The geological exploration of kimberlitic rocks in Québec /
Diamonds have been discovered in a variety of potassic ultramafic rocks including group-I and group-II kimberlites, olivine lamproites and aillikites, all of which are macroscopically similar and can be difficult to differentiate when viewed under the microscope. However, group-I kimberlites, and to...
| Main Author: | |
|---|---|
| Format: | Thesis |
| Language: | English |
| Published: |
McGill University
2007
|
| Subjects: | |
| Online Access: | http://digitool.Library.McGill.CA:80/R/?func=dbin-jump-full&object_id=101135 |
| id |
ftcanadathes:oai:collectionscanada.gc.ca:QMM.101135 |
|---|---|
| record_format |
openpolar |
| institution |
Open Polar |
| collection |
Theses Canada/Thèses Canada (Library and Archives Canada) |
| op_collection_id |
ftcanadathes |
| language |
English |
| topic |
Kimberlite -- Québec (Province) Geochemical prospecting -- Québec (Province) |
| spellingShingle |
Kimberlite -- Québec (Province) Geochemical prospecting -- Québec (Province) Hartzler, Joy R. The geological exploration of kimberlitic rocks in Québec / |
| topic_facet |
Kimberlite -- Québec (Province) Geochemical prospecting -- Québec (Province) |
| description |
Diamonds have been discovered in a variety of potassic ultramafic rocks including group-I and group-II kimberlites, olivine lamproites and aillikites, all of which are macroscopically similar and can be difficult to differentiate when viewed under the microscope. However, group-I kimberlites, and to a much lesser extent group-II kimberlites and olivine lamproites, are known to contain economic concentrations of diamonds. This study addresses the problem of distinguishing among different types of kimberlitic and related rocks by developing a geochemically-based method for classifying them. Geochemical methods have been largely ignored in the classification of kimberlites and related rock types due to high concentrations of xenoliths. However, this problem can be largely overcome by only selecting matrix material for analysis. An evolving kimberlitic magma will become enriched or improvished in Si due to the fractionation of olivine and phlogopite, depending on the initial Si concentration of the magma. As they have low Si concentrations, group-I kimberlites and aillikites can be separated from group-II kimberlites and meimechites, which have higher Si concentrations for any Mg content. Furthermore, since aillikites and meimechites are relatively rich in Fe compared to group-I and group-II kimberlites, these rock types form four separate fields on a Si vs. Fe discrimination diagram. Similar rock-type separation is observed when the ratio of La to Yb is plotted against the ratio of Sm to Yb. Kimberlite and other potassic ultramafic rocks were sampled from nine areas in Quebec: the Otish Mountains, Wemindji, Torngat Mountains, Desmaraisville, Temiscamingue, Ile Bizard, Lac Leclair, Baie James and Ayer's Cliff regions. Major and selected trace element concentrations were determined by XRF analysis for all samples, while a subset of representative samples was selected for trace element analysis by ICP-MS. Electron microprobe analyses of unaltered olivine and phlogopite were also conducted. Of the 37 samples that were classified both mineralogically and chemically, 23 or 62% were correctly classified using Fe and Si. This number increases to 84%, if the REE are used in conjunction with Si and Fe. The Si vs. Fe discrimination diagram separates group-I kimberlite from most aillikite and meimechite rocks and group-II kimberlite/olivine lamproite rocks from most aillikite and meimechite rocks. Therefore, major and trace element geochemistry offers an important tool for the classification of kimberlitic rocks. Vasilenko et al. (2002) and Francis (2003) both suggested that diamond grades can be correlated with the major element compositions of the kimberlites. The data collected in this study confirm the inverse relationship between TiO2 concentration and diamond grade. The lowest TiO 2 values were obtained on samples from the Otish Mountains and Renard samples in particular. Other areas of Quebec are characterized by higher TiO2 contents with most samples containing greater than 2 wt% TiO 2. Therefore, the kimberlitic rocks from the Renard locality have the greatest potential for an economic diamond deposit. The origin of this correlation needs to be explored, however, because it is unclear whether this is a feature of the mantle source, or reflects the survivability of diamonds within the kimberlites. |
| format |
Thesis |
| author |
Hartzler, Joy R. |
| author_facet |
Hartzler, Joy R. |
| author_sort |
Hartzler, Joy R. |
| title |
The geological exploration of kimberlitic rocks in Québec / |
| title_short |
The geological exploration of kimberlitic rocks in Québec / |
| title_full |
The geological exploration of kimberlitic rocks in Québec / |
| title_fullStr |
The geological exploration of kimberlitic rocks in Québec / |
| title_full_unstemmed |
The geological exploration of kimberlitic rocks in Québec / |
| title_sort |
geological exploration of kimberlitic rocks in québec / |
| publisher |
McGill University |
| publishDate |
2007 |
| url |
http://digitool.Library.McGill.CA:80/R/?func=dbin-jump-full&object_id=101135 |
| op_coverage |
Master of Science (Department of Earth and Planetary Sciences.) |
| long_lat |
ENVELOPE(-80.500,-80.500,53.500,53.500) ENVELOPE(-77.162,-77.162,60.821,60.821) ENVELOPE(-63.767,-63.767,-65.017,-65.017) ENVELOPE(-63.665,-63.665,59.000,59.000) ENVELOPE(-78.816,-78.816,53.000,53.000) |
| geographic |
Baie James Lac Leclair Renard Torngat Mountains Wemindji |
| geographic_facet |
Baie James Lac Leclair Renard Torngat Mountains Wemindji |
| genre |
Wemindji |
| genre_facet |
Wemindji |
| op_relation |
alephsysno: 002612144 proquestno: AAIMR32714 Theses scanned by UMI/ProQuest. http://digitool.Library.McGill.CA:80/R/?func=dbin-jump-full&object_id=101135 |
| op_rights |
© Joy R. Hartzler, 2007 |
| _version_ |
1766233820958294016 |
| spelling |
ftcanadathes:oai:collectionscanada.gc.ca:QMM.101135 2023-05-15T18:43:25+02:00 The geological exploration of kimberlitic rocks in Québec / Hartzler, Joy R. Master of Science (Department of Earth and Planetary Sciences.) 2007 application/pdf http://digitool.Library.McGill.CA:80/R/?func=dbin-jump-full&object_id=101135 en eng McGill University alephsysno: 002612144 proquestno: AAIMR32714 Theses scanned by UMI/ProQuest. http://digitool.Library.McGill.CA:80/R/?func=dbin-jump-full&object_id=101135 © Joy R. Hartzler, 2007 Kimberlite -- Québec (Province) Geochemical prospecting -- Québec (Province) Electronic Thesis or Dissertation 2007 ftcanadathes 2014-02-16T01:08:18Z Diamonds have been discovered in a variety of potassic ultramafic rocks including group-I and group-II kimberlites, olivine lamproites and aillikites, all of which are macroscopically similar and can be difficult to differentiate when viewed under the microscope. However, group-I kimberlites, and to a much lesser extent group-II kimberlites and olivine lamproites, are known to contain economic concentrations of diamonds. This study addresses the problem of distinguishing among different types of kimberlitic and related rocks by developing a geochemically-based method for classifying them. Geochemical methods have been largely ignored in the classification of kimberlites and related rock types due to high concentrations of xenoliths. However, this problem can be largely overcome by only selecting matrix material for analysis. An evolving kimberlitic magma will become enriched or improvished in Si due to the fractionation of olivine and phlogopite, depending on the initial Si concentration of the magma. As they have low Si concentrations, group-I kimberlites and aillikites can be separated from group-II kimberlites and meimechites, which have higher Si concentrations for any Mg content. Furthermore, since aillikites and meimechites are relatively rich in Fe compared to group-I and group-II kimberlites, these rock types form four separate fields on a Si vs. Fe discrimination diagram. Similar rock-type separation is observed when the ratio of La to Yb is plotted against the ratio of Sm to Yb. Kimberlite and other potassic ultramafic rocks were sampled from nine areas in Quebec: the Otish Mountains, Wemindji, Torngat Mountains, Desmaraisville, Temiscamingue, Ile Bizard, Lac Leclair, Baie James and Ayer's Cliff regions. Major and selected trace element concentrations were determined by XRF analysis for all samples, while a subset of representative samples was selected for trace element analysis by ICP-MS. Electron microprobe analyses of unaltered olivine and phlogopite were also conducted. Of the 37 samples that were classified both mineralogically and chemically, 23 or 62% were correctly classified using Fe and Si. This number increases to 84%, if the REE are used in conjunction with Si and Fe. The Si vs. Fe discrimination diagram separates group-I kimberlite from most aillikite and meimechite rocks and group-II kimberlite/olivine lamproite rocks from most aillikite and meimechite rocks. Therefore, major and trace element geochemistry offers an important tool for the classification of kimberlitic rocks. Vasilenko et al. (2002) and Francis (2003) both suggested that diamond grades can be correlated with the major element compositions of the kimberlites. The data collected in this study confirm the inverse relationship between TiO2 concentration and diamond grade. The lowest TiO 2 values were obtained on samples from the Otish Mountains and Renard samples in particular. Other areas of Quebec are characterized by higher TiO2 contents with most samples containing greater than 2 wt% TiO 2. Therefore, the kimberlitic rocks from the Renard locality have the greatest potential for an economic diamond deposit. The origin of this correlation needs to be explored, however, because it is unclear whether this is a feature of the mantle source, or reflects the survivability of diamonds within the kimberlites. Thesis Wemindji Theses Canada/Thèses Canada (Library and Archives Canada) Baie James ENVELOPE(-80.500,-80.500,53.500,53.500) Lac Leclair ENVELOPE(-77.162,-77.162,60.821,60.821) Renard ENVELOPE(-63.767,-63.767,-65.017,-65.017) Torngat Mountains ENVELOPE(-63.665,-63.665,59.000,59.000) Wemindji ENVELOPE(-78.816,-78.816,53.000,53.000) |