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Crystal growth of metastable quartz solid solutions in MgO - Al2O3 - SiO2 glasses
Journal
of Crystal
Growth 2 (1968) 41 l-412
CRYSTAL
0 North-Holland
Publishing
LETTERS
TO THE
EDITORS
GROWTH OF METASTABLE QUARTZ SOLID SOLUTIONS MgO - AI,O, - SiOz GLASSES HANS-JOERG
Itwtitute
Co., Amsterdam
of Crystallography
and Petrography
SCHEEL*
of the Federal
Received
IN
25 July
Institute
of Technology,
Zurich,
Switzerland
1968
Crystals of metastable high-quartz solid solutions have been grown from MgO-A1203-Si02 glasses by initiating crystal interior of the glass. Transformation to the stable cordierite-phase is prevented by the high viscosity of the glassy
The metastable high-quartz phase is the first crystallization product from MgO-AI,O,-x SiO, glasses at low temperatures’). It is not possible to obtain crystals of this phase by normal crystal growing techniques.
Fig.
1.
Preferred
orientation
* Now with IBM Zurich
Research
of
the
metastable quartz-type into the glassy medium
Laboratory,
8803 Rtischlikon,
growth in the medium.
For instance Schreyer and Yoder’) did not find quartz solid solutions in the system 2MgO-2Al,O,-5SiO,H,O between 350 and 1300 “C and pressures up to 10000 atm, only pure low-quartz, cordierite, mont-
crystals (partially
which nucleated crossed nicols).
Switzerland.
411
at the wall
of the bore-hole
and
grew
412
HANS-JOERG
morillonite, etc. In the anhydrous system they observed crystallization of quartz solid solutions at low temperatures after short crystallization times. Crystallization of bulk glass samples,
with and with-
out flux, starts from the surface and results in the formation of small crystallites. If the crystallization could
SCHEEL
quartz-type phase was identified by X-ray Guinier photographs. In the microscope (crossed nicols) one sees the orientation of the c-axes parallel to the growth direction; this effect has been described and explained by Laves3) and by Kamb4). It should be possible to increase the crystal size by slowly traversing a suitable temperature gradient (a
start at some point in the interior of the glass the crystallites would have a better possibility of increasing
zone
their size in all directions. Therefore bore-holes of about l-2 mm diameter were drilled into bulk glass
molten zone in zone melting) gradient should prevent the
samples and filled with a flux of composition Li,O . 4 WO,. The samples were packed in platinum foil and annealed in a furnace of uniform temperature for three months. During this time the temperature was raised stepwise from 600 to 800 “C. The glass sample of composition MgO * Al,O, . 3Si0, (l/l/3) showed single crystals of the quartz solid solution of 0.2-0.3 mm diameter and 1.5-2 mm length (see fig. 1). The compositions l/l/2 and l/l/4 gave smaller crystals, and l/l/6 did not crystallize under these conditions. The
crystallized metastable quartz-type phase. The author thanks Prof. Dr. F. Laves for his interest in this work, and Owens-Illinois Inc., Toledo, for financial support.
of ideal
diffusion
constants
analogous
to the
through the glass; the transformation of the
References 1) W. Schreyer and J. F. Schairer, Z. Krist. 116 (1961) 60. 2) W. Schreyer and H. S. Yoder, Neues Jahrb. Mineral. Abh. 101 (1964) 271. 3) F. Laves, Naturwissenschaften 27 (1939) 705. 4) W. B. Kamb, J. Geology 67 (1959) 153.
of Crystal
Growth 2 (1968) 41 l-412
CRYSTAL
0 North-Holland
Publishing
LETTERS
TO THE
EDITORS
GROWTH OF METASTABLE QUARTZ SOLID SOLUTIONS MgO - AI,O, - SiOz GLASSES HANS-JOERG
Itwtitute
Co., Amsterdam
of Crystallography
and Petrography
SCHEEL*
of the Federal
Received
IN
25 July
Institute
of Technology,
Zurich,
Switzerland
1968
Crystals of metastable high-quartz solid solutions have been grown from MgO-A1203-Si02 glasses by initiating crystal interior of the glass. Transformation to the stable cordierite-phase is prevented by the high viscosity of the glassy
The metastable high-quartz phase is the first crystallization product from MgO-AI,O,-x SiO, glasses at low temperatures’). It is not possible to obtain crystals of this phase by normal crystal growing techniques.
Fig.
1.
Preferred
orientation
* Now with IBM Zurich
Research
of
the
metastable quartz-type into the glassy medium
Laboratory,
8803 Rtischlikon,
growth in the medium.
For instance Schreyer and Yoder’) did not find quartz solid solutions in the system 2MgO-2Al,O,-5SiO,H,O between 350 and 1300 “C and pressures up to 10000 atm, only pure low-quartz, cordierite, mont-
crystals (partially
which nucleated crossed nicols).
Switzerland.
411
at the wall
of the bore-hole
and
grew
412
HANS-JOERG
morillonite, etc. In the anhydrous system they observed crystallization of quartz solid solutions at low temperatures after short crystallization times. Crystallization of bulk glass samples,
with and with-
out flux, starts from the surface and results in the formation of small crystallites. If the crystallization could
SCHEEL
quartz-type phase was identified by X-ray Guinier photographs. In the microscope (crossed nicols) one sees the orientation of the c-axes parallel to the growth direction; this effect has been described and explained by Laves3) and by Kamb4). It should be possible to increase the crystal size by slowly traversing a suitable temperature gradient (a
start at some point in the interior of the glass the crystallites would have a better possibility of increasing
zone
their size in all directions. Therefore bore-holes of about l-2 mm diameter were drilled into bulk glass
molten zone in zone melting) gradient should prevent the
samples and filled with a flux of composition Li,O . 4 WO,. The samples were packed in platinum foil and annealed in a furnace of uniform temperature for three months. During this time the temperature was raised stepwise from 600 to 800 “C. The glass sample of composition MgO * Al,O, . 3Si0, (l/l/3) showed single crystals of the quartz solid solution of 0.2-0.3 mm diameter and 1.5-2 mm length (see fig. 1). The compositions l/l/2 and l/l/4 gave smaller crystals, and l/l/6 did not crystallize under these conditions. The
crystallized metastable quartz-type phase. The author thanks Prof. Dr. F. Laves for his interest in this work, and Owens-Illinois Inc., Toledo, for financial support.
of ideal
diffusion
constants
analogous
to the
through the glass; the transformation of the
References 1) W. Schreyer and J. F. Schairer, Z. Krist. 116 (1961) 60. 2) W. Schreyer and H. S. Yoder, Neues Jahrb. Mineral. Abh. 101 (1964) 271. 3) F. Laves, Naturwissenschaften 27 (1939) 705. 4) W. B. Kamb, J. Geology 67 (1959) 153.