 pF
-55°C ~ 150°C
150 V
-
High Stability, Vertical Silicon Cap, Wirebond
0202 (0505 Metric)
0.004" (0.10mm)
0.020" L x 0.020" W (0.50mm x 0.50mm)
-
WASC
935248520427-T3T
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Quantity
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PCB Symbol, Footprint & 3D Model
-
-
2700 pF
-55°C ~ 150°C
150 V
-
High Stability, Vertical Silicon Cap, Wirebond
Nonstandard Chip
0.004" (0.10mm)
0.020" L x 0.079" W (0.50mm x 2.00mm)
-
WASC
935247521437-T3T
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Quantity
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PCB Symbol, Footprint & 3D Model
-
-
3700 pF
-55°C ~ 150°C
150 V
-
High Stability, Vertical Silicon Cap, Wirebond
Nonstandard Chip
0.004" (0.10mm)
0.020" L x 0.064" W (0.50mm x 1.63mm)
-
WASC
935248521437-T3T
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Quantity
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PCB Symbol, Footprint & 3D Model
-
-
3700 pF
-55°C ~ 150°C
150 V
-
High Stability, Vertical Silicon Cap, Wirebond
0402 (1005 Metric)
0.016" (0.41mm)
0.047" L x 0.028" W (1.20mm x 0.70mm)
-
WASC
935247522447-T3T
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Quantity
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PCB Symbol, Footprint & 3D Model
-
-
4700 pF
-55°C ~ 150°C
150 V
-
High Stability, Vertical Silicon Cap, Wirebond
Nonstandard Chip
0.004" (0.10mm)
0.020" L x 0.064" W (0.50mm x 1.63mm)
-
WASC
935248522447-T3T
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Quantity
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PCB Symbol, Footprint & 3D Model
High Reliability
-
4700 pF
-55°C ~ 150°C
150 V
-
High Stability
0201 (0603 Metric)
0.016" (0.41mm)
0.031" L x 0.024" W (0.80mm x 0.60mm)
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WASC

About  Silicon Capacitors

Silicon and thin-film capacitors are specialized devices that are manufactured using tools, methods, and materials commonly associated with semiconductor device production. This enables the production of capacitors with near-ideal characteristics and exceptional parameter stability. However, these capacitors have a limited range of available values and tend to be more expensive compared to ceramic-based capacitors, which are their primary competitors. The manufacturing process of silicon and thin-film capacitors allows for extreme precision and control over the production parameters. This results in capacitors that exhibit excellent stability in terms of capacitance, voltage ratings, and other electrical properties. They are designed to maintain their specified values over time and under varying conditions, making them ideal for applications that require precise and reliable performance. Despite their advantages, silicon and thin-film capacitors have a relatively narrow range of available capacitance values compared to ceramic-based capacitors. This limitation may restrict their use in certain applications that require a broader range of capacitance options. Furthermore, the cost of manufacturing silicon and thin-film capacitors is generally higher due to the specialized processes and materials involved. As a result, these capacitors are often considered more expensive compared to ceramic-based alternatives. In summary, silicon and thin-film capacitors are produced using semiconductor manufacturing techniques, allowing for the creation of capacitors with near-ideal characteristics and excellent parameter stability. While they have a limited range of capacitance values, they are well-suited for applications that demand precise and reliable performance. However, their higher cost compared to ceramic-based capacitors is an important consideration when selecting the appropriate capacitor for a given application.