U.S. patent application number 09/726379 was filed with the patent office on 2001-06-07 for copper powder and process for producing copper powder.
This patent application is currently assigned to DOWA MINING CO., LTD.. Invention is credited to Miyoshi, Hiromasa, Okada, Yoshihiro, Sano, Kazushi, Takada, Yoshiomi.
Application Number | 20010002558 09/726379 |
Document ID | / |
Family ID | 18353724 |
Filed Date | 2001-06-07 |
United States Patent
Application |
20010002558 |
Kind Code |
A1 |
Sano, Kazushi ; et
al. |
June 7, 2001 |
Copper powder and process for producing copper powder
Abstract
A copper powder is provided that has an average particle
diameter in the range of from not less than 0.1 .mu.m to less than
1.5 .mu.m, that has a narrow particle size distribution width whose
value A defined by Equation (1) below in terms of X25, X50 and X75
defined below is not greater than 1.2, and that forms a
pseudo-fused sintered product when held at a temperature of
800.degree. C. under an atmosphere of inert gas at one atmosphere
pressure: A=(X75-X25)/X50 (1), where X25, X50 and X75 are values of
particle diameter X corresponding to Q% =25%, 50% and 75% on a
cumulative particle-size curve plotted in an orthogonal coordinate
system whose abcissa represents particle diameter X (.mu.m) and
ordinate represents Q% (ratio of particles present of a diameter
not greater than the corresponding value of X; expressed in units
of vol % of particles). The copper powder is produced by conducting
wet reduction of cuprous oxide into metallic copper powder in the
presence of ammonia or an ammonium salt. When used to form the
terminal electrodes of multi-layer capacitor, it enables the
electrodes to form into solid sintered bodies with few pores by
sintering at a low temperature.
Inventors: |
Sano, Kazushi; (Okayamashi,
JP) ; Okada, Yoshihiro; (Okayama-shi, JP) ;
Miyoshi, Hiromasa; (Okayama-shi, JP) ; Takada,
Yoshiomi; (Tokyo, JP) |
Correspondence
Address: |
McDERMOTT, WILL & EMERY
600 13th Street, N.W.
Washington
DC
20005-3096
US
|
Assignee: |
DOWA MINING CO., LTD.
|
Family ID: |
18353724 |
Appl. No.: |
09/726379 |
Filed: |
December 1, 2000 |
Current U.S.
Class: |
75/373 ;
361/500 |
Current CPC
Class: |
B22F 9/24 20130101; H01G
4/0085 20130101 |
Class at
Publication: |
75/373 ;
361/500 |
International
Class: |
H01G 009/00; B22F
009/00 |
Foreign Application Data
Date |
Code |
Application Number |
Dec 1, 1999 |
JP |
11-342435 |
Claims
What is claimed is:
1. In a process for producing copper powder comprising a step of
reacting an aqueous solution of a copper salt and an alkali to
precipitate copper hydroxide, thereby obtaining a suspension
containing copper hydroxide, a primary- reduction step conducted in
the suspension to reduce the copper hydroxide obtained to cuprous
oxide, a secondary-reduction step conducted in the suspension to
reduce the cuprous oxide obtained to metallic copper and a step of
separating the metallic copper from the suspension; the improvement
characterizing in that the suspension before or in the course of
the secondary-reduction step is contacted with ammonia or an
ammoniate.
2. A process according to claim 1, wherein the copper powder has an
average particle diameter of not greater than 1.2 .mu.m and is
non-agglomerative.
3. A process according to claim 1, wherein the ammonia or ammoniate
is contained in the suspension in an amount of 0.01-0.1 mole as
ammonia per mole of copper in the system.
4. A copper powder that has an average particle diameter in the
range of from not less than 0.1 .mu.m to less than 1.5 .mu.m, that
has a narrow particle size distribution width whose value A defined
by Equation (1) below in terms of X25, X50 and X75 defined below is
not greater than 1.2, and that forms a pseudo-fused sintered
product when held at a temperature of 800.degree. C. under an
atmosphere of inert gas at one atmosphere pressure: A=(X75-X25)/X50
(1), where X25, X50 and X75 are values of particle diameter X
corresponding to Q%=25%, 50% and 75% on a cumulative particle-size
curve plotted in an orthogonal coordinate system whose abscissa
represents particle diameter X (.mu.m) and ordinate represents Q%
(ratio of particles present of a diameter not greater than the
corresponding value of X; expressed in units of vol % of
particles).
5. A copper powder according to claim 4 whose average particle
diameter is in the range of 0.3-1.2 .mu.m and whose value A is not
greater than 1.0.
6. A copper powder according to claim 4 or 5 utilized in forming a
terminal electrode of a multi-layer ceramic capacitor by sintering
the powder under heating an electrical conductive past containing
the powder.
Description
BACKGROUND OF THE INVENTION
[0001] 1. Field of the Invention
[0002] This invention relates to a process for producing a copper
powder that exhibits little agglomeration despite small particle
diameter and to a copper powder enabling production of a pore-free
sintered product at a low sintering temperature.
[0003] 2. Background Art
[0004] Bonding or fixing conductive circuit members at desired
locations on an insulating board is commonly done using a
conductive paste. The conductive paste utilizes a powder of copper,
nickel, silver or the like as its conductive material. Copper paste
is widely used because copper powder is not only inexpensive but
also low in electrical resistance and resistant to migration.
[0005] Recently it is proposed to form a terminal electrode of
multi-layer ceramic capacitors by using an electrical conductive
past having a metal powder therein as a filler. In this case, the
conductive past is attached to the baked laminated ceramics of an
dielectric substance, then heated as a whole at temperatures
sufficient to occur the vaporization of vehicle component or the
decomposition of the resins of the paste and to sinter the residual
metal powder in the past thereby to form a terminal electrode. This
conductive paste also generally uses copper powder as its powder
component.
[0006] Known process of producing copper powder include the
mechanical pulverization process, atomization process of spraying
molten copper, electrolytic cathode deposition process, vapor
deposition process and the wet reduction process. The wet reduction
process is the main one used to produce copper powder for
conductive paste because it is superior to the others in the point
of enabling ready production of particles of uniformly small size.
Copper powder production processes using the wet reduction method
are taught by, for instance, Japanese Patent Publication JPA No.
4-116109 (1992), JPA No. 2-197012 (1990) and JPA No. 62-99406
(1987).
[0007] When the terminal electrodes of multi-layer ceramic
capacitors are formed by a copper paste made from conventional
copper powder, a sintering temperature higher than 800.degree. C.
is generally required to produce high-density conductors. This is
because at a temperature of 800.degree. C. or lower, the sintering
that occurs, if any, does not integrally bind the particles to a
degree sufficient to avoid a sintered body including many pores. It
is therefore impossible to obtain good conductors. The need to
employ a high sintering temperature exceeding 800.degree. C. (under
an inert atmosphere of 1 atmosphere) leads to the following
problems.
[0008] When heated to a temperature higher than 800.degree. C.,
multi-layered ceramics are, depending on their material, liable to
deteriorate and decrease the capacity by incurring cracks between
the ceramics and external electrode based on the shrinkage of the
past as to cause mismatch with the ceramics. This restricts the
selection of the ceramics material of the stacked boards.
[0009] Aside from these quality-related problems, high-temperature
sintering is also costly in terms of energy and facility costs
since it requires more heating energy, a longer heating period and
more expensive heating equipment, thus increasing production cost.
It also tends to lower yield.
[0010] The object of the present invention is therefore to provide
a copper powder enabling production of a solid sintered product
with few pores even at a low sintering temperature.
SUMMARY OF THE INVENTION
[0011] Through a concentrated study in search of a solution to the
aforesaid problem, the inventors succeeded in producing a copper
powder that is highly resistant to agglomeration despite its small
particle diameter and can therefore be used to produce a pore-free
sintered product (called a "pseudo-fused sintered product" in this
specification because, at first sight, it appears to have a
once-melted-down consistency) even at a sintering temperature of
not higher than 800.degree. C. Specifically, the inventors found
that in the wet reduction process it is possible to produce
small-particle-diameter copper powder of narrow particle-size
distribution and smooth particle surface (specific surface area
measured by the B.E.T. method being small for the particle
diameter) by bringing the suspension into the presence of ammonia
or an ammonium salt before or in the course of the secondary
reduction, and that the so-obtained copper powder is highly
resistant to agglomeration of the particles and therefore suitable
for low-temperature sintering.
[0012] Thus, the present invention provides a process for producing
copper powder comprising a step of reacting an aqueous solution of
a copper salt and an alkali to precipitate copper hydroxide,
thereby obtaining a suspension containing copper hydroxide, a
primary-reduction step conducted in the suspension to reduce the
copper hydroxide obtained to cuprous oxide, a secondary-reduction
step conducted in the suspension to reduce the cuprous oxide
obtained to metallic copper and a step of separating the metallic
copper from the suspension, the process characterizing in that the
suspension before or in the course of the secondary- reduction step
should be contacted with ammonia or an ammoniate.
[0013] This process according to the present invention produces a
copper powder that has an average particle diameter in the range of
from not less than 0.1 .mu.m to less than 1.5 .mu.m, that has a
narrow particle size distribution width whose value A defined by
Equation (1) below in terms of X25, X50 and X75 defined below is
not greater than 1.2, and that forms a pseudo-fused sintered
product when held at a temperature of 800.degree. C. under an
atmosphere of inert gas at one atmosphere pressure:
A=(X75-X25)/X50 (1),
[0014] where X25, X50 and X75 are values of particle diameter X
corresponding to Q% =25%, 50% and 75% on a cumulative particle-size
curve plotted in an orthogonal coordinate system whose abscissa
represents particle diameter X (.mu.m) and ordinate represents Q%
(ratio of particles present of a diameter not greater than the
corresponding value of X; expressed in units of vol % of
particles).
BRIEF EXPLANATION OF THE DRAWINGS
[0015] FIG. 1 is a helos particle-size distribution chart of copper
powder according to the present invention.
[0016] FIG. 2 is a scanning electron microscope (SEM) image of
copper powder according to the present invention.
[0017] FIG. 3 is an SEM image of a sintered product obtained by
sintering the copper powder according to this invention at
800.degree. C.
[0018] FIG. 4 is a helos particle-size distribution chart of a
copper powder according to a comparative example.
[0019] FIG. 5 is an SEM image of a copper powder according to a
comparative example (particles of small diameter but
agglomerated).
[0020] FIG. 6 is an SEM image of a sintered product obtained by
sintering a copper powder according to a comparative example
(particles of small diameter but agglomerated) at 800.degree.
C.
[0021] FIG. 7 is an SEM image of a copper powder according to a
comparative example (particles not agglomerated but of large
diameter).
[0022] FIG. 8 is an SEM image of a sintered product obtained by
sintering a copper powder according to a comparative example
(particles not agglomerated but of large diameter) at 800.degree.
C.
DESCRIPTION OF THE PREFERRED EMBODIMENTS
[0023] The conventional process of producing copper powder by wet
reduction comprises a step of reacting an aqueous solution of a
copper salt and an alkali to precipitate copper hydroxide, thereby
obtaining a suspension containing copper hydroxide, a
primary-reduction step conducted in the suspension to reduce the
copper hydroxide obtained to cuprous oxide, and a
secondary-reduction step conducted in the suspension to reduce the
cuprous oxide obtained to metallic copper. A metallic copper powder
can then be obtained by separating the metallic copper obtained
from the suspension and drying it, either immediately or after
surface treatment for imparting oxidation resistance. However, the
inventors discovered that when the reduction in the
secondary-reduction step is promoted by presence of ammonia or an
ammoniate, a copper powder can be obtained that, even at a small
particle diameter of, for instance, not greater than 1.5 .mu.m,
preferably not greater than 1.2 .mu.m, more preferably not greater
than 1.0 .mu.m, exhibits small B.E.T specific surface area for the
particle diameter (has minimal surface irregularity) and narrow
particle-size distribution (consists of particles of substantially
the same diameter), and further discovered that the copper powder
is highly resistant to agglomeration despite its small particle
diameter. The inventors also learned that the copper powder forms a
pseudo-fused sintered product even when sintered at a low
temperature.
[0024] The sintering for forming the external electrodes of stacked
insulating boards is generally conducted in a non-oxidizing
atmosphere under normal pressure (actually under an atmosphere of
inert gas at one atmosphere pressure). Sintering at low temperature
proceeds more readily with decreasing particle diameter of the
copper powder in the copper paste. However, in the case of a fine
powder of an average particle diameter of smaller than 1 .mu.m
(submicron powder) obtained by the conventional wet reduction
process, the particles actually tend to adhere (bond) or tangle in
groups of several to several tens of particles to form coarse
particles (compound particles measuring several .mu.m to several
tens of .mu.m in diameter). The powder therefore becomes one
composed of intermixed compound particles and submicron particles
(an agglomerated powder). When such a copper powder is sintered at
a low temperature, any sintering that occurs proceeds only
partially and the sintered product includes many pores. From this
it follows that reduction of particle diameter alone is not
sufficient for achieving a low sintering temperature.
[0025] As demonstrated by the Examples set out later, however, when
the secondary reduction of the wet reduction process is promoted by
the presence of ammonia or an ammoniate, the copper powder
obtained, even if a fine powder of a particle diameter smaller than
1 .mu.m, does not readily form coarse particles (is highly
resistant to agglomeration) and enables production of a
pseudo-fused sintered product with no or very few pores even when
sintered at a temperature not higher than 800.degree. C. The reason
for this, while not completely verified, is thought to be that
ammonia or ammoniate present in the solution acts as a complexing
agent that causes the Cu to shift to the solution as a complex and
since the reduction proceeds from this, smooth metallic copper
particles of uniform diameter are produced. The ammonia or
ammoniate can be added in the form of ammonia gas, ammonia water,
ammonium hydroxide or any of various ammonium compounds and
ammonium salts. Ammonia water is convenient for ease of handling.
The amount added is preferably 0.01-0.1 mole, more preferably
0.02-0.08 mole, as ammonia per mole of copper in the system. In
actual practice, the ammonia or ammoniate preferably remains in the
solution at the time of completion of the reduction to metallic
copper.
[0026] In order to reduce the average particle diameter of the
metallic copper powder, the reducing agent used for the secondary
reduction should be added at one time in not less than an
equivalent amount. Taking the specific case of using hydrous
hydrazine as the reducing agent, at least 1.1 times the chemical
equivalent of hydrous hydrazine required for reducing the cuprous
oxide to metallic copper should be added all at once. This enables
production of a fine metallic copper powder having an average
particle diameter in the range of 0.1-1.5 .mu.m, preferably 0.3-1.2
.mu.m. Moreover, by blowing an oxygen-containing gas into the
suspension of cuprous oxide produced by the primary reduction, the
particle diameter can be controlled in proportion to the amount of
blown gas and the particle size distribution width can also be
narrowed. Although the particle diameter increases with increasing
amount of blown-in oxygen-containing gas, when the desired effect
is to maintain a small particle diameter while narrowing the
particle size distribution width, a small overall amount of
oxygen-containing gas is preferably blown in over an extended
period.
[0027] Known methods can be used for the other processing steps.
For instance, in the step of precipitating copper hydroxide, the
aqueous solution of copper salt can be an aqueous copper sulfate
solution used in the ordinary manner as, but an aqueous solution of
copper chloride, copper carbonate, copper nitrate or the like is
also usable. Although an aqueous solution of NaOH is most commonly
used as the alkali, any of various other alkalis that have no
effect on other aspects of the invention process can be used
instead. The reaction for precipitating copper hydroxide can be
conducted by the method of separately preparing an aqueous solution
of copper salt of a certain concentration and an aqueous alkali
solution of a certain concentration, mixing the two to prepare a
solution containing excess alkali, and then immediately subjecting
the solution to vigorous stirring. Otherwise it can be carried out
by the method of continuously adding the aqueous alkali solution to
the aqueous solution of a copper salt under stirring. Addition of a
reducing agent to the obtained copper hydroxide suspension in order
to reduce the copper hydroxide to cuprous oxide can be conducted by
using a glucose as the reducing agent in the ordinary manner. This
primary reduction step is preferably carried out under an inert gas
atmosphere and increasing temperature (50-90.degree. C). The
blowing-in of oxygen-containing gas, when conducted, can be carried
out by bubbling air into the suspension.
[0028] After the final reduction to metallic copper by addition of
hydrous hydrazine in the presence of ammonia or ammoniate, the
metallic copper is separated from the suspension and dried, either
immediately or after surface treatment for imparting oxidation
resistance, to afford a metallic copper powder of small average
particle diameter that exhibits little agglomeration.
[0029] The copper powder has an average particle diameter of from
not less than 0.1 .mu.m to less than 1.5 .mu.m, preferably 0.3-1.2
.mu.m. The number of particles of a particle diameter near the
average particle diameter is great and the number of particles of a
particle diameter far from the average particle diameter is small.
Specifically, when the particle size distribution is measured by,
for example, a helos particle size distribution measuring device,
the copper powder is found to have a narrow particle size
distribution width whose value A, defined by Equation (1) in terms
of X25, X50 and X75, i.e., values of particle diameter X
corresponding to Q%=25%, 50% and 75% (where Q% is the ratio of
particles present of a diameter not greater than the corresponding
value of X; expressed in units of vol % of particles), is not
greater than 1.2, preferably not greater than 1.0:
A=(X75-X25)/X50 (1),
[0030] on a cumulative particle-size curve plotted in an orthogonal
coordinate system whose abscissa represents particle diameter X
(.mu.m) and ordinate represents Q% (see FIG. 1 relating to Examples
set out below). In addition, the copper powder exhibits a low B.E.T
specific surface area despite its small average particle diameter.
In other words, it consists of smooth particles of minimal surface
irregularity (see FIG. 2 relating to Examples set out below).
[0031] Owing to its achievement of the aforesaid average particle
diameter, value A, and surface smoothness (e.g., a small B.E.T.
specific surface area of not more than 2.0 m.sup.2/g even at an
average particle diameter of around 0.8 .mu.m), the copper powder
according to the present invention forms a pseudo-fused sintered
product when held at a temperature of 800.degree. C. under an
atmosphere of inert gas at one atmosphere pressure (see FIG. 3
related to Examples set out below). In contrast, a copper powder
whose average particle diameter falls within the range specified by
the present invention but whose value A falls outside the range
specified by the present invention forms a porous sintered product
including pores when sintered at the same temperature of
800.degree. C. (see FIG. 6, for example). Moreover, a copper powder
whose value A falls within the range specified by the present
invention but whose average particle diameter is larger than the
upper limit of the range specified by the present invention does
not sinter when held at 800.degree. C. (see FIG. 8, for
example).
[0032] Therefore, when a conductive paste utilizing the invention
copper powder as filler is used to form the external electrodes of
stacked boards for mounting semiconductor chips, for example, it
becomes possible to form pore-free external electrodes at a low
sintering temperature.
WORKING EXAMPLES
EXAMPLE 1
[0033] An aqueous solution of copper sulfate A was prepared by
dissolving 1.04 Kg of CuSO.sub.4.multidot.5H.sub.2O in 2.54 Kg of
pure water and an aqueous alkali solution B was prepared by adding
850 g of an aqueous solution of NaOH of 49% concentration to 3.2 Kg
of pure water. The total amount of solution A and solution B, held
at 29.degree. C. and 27.degree. C., respectively, were poured into
a reaction vessel and stirred. A suspension of precipitated copper
hydroxide was obtained whose temperature was increased to
36.degree. C. by heat of the reaction.
[0034] A glucose solution prepared by dissolving 1.12 Kg of a
glucose in 1.59 Kg pure water was added to the total amount of
copper hydroxide suspension obtained. The solution rose to a
temperature of 70.degree. C. over a 30-min period following the
addition and was maintained at this temperature for 30 min
thereafter. The processing operations up to this point (i.e., the
precipitation of copper hydroxide and its reduction to cuprous
oxide) were conducted throughout under a nitrogen atmosphere.
[0035] Air was then bubbled into the suspension at a flow rate of 1
liter/min over a period of 200 min, whereafter the suspension was
left standing in a nitrogen atmosphere for two days. The
supernatant (pH 5.5) was then removed to harvest substantially the
total amount of the precipitate. A suspension was prepared by
adding 2.25 Kg of pure water to the precipitate.
[0036] To the suspension was added 20 wt % ammonia water in an
amount of 2 wt % based on the weight of the suspension. This amount
of ammonia addition corresponded to 0.04 mole of ammonia per mole
of copper in the system. This made the pH of the suspension 10.
After the suspension had been adjusted to 50.degree. C., 130 g of
hydrous hydrazine was added thereto all at one time. The
temperature of the suspension was increased to 80.degree. C. by
heat generated up to completion of the reaction. Upon completion of
the reaction, the suspension was subjected to solid-liquid
separation and a copper powder was obtained by drying the harvested
solid content at 110.degree. C. under an inert gas atmosphere.
[0037] The average particle diameter of the copper powder measured
using a sub-sieve siezer (SSS) was 0.8 .mu.m. The B.E.T specific
surface area was found to be 1.6 m.sup.2/g. An analysis showed
oxygen content to be 0.16 wt % and carbon content to be 0.09 wt
%.
[0038] The particle size distribution of the copper powder was
determined using a helos particle size distribution measuring
device (Helos H0780; Sympatic Co.,Ltd.). The results are shown in
FIG. 1. Curve 1 in the drawing is a particle size distribution
curve showing how distribution density (right vertical axis) varies
as a function of particle diameter X (.mu.m) (horizontal axis
represented by logarithm scal). Curve 2 is cumulative particle size
curve showing how Q% (left vertical axis) varies as a function of
particle diameter X (.mu.m) (horizontal axis). Q% represents the
vol % of particles of not greater than particle diameter X(.mu.m)
present. As can be seen from Curve 2, the particle diameters X at
Q% of 25%, 50% and 75% were X25=0.47, X50=0.77 and X75=1.08 /.mu.m.
The value of A was therefore 0.79. The foregoing results are
summarized in Table 1.
[0039] FIG. 2 is a scanning electron microscope (SEM) image of the
copper powder of this Example. As can be seen, the copper powder
was composed of smooth- surfaced particles of substantially equal
diameters of around 0.8 .mu.m.
[0040] 30 g of the copper powder of this Example and 6 g of resin
(ethyl cellulose: 95% +terpineol; 5%) were blended in a deaerating
blender for 3 min. A 30 .mu.m-thick coat of the blended material
was applied to an aluminum board and dried for 3 hr at 100.degree.
C. in a nitrogen atmosphere. The dried product was sintered for 30
min at 800.degree. C. in a nitrogen atmosphere (1 atmosphere). A
scanning transmission electron microscope (SEM) image of the
sintered body obtained is shown in FIG. 3. This image demonstrates
that the copper powder of this Example formed a pseudo-fused
sintered product at 800.degree. C. In other words, a solid sintered
product having substantially no pores and presenting a
once-melted-down consistency was obtained at a sintering
temperature 800.degree. C.
EXAMPLE 2
[0041] The process of Example 1 was repeated except that the amount
of 20 wt % ammonia water added was changed to 1.5 wt % based on the
weight of the suspension. This amount of ammonia addition
corresponded to 0.03 mole of ammonia per mole of copper in the
system. The properties of the copper powder obtained were
determined in the same manner as in Example 1 and are also shown in
Table 1. When the copper powder was sintered under the same
conditions as in Example 1, there was obtained a pseudo-fused
sintered product that, like that of Example 1, was substantially
free of pores.
EXAMPLE 3
[0042] The process of Example 1 was repeated except that the amount
of 20 wt % ammonia water added was changed to 1.0 wt % based on the
weight of the suspension. This amount of ammonia addition
corresponded to 0.02 mole of ammonia per mole of copper in the
system. The properties of the copper powder obtained were
determined in the same manner as in Example 1 and are also shown in
Table 1. When the copper powder was sintered under the same
conditions as in Example 1, there was obtained a pseudo-fused
sintered product that, like that of Example 1, was substantially
free of pores.
COMPARATIVE EXAMPLE 1
[0043] The process of Example 1 was repeated except that no
addition of ammonia water was effected. The properties of the
copper powder obtained were determined in the same manner as in
Example 1 and are also shown in Table 1.
[0044] FIG. 4 shows a particle size distribution Curve 1 and a
cumulative particle size Curve 2 based on the copper powder
particle size distribution of the copper powder of this Comparative
Example determined using a helos particle size distribution
measuring device as in Example 1. FIG. 5 is an SEM image of the
copper powder and FIG. 6 is an SEM image of a sintered product
obtained by sintering the copper powder under the same conditions
(800.degree. C.) as in Example 1. As can be seen in FIG. 5,
agglomeration of the copper powder had progressed to the point that
it included many coarse particles consisting of several to several
tens of adhered or tangled particles. As can be seen from FIG. 6,
the agglomerated powder of this Comparative Example, when sintered
at a temperature of 800.degree. C., did not, despite its small
average particle diameter, form a pseudo-fused sintered product
with few pores like that in FIG. 1 but formed a sintered product
that included many pores because the particles were only partially
joined. Obviously such a product would have lower electrical
conductivity than that of Example 1.
COMPARATIVE EXAMPLE 2
[0045] The process of Comparative Example 1 was repeated except
that air was bubbled at a flow rate of 7 liter/min over a period of
200 min. The properties of the copper powder obtained determined in
the manner of Example 1 are also shown in Table 1.
[0046] FIG. 7 is an SEM image of the copper powder and FIG. 8 is an
SEM image of a sintered product obtained by sintering the copper
powder under the same conditions (800.degree. C.) as in Example 1.
As can be seen from FIG. 7, the copper powder of this Comparative
Example was composed of large-diameter particles. (Note that the
magnification in FIG. 7 is one-half that in FIGS. 2 and 5.) The
particles did not agglomerate. As can be seen from FIG. 8, no
sintering progressed at 800.degree. C. in the case of the
large-particle-diameter copper powder of this Comparative
Example.
1 TABLE 1 Average Cumulative particle distribution of Value BET
diameter Oxygen Carbon particle diameter A Value SSS value content
content (.mu.m) (X75- No (m.sup.2) (.mu.m) (%) (%) X25 X50 X75
X25)/X50 Example 1 1.6 0.8 0.16 0.09 0.47 0.77 1.08 0.79 Example 2
1.7 0.8 0.17 0.08 0.45 0.80 1.12 0.84 Example 3 2.0 0.8 0.15 0.08
0.46 0.79 1.20 0.94 Comparative 2.8 0.6 0.25 0.14 0.45 0.91 1.58
1.48 Example 1 Comparative 0.8 1.5 0.21 0.07 1.00 1.30 1.70 0.53
Example 2
[0047] As explained in the foregoing, the present invention
provides a metallic copper powder that forms a pseudo-fused
sintered product with few pores when sintered at 800.degree. C. As
the metallic copper powder has a property of sintering into a solid
body, it is, for example, highly suitable for use in forming a
sintered terminal electrode of multi-layer ceramics capacitors.
* * * * *