TMCP
www.vishay.com
Vishay Polytech
MAXIMUM PERMISSIBLE POWER DISSIPATION AT +25 °C (W) IN FREE AIR
0.064
POWER DISSIPATION
CASE CODE
P
STANDARD PACKAGING QUANTITY
CASE CODE
P
UNITS PER 7" REEL
3000
PERFORMANCE CHARACTERISTICS
ITEM
CONDITION
POST TEST PERFORMANCE
Specified
initial value
Capacitance
change
-
6
8
Temperature
characteristics
Measure the specified characteristics in
each stage
Dissipation
factor (%)
10
12
20
30
Leakage
current
Solder dip:
260 °C ± 5 °C 10 s ± 1 s
Reflow:
260 °C 10 s ± 1 s
Leave at 40 °C and
90 % to 95 % RH for 500 h
Refer to
Standard
Ratings
table
-55 °C
-20 % to 0 %
10
12
14
16
24
60
-
+85 °C
0 % to +20 %
8
10
12
14
22
30
1000 %
specified
intial value
or less
+125 °C
0 % to +20 %
10
12
14
16
24
40
1250 %
specified
intial value
or less
Capacitance change
Dissipation factor
Leakage current
Capacitance change
Dissipation factor
Leakage current
Capacitance change
Within ± 20 % of initial value
Initial specified value or less
Initial specified value or less
Within ± 20 % of initial value
Shall not exceed 150 % of initial specified value
Initial specified value or less
Within ± 20 % of initial value
Initial specified value or less
Shall not exceed 200 % of initial specified value
Within ± 20 % of initial value
Initial specified value or less
Initial specified value or less
Within ± 20 % of initial value or less
Shall not exceed 150 % of initial specified value
Shall not exceed 200 % of initial specified value
Solder heat
resistance
Moisture
resistance
no load
High
temperature
load
85 °C. The rated voltage is applied for
2000 h
Leave at -55 °C, normal temperature,
125 °C, and normal temperature for
30 min, 3 min, 30 min, and 3 min.
Repeat this operation 5 times running
Leave at 40 °C and 90 % to 95 % RH
The rated voltage is applied for 500 h
85 °C. The rated voltage is applied
through a protective resistor of 1
/V.
Dissipation factor
Leakage current
Capacitance change
Dissipation factor
Leakage current
Capacitance change
Dissipation factor
Leakage current
1 % / 1000 h
Thermal shock
Moisture
resistance
load
Failure rate
Note
• Test conditions per JIS C5101-1
Revision: 16-Jan-17
Document Number: 40179
4
For technical questions, contact:
polytech@vishay.com
THIS DOCUMENT IS SUBJECT TO CHANGE WITHOUT NOTICE. THE PRODUCTS DESCRIBED HEREIN AND THIS DOCUMENT
ARE SUBJECT TO SPECIFIC DISCLAIMERS, SET FORTH AT
www.vishay.com/doc?91000
Molded Guide
www.vishay.com
Vishay Polytech
Guide for Tantalum and Niobium
Solid Electrolyte Chip Capacitors
INTRODUCTION
Tantalum electrolytic capacitors are the preferred choice in
applications where volumetric efficiency, stable electrical
parameters, high reliability, and long service life are primary
considerations. The stability and resistance to elevated
temperatures of the tantalum / tantalum oxide / manganese
dioxide system make solid tantalum capacitors an
appropriate choice for today's surface mount assembly
technology.
Vishay Sprague has been a pioneer and leader in this field,
producing a large variety of tantalum capacitor types for
consumer, industrial, automotive, military, and aerospace
electronic applications.
Tantalum is not found in its pure state. Rather, it is
commonly found in a number of oxide minerals, often in
combination with Columbium ore. This combination is
known as “tantalite” when its contents are more than
one-half tantalum. Important sources of tantalite include
Australia, Brazil, Canada, China, and several African
countries. Synthetic tantalite concentrates produced from
tin slags in Thailand, Malaysia, and Brazil are also a
significant raw material for tantalum production.
Electronic applications, and particularly capacitors,
consume the largest share of world tantalum production.
Other important applications for tantalum include cutting
tools (tantalum carbide), high temperature super alloys,
chemical processing equipment, medical implants, and
military ordnance.
Vishay Sprague is a major user of tantalum materials in the
form of powder and wire for capacitor elements and rod and
sheet for high temperature vacuum processing.
Rating for rating, tantalum capacitors tend to have as much
as three times better capacitance / volume efficiency than
aluminum electrolytic capacitors. An approximation of the
capacitance / volume efficiency of other types of capacitors
may be inferred from the following table, which shows the
dielectric constant ranges of the various materials used in
each type. Note that tantalum pentoxide has a dielectric
constant of 26, some three times greater than that of
aluminum oxide. This, in addition to the fact that extremely
thin films can be deposited during the electrolytic process
mentioned earlier, makes the tantalum capacitor extremely
efficient with respect to the number of microfarads available
per unit volume. The capacitance of any capacitor is
determined by the surface area of the two conducting
plates, the distance between the plates, and the dielectric
constant of the insulating material between the plates.
COMPARISON OF CAPACITOR
DIELECTRIC CONSTANTS
DIELECTRIC
Air or vacuum
Paper
Plastic
Mineral oil
Silicone oil
Quartz
Glass
Porcelain
Mica
Aluminum oxide
Tantalum pentoxide
Ceramic
e
DIELECTRIC CONSTANT
1.0
2.0 to 6.0
2.1 to 6.0
2.2 to 2.3
2.7 to 2.8
3.8 to 4.4
4.8 to 8.0
5.1 to 5.9
5.4 to 8.7
8.4
26
12 to 400K
THE BASICS OF TANTALUM CAPACITORS
Most metals form crystalline oxides which are
non-protecting, such as rust on iron or black oxide on
copper. A few metals form dense, stable, tightly adhering,
electrically insulating oxides. These are the so-called “valve”
metals and include titanium, zirconium, niobium, tantalum,
hafnium, and aluminum. Only a few of these permit the
accurate control of oxide thickness by electrochemical
means. Of these, the most valuable for the electronics
industry are aluminum and tantalum.
Capacitors are basic to all kinds of electrical equipment,
from radios and television sets to missile controls and
automobile ignitions. Their function is to store an electrical
charge for later use.
Capacitors consist of two conducting surfaces, usually
metal plates, whose function is to conduct electricity. They
are separated by an insulating material or dielectric. The
dielectric used in all tantalum electrolytic capacitors is
tantalum pentoxide.
Tantalum pentoxide compound possesses high-dielectric
strength and a high-dielectric constant. As capacitors are
being manufactured, a film of tantalum pentoxide is applied
to their electrodes by means of an electrolytic process. The
film is applied in various thicknesses and at various voltages
and although transparent to begin with, it takes on different
colors as light refracts through it. This coloring occurs on the
tantalum electrodes of all types of tantalum capacitors.
Revision: 11-Apr-16
In the tantalum electrolytic capacitor, the distance between
the plates is very small since it is only the thickness of the
tantalum pentoxide film. As the dielectric constant of the
tantalum pentoxide is high, the capacitance of a tantalum
capacitor is high if the area of the plates is large:
eA
C
=
------
-
t
where
C = capacitance
e = dielectric constant
A = surface area of the dielectric
t = thickness of the dielectric
Tantalum capacitors contain either liquid or solid
electrolytes. In solid electrolyte capacitors, a dry material
(manganese dioxide) forms the cathode plate. A tantalum
lead is embedded in or welded to the pellet, which is in turn
connected to a termination or lead wire. The drawings show
the construction details of the surface mount types of
tantalum capacitors shown in this catalog.
Document Number: 40218
1
For technical questions, contact:
tantalum@vishay.com
THIS DOCUMENT IS SUBJECT TO CHANGE WITHOUT NOTICE. THE PRODUCTS DESCRIBED HEREIN AND THIS DOCUMENT
ARE SUBJECT TO SPECIFIC DISCLAIMERS, SET FORTH AT
www.vishay.com/doc?91000
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