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Separating intermediate phases from zinc-base alloys
Metallography
107
Separating
Intermediate
Phases from
L. NEUMEIER
AND
Zinc-Base Alloys
J. RISBECK
U. S. Department of the Interior, Bureau of Mines, Rolla Metallurgy Research Center, Rolla, Missouri 65401
During copper
research
on wrought
or titanium
or both,
extracting
intermediate-phase
the creep diffraction
and other analysis
zinc-base
a simple
alloys
procedure
particles
containing
small
was devised
from the alloys.
additions
of
for electrolytically
These
phases
influence
properties of the alloys, and they were extracted for x-ray in conjuction with optical microscopy and microprobe
analysis. The particles Examples Fig.
1. The
contained
ranged
from fine to relatively
of the size and distribution extraction
technique
to more than
worked
3 wt o/o-copper
(4
coarse,
of the particles well
often in the same specimen. in rolled alloys are shown
for the
alloys
alloys.
(A) Zn-0.75%
(0 CU; (B) Zn-0.12%
Ti;
Metallography, Copyright
0
in
which
and 1 wt o/o titanium.
(B)
FIG. 1. Cold-rolled Cu-0.36% Ti. 750 x .
studied,
1969 by American
Elsevier
Publishing
and (C) Zn-1.0%
2 (1969)
107-108
Company,
Inc.
108
L. Neumeia and J. R&beck
The specimen is made the anode in a cell with a stainless-steel electrolyte
consisting
cathode and an
of about 10 g of CrO, per 100 ml of water. With about
40 volts dc applied, the zinc solid-solution matrix is selectively dissolved, and the insoluble particles settle to the bottom of the cell. Finer particles may require a day or so to settle completely.
The residue is collected, washed with water or
alcohol, and dried. The matrix of a half-inch
cubic specimen can be completely
dissolved in about an hour. During preparation of a sample, the cathode should be removed several times to wash away decomposed electrolyte. This film formation on the cathode may be minimized by immersing the cell in an ice bath and reducing the voltage, with some sacrifice in dissolution rate. The technique
was devised by J. Fore and M. Adam of the metallography
laboratory at the Rolla (Missouri) Metallurgy Research Center, Bureau of Mines, U.S. Department of the Interior.
Accepted February 20, 1969
107
Separating
Intermediate
Phases from
L. NEUMEIER
AND
Zinc-Base Alloys
J. RISBECK
U. S. Department of the Interior, Bureau of Mines, Rolla Metallurgy Research Center, Rolla, Missouri 65401
During copper
research
on wrought
or titanium
or both,
extracting
intermediate-phase
the creep diffraction
and other analysis
zinc-base
a simple
alloys
procedure
particles
containing
small
was devised
from the alloys.
additions
of
for electrolytically
These
phases
influence
properties of the alloys, and they were extracted for x-ray in conjuction with optical microscopy and microprobe
analysis. The particles Examples Fig.
1. The
contained
ranged
from fine to relatively
of the size and distribution extraction
technique
to more than
worked
3 wt o/o-copper
(4
coarse,
of the particles well
often in the same specimen. in rolled alloys are shown
for the
alloys
alloys.
(A) Zn-0.75%
(0 CU; (B) Zn-0.12%
Ti;
Metallography, Copyright
0
in
which
and 1 wt o/o titanium.
(B)
FIG. 1. Cold-rolled Cu-0.36% Ti. 750 x .
studied,
1969 by American
Elsevier
Publishing
and (C) Zn-1.0%
2 (1969)
107-108
Company,
Inc.
108
L. Neumeia and J. R&beck
The specimen is made the anode in a cell with a stainless-steel electrolyte
consisting
cathode and an
of about 10 g of CrO, per 100 ml of water. With about
40 volts dc applied, the zinc solid-solution matrix is selectively dissolved, and the insoluble particles settle to the bottom of the cell. Finer particles may require a day or so to settle completely.
The residue is collected, washed with water or
alcohol, and dried. The matrix of a half-inch
cubic specimen can be completely
dissolved in about an hour. During preparation of a sample, the cathode should be removed several times to wash away decomposed electrolyte. This film formation on the cathode may be minimized by immersing the cell in an ice bath and reducing the voltage, with some sacrifice in dissolution rate. The technique
was devised by J. Fore and M. Adam of the metallography
laboratory at the Rolla (Missouri) Metallurgy Research Center, Bureau of Mines, U.S. Department of the Interior.
Accepted February 20, 1969