Tuesday, June 09, 2015

Gypsum & Anhydrite

Gypsum is an important industrial mineral, and has been mined and quarried in Manitoba nearly continuously since 1901. Gypsum is an evaporite mineral that was deposited in a shallow, inland sea that covered Manitoba during the Jurassic Period, approximately 200 million years ago.

The Western Edge of Lake Manitoba
Along the western edge of Lake Manitoba, and around Gypsumville, gypsum deposits occur very near to the surface. They create a unique landscape of sinkholes, caves, and karst topography. Gypsum is currently being quarried on the west side of Lake Manitoba, but since 1901 there have been multiple mines and quarries in a variety of localities across southern Manitoba.
 
Gypsum is extracted from the quarry using heavy machinery, transported to Winnipeg, and processed into wallboard or used to make cement.

Gypsum and Anhydrite
Gypsum is a calcium sulphate mineral, with its chemical formula being CaSO4 • 2H2O.
Gypsum is often white or grey, but may display a variety of colours. It can be fine to coarse grained, and grows several interesting crystal forms and textures. Gypsum is very soft, so soft that fingernails can scratch this mineral. The term gypsum can also be used to describe a rock composed primarily or entirely of gypsum crystals.
Possible replacement texture in gypsum; clays are interspersed through the rock.
Edge of rock hammer for scale.

Gypsum has undergone a complicated history of diagenesis (shallow, low-grade metamorphism) in Manitoba. Gypsum was originally deposited when a shallow, marine seaway that covered Manitoba in the Jurassic Period experienced increased rates of evaporation due to a hot, dry climate. Overtime, the gypsum was buried by younger rocks and sediments, and was subjected to hotter temperatures. The heat caused the water in gypsum to be driven out of the crystal structure, and the mineral turned into anhydrite, CaSO4. When the anhydrite beds were exhumed and brought near the surface, where they were subjected to groundwater flow. This water re-hydrated the anhydrite, and some of the deposit has reverted back to gypsum.

Taking a Closer Look at Gypsum
Fractures and veins filled with clay and mudstone through the greyish-white gypsum.
Gypsum is an important industrial mineral in Manitoba. The quarried gypsum is hauled to Winnipeg, and processed into wallboard. It is also an ingredient of cement. Because gypsum is economically important, I will be examining known occurrences of gypsum and providing a comprehensive update on this commodity. This will involve reviewing previous studies done on gypsum, current and historical industrial activity, examining core logs, and completing stratigraphic sections and maps of quarries.



Several localities within the gypsum quarry, like this one, 
will be ideal for completing a stratigraphic section.
Vertical walls found in this active gypsum quarry provide an opportunity to complete a stratigraphic section. A stratigraphic section is a detailed look at how the geology of a unit of rocks changes upwards and laterally. This allows geologists to preform correlations with other occurrences of similar rocks. It also enables geologists to understand how the depositional environment of these rocks changed over time. Information collected for a stratigraphic section may include mineralogy, fossils, sedimentary structures, mineral textures, and veins/fractures. Representative rock samples are taken too.


Written by Kathryn Lapenskie

Thursday, June 04, 2015

The Manitoba Escarpment - vestiges of an ancient ocean

In the southwestern corner of the province lies the Manitoba Escarpment: a wedge of Cretaceous shales that was deposited in an inland sea that expanded across the centre of North America approximately 80 million years ago. These rocks contain economically important deposits, as well as the remains of prehistoric marine reptiles and fish that inhabited the inland sea.

The Manitoba Escarpment
In mid-April, a few geologists from the Manitoba Geological Survey and several people from the Canadian Fossil Discovery Centre went on a two-day field trip to study Cretaceous shale in the Morden-Miami area of Manitoba.

We stopped at several localities to examine exposures of different rock units and to look at some reclaimed and active quarries. Among the localities we visited included a paleontologically significant site that is currently being excavated by the Canadian Fossil Discovery Centre. There were great exposures of the Pembina Member of the Pierre Shale at this site.

The Pembina Member is composed of black shale interbedded with layers of cream-coloured bentonite beds.
The Pembina Member is composed of black shale that is interbedded with seams of bentonite. Bentonite was initially deposited as volcanic ash at the bottom of the sea by volcanoes that were most likely located in Montana. Through interactions with ancient sea water, that volcanic ash has been altered into clays. Historically, bentonite was an important industrial mineral and was quarried in the Morden-Miami area. Bentonite is also used to preform age-dating, allowing geologists to pinpoint the exact age of the rocks (give or take a few thousand years!). The Pembina Member also contains numerous fossils of Cretaceous vertebrates including plesiosaurs, giant turtles, sharks, fish, and the mighty mosasaur. The Canadian Fossil Discovery Centre has many fossils and reconstructed skeletons of these amazing creatures on display.



The Boyne Member, underlying the Pembina Member;
thin, darker-brown beds are bentonite seams.
Underlying the Pembina Member is the Boyne Member, which is a buff to grey unit that contains few brown-coloured bentonite seams. The upper part of the Boyne is composed of an upper chalky unit, pictured right, and a lower calcareous shale unit.
Historically, the Boyne Member was mined for natural cement rock. Occasionally well preserved fossils, such as shark teeth, can be found from the Boyne. Many road cuts along the southern escarpment provide excellent exposure of the Boyne, as well as other members.



The Babock beds are resistive beds located immediately above the lower part
 of this outcrop that is covered by vegetation.


At another outcrop of the Boyne we were able to observe the upper and lower units. The units are roughly separated by the Babcock bed, which is a layer of resistive, calcareous shale. Above the Babcock bed is the buff-coloured chalky unit, and below is the grey-coloured calcareous shale unit, that is partially covered in slumped material and vegetation.

 

Brick Production

Beehive kiln of the old brick plant. Please note this site is on private
property and cannot be accessed without permission of the landowner.
We travelled up the Roseisle Creek valley to explore more important sites. We stopped at the old Leary's brick plant that produced bricks from 1900-1907 and 1947-1952. There used to be several brick plants across southern Manitoba, using a variety of shales and clays to create bricks in a wide range of colours. Bricks are no longer produced in the province, but if you're lucky you might spy some Manitoba-made bricks on older buildings.


 
Shale from the Morden Member was extracted from the banks of the Roseisle Creek (pictured on the left), and produced bricks with a rich red colour. It was carried across the creek and fired in the beehive kiln (pictured on the right).

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The Manitoba Escarpment provides wonderful scenery and a variety of localities that are great for observing Cretaceous sedimentary rocks. Road cuts and rivers provide opportunities to work up or down section to observe how the rocks changed through time. Changes in geology represent changes in the environment the rocks were deposited in. Fossils of the animals that lived in this seaway provide important information about paleoenvironments, and the evolution and adaptation of these creatures.

Written by Kathryn Lapenskie