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An analysis and production book of Born yesterday by Garson Kanin /Conrod, Douglas Keith. January 1950 (has links)
Thesis (M.A.)--Ohio State University, 1950. / Includes bibliographical references (leaves 62-63). Available online via OhioLINK's ETD Center.
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MacBird! : a history and feminist critique of Barbara Garson's radical play /Todd, Susan Gayle. January 2009 (has links) (PDF)
Thesis (Ph. D.)--University of Texas at Austin, 2009. / Vita. Includes bibliographical references (leaves 227-246).
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STRUCTURAL CONTROLS OF Ni-Cu-PGE ORES AND MOBILIZATION OF METALS AT THE GARSON MINE, SUDBURYMukwakwami, Joshua 24 January 2014 (has links)
The Garson Ni-Cu-PGE deposit is located on the South Range of the 1850 Ma Sudbury
structure along the contact between the Sudbury Igneous Complex (SIC) and the
underlying metasedimentary and metavolcanic rocks of the Paleoproterozoic Huronian
Supergroup. It comprises four ore bodies that are hosted by E-W-trending shear zones
that dip steeply to the south. The shear zones formed as south-directed D1 thrusts in
response to flexural-slip during regional buckling of the SIC. They imbricated the ore
zones, the SIC norite, the underlying Huronian rocks and they emplaced slivers of
Huronian rocks and anatectic breccia into the overlying Main Mass norite. Coexisting
garnet-amphibole pairs yielded syn-D1 amphibolite facies metamorphic temperatures
ranging from ~550°C to 590°C. The shear zones were coeval with the moderately southdipping South Range and Thayer Lindsley shear zones, which formed to accommodate
the strain in the hinge zone as the SIC tightened with progressive D1 shortening. The SE limb of the SIC was overturned together with the D1 thrusts, which were then reactivated as steeply south-dipping reverse shear zones during syn-D2 greenschist metamorphism.Syn-D2 metamorphic titanite yield a U-Pb age of ca. 1849 ± 6 Ma, suggesting that D1 and D2 are part of a single progressive deformation event that occurred immediately after
crystallization of the SIC during the Penokean Orogeny.
The ore bodies plunge steeply to the south parallel to the colinear L1 and L2 stretching
mineral lineations. Ore types consist mainly of pyrrhotite-pentlandite-chalcopyrite breccia ores, but also include pyrrhotite-pentlandite-chalcopyrite disseminated sulfide
mineralization in norite, and syn-D2 quartz-calcite-chalcopyrite-pyrrhotite-pentlandite
iv veins. In the breccia ores, matrix sulfides surround silicate rock fragments that have a strong shape-preferred orientation defining a pervasive foliation. The fragments are highly stretched parallel to the mineral lineations in wall rocks, suggesting that the ore bodies are zones of high strain. Pyrrhotite and chalcopyrite occur in piercement structures, in boudin necks between fragments, in fractures in wall rocks and in fold hinges, suggesting that the sulfides were mobilized by ductile plastic flow. Despite evidence of high strain in the ore zones, the sulfide matrix in D1 and D2 breccia ores show little evidence of strain as they consist predominantly of polygonal pyrrhotite aggregates, suggesting that they recrystallized during, or immediately after D1 and D2. However, rare elongate pyrrhotite grains aligned parallel to S2 are locally preserved only in D2 breccia ores. Exsolution of pentlandite loops along grain boundaries of elongate pyrrhotite formed S2-parallel pentlandite-rich layers in D2 breccia ores, whereas the pentlandite
loops are multi-oriented in D1 contact breccia as they were exsolved along grain
boundaries polygonal pyrrhotite. Because exsolution of pentlandite post-date D1 and D2, and that individual pentlandite grains neither have a shape-preferred orientation nor show evidence for cataclastic flow, the sulfides reverted to, and were mobilized as a
homogeneous metamorphic monosulfide solid solution (mss) during D1 and possibly D2.
This is in agreement with predictions from phase equilibria as the average Garson
composition plots within the mss field in Fe-Ni-S ternary diagram at temperatures above
~400°C.
Disseminated and breccia ores at Garson have similar mantle-normalized multi-element
chalcophile patterns as undeformed contact-type disseminated and massive ore,
v respectively, at the well known Creighton mine in the South Range. This suggests that the Garson ores are magmatic in origin and that their compositions were not significantly altered by hydrothermal fluids and deformation. The lack of variations in Ni tenors between the disseminated and breccias ores suggest that the R-factor was not the process controlling metal tenors because the disseminated sulfides do not consistently have higher metal tenors than the breccia ore. The breccia ores are enriched in Rh-Ru-Ir and are
depleted in Cu-Pd-Pt-Au, in contrast to footwall-type ore at the nearby Garson Ramp
mine which is enriched in the same metals. When Ni100, Rh100, Ir100, Pt100 and Pd100 are
plotted against Cu100, the breccia and footwall-type ore analyses plot along model mss
fractionation and sulfide melt model curves, suggesting that these two ore types are
related by mss fractionation.
In summary, the Garson breccia ores are mss cumulates that settled quickly at the base of
the SIC via a gravity filtration process, and were mobilized as a metamorphic mss by
ductile plastic flow during D1 and D2. Despite minor local hydrothermal mobilization of some metals, the study confirms findings from other studies that highly deformed Ni-Cu-PGE deposits, such as the Garson deposit, can provide important information on the genesis of the deposits.
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Structural controls of Ni-Cu-PGE ores and mobilization of metals at the Garson Mine, SudburyMukwakwami, Joshua 31 July 2013 (has links)
The Garson Ni-Cu-PGE deposit is located on the South Range of the 1850 Ma Sudbury
structure along the contact between the Sudbury Igneous Complex (SIC) and the
underlying metasedimentary and metavolcanic rocks of the Paleoproterozoic Huronian
Supergroup. It comprises four ore bodies that are hosted by E-W-trending shear zones
that dip steeply to the south. The shear zones formed as south-directed D1 thrusts in
response to flexural-slip during regional buckling of the SIC. They imbricated the ore
zones, the SIC norite, the underlying Huronian rocks and they emplaced slivers of
Huronian rocks and anatectic breccia into the overlying Main Mass norite. Coexisting
garnet-amphibole pairs yielded syn-D1 amphibolite facies metamorphic temperatures
ranging from ~550°C to 590°C. The shear zones were coeval with the moderately southdipping
South Range and Thayer Lindsley shear zones, which formed to accommodate
the strain in the hinge zone as the SIC tightened with progressive D1 shortening. The SE
limb of the SIC was overturned together with the D1 thrusts, which were then reactivated
as steeply south-dipping reverse shear zones during syn-D2 greenschist metamorphism.
Syn-D2 metamorphic titanite yield a U-Pb age of ca. 1849 ± 6 Ma, suggesting that D1 and
D2 are part of a single progressive deformation event that occurred immediately after
crystallization of the SIC during the Penokean Orogeny.
The ore bodies plunge steeply to the south parallel to the colinear L1 and L2 stretching
mineral lineations. Ore types consist mainly of pyrrhotite-pentlandite-chalcopyrite breccia
ores, but also include pyrrhotite-pentlandite-chalcopyrite disseminated sulfide
mineralization in norite, and syn-D2 quartz-calcite-chalcopyrite-pyrrhotite-pentlandite
iv
veins. In the breccia ores, matrix sulfides surround silicate rock fragments that have a
strong shape-preferred orientation defining a pervasive foliation. The fragments are
highly stretched parallel to the mineral lineations in wall rocks, suggesting that the ore
bodies are zones of high strain. Pyrrhotite and chalcopyrite occur in piercement
structures, in boudin necks between fragments, in fractures in wall rocks and in fold
hinges, suggesting that the sulfides were mobilized by ductile plastic flow. Despite
evidence of high strain in the ore zones, the sulfide matrix in D1 and D2 breccia ores show
little evidence of strain as they consist predominantly of polygonal pyrrhotite aggregates,
suggesting that they recrystallized during, or immediately after D1 and D2. However, rare
elongate pyrrhotite grains aligned parallel to S2 are locally preserved only in D2 breccia
ores. Exsolution of pentlandite loops along grain boundaries of elongate pyrrhotite
formed S2-parallel pentlandite-rich layers in D2 breccia ores, whereas the pentlandite
loops are multi-oriented in D1 contact breccia as they were exsolved along grain
boundaries polygonal pyrrhotite. Because exsolution of pentlandite post-date D1 and D2,
and that individual pentlandite grains neither have a shape-preferred orientation nor show
evidence for cataclastic flow, the sulfides reverted to, and were mobilized as a
homogeneous metamorphic monosulfide solid solution (mss) during D1 and possibly D2.
This is in agreement with predictions from phase equilibria as the average Garson
composition plots within the mss field in Fe-Ni-S ternary diagram at temperatures above
~400°C.
Disseminated and breccia ores at Garson have similar mantle-normalized multi-element
chalcophile patterns as undeformed contact-type disseminated and massive ore,
v
respectively, at the well known Creighton mine in the South Range. This suggests that the
Garson ores are magmatic in origin and that their compositions were not significantly
altered by hydrothermal fluids and deformation. The lack of variations in Ni tenors
between the disseminated and breccias ores suggest that the R-factor was not the process
controlling metal tenors because the disseminated sulfides do not consistently have higher
metal tenors than the breccia ore. The breccia ores are enriched in Rh-Ru-Ir and are
depleted in Cu-Pd-Pt-Au, in contrast to footwall-type ore at the nearby Garson Ramp
mine which is enriched in the same metals. When Ni100, Rh100, Ir100, Pt100 and Pd100 are
plotted against Cu100, the breccia and footwall-type ore analyses plot along model mss
fractionation and sulfide melt model curves, suggesting that these two ore types are
related by mss fractionation.
In summary, the Garson breccia ores are mss cumulates that settled quickly at the base of
the SIC via a gravity filtration process, and were mobilized as a metamorphic mss by
ductile plastic flow during D1 and D2. Despite minor local hydrothermal mobilization of
some metals, the study confirms findings from other studies that highly deformed Ni-Cu-
PGE deposits, such as the Garson deposit, can provide important information on the
genesis of the deposits.
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STRUCTURAL CONTROLS OF Ni-Cu-PGE ORES AND MOBILIZATION OF METALS AT THE GARSON MINE, SUDBURYMukwakwami, Joshua 15 August 2013 (has links)
The Garson Ni-Cu-PGE deposit is located on the South Range of the 1850 Ma Sudbury
structure along the contact between the Sudbury Igneous Complex (SIC) and the
underlying metasedimentary and metavolcanic rocks of the Paleoproterozoic Huronian
Supergroup. It comprises four ore bodies that are hosted by E-W-trending shear zones
that dip steeply to the south. The shear zones formed as south-directed D1 thrusts in
response to flexural-slip during regional buckling of the SIC. They imbricated the ore
zones, the SIC norite, the underlying Huronian rocks and they emplaced slivers of
Huronian rocks and anatectic breccia into the overlying Main Mass norite. Coexisting
garnet-amphibole pairs yielded syn-D1 amphibolite facies metamorphic temperatures
ranging from ~550°C to 590°C. The shear zones were coeval with the moderately southdipping
South Range and Thayer Lindsley shear zones, which formed to accommodate
the strain in the hinge zone as the SIC tightened with progressive D1 shortening. The SE
limb of the SIC was overturned together with the D1 thrusts, which were then reactivated
as steeply south-dipping reverse shear zones during syn-D2 greenschist metamorphism.
Syn-D2 metamorphic titanite yield a U-Pb age of ca. 1849 ± 6 Ma, suggesting that D1 and
D2 are part of a single progressive deformation event that occurred immediately after
crystallization of the SIC during the Penokean Orogeny.
The ore bodies plunge steeply to the south parallel to the colinear L1 and L2 stretching
mineral lineations. Ore types consist mainly of pyrrhotite-pentlandite-chalcopyrite breccia
ores, but also include pyrrhotite-pentlandite-chalcopyrite disseminated sulfide
mineralization in norite, and syn-D2 quartz-calcite-chalcopyrite-pyrrhotite-pentlandite
iv
veins. In the breccia ores, matrix sulfides surround silicate rock fragments that have a
strong shape-preferred orientation defining a pervasive foliation. The fragments are
highly stretched parallel to the mineral lineations in wall rocks, suggesting that the ore
bodies are zones of high strain. Pyrrhotite and chalcopyrite occur in piercement
structures, in boudin necks between fragments, in fractures in wall rocks and in fold
hinges, suggesting that the sulfides were mobilized by ductile plastic flow. Despite
evidence of high strain in the ore zones, the sulfide matrix in D1 and D2 breccia ores show
little evidence of strain as they consist predominantly of polygonal pyrrhotite aggregates,
suggesting that they recrystallized during, or immediately after D1 and D2. However, rare
elongate pyrrhotite grains aligned parallel to S2 are locally preserved only in D2 breccia
ores. Exsolution of pentlandite loops along grain boundaries of elongate pyrrhotite
formed S2-parallel pentlandite-rich layers in D2 breccia ores, whereas the pentlandite
loops are multi-oriented in D1 contact breccia as they were exsolved along grain
boundaries polygonal pyrrhotite. Because exsolution of pentlandite post-date D1 and D2,
and that individual pentlandite grains neither have a shape-preferred orientation nor show
evidence for cataclastic flow, the sulfides reverted to, and were mobilized as a
homogeneous metamorphic monosulfide solid solution (mss) during D1 and possibly D2.
This is in agreement with predictions from phase equilibria as the average Garson
composition plots within the mss field in Fe-Ni-S ternary diagram at temperatures above
~400°C.
Disseminated and breccia ores at Garson have similar mantle-normalized multi-element
chalcophile patterns as undeformed contact-type disseminated and massive ore,
v
respectively, at the well known Creighton mine in the South Range. This suggests that the
Garson ores are magmatic in origin and that their compositions were not significantly
altered by hydrothermal fluids and deformation. The lack of variations in Ni tenors
between the disseminated and breccias ores suggest that the R-factor was not the process
controlling metal tenors because the disseminated sulfides do not consistently have higher
metal tenors than the breccia ore. The breccia ores are enriched in Rh-Ru-Ir and are
depleted in Cu-Pd-Pt-Au, in contrast to footwall-type ore at the nearby Garson Ramp
mine which is enriched in the same metals. When Ni100, Rh100, Ir100, Pt100 and Pd100 are
plotted against Cu100, the breccia and footwall-type ore analyses plot along model mss
fractionation and sulfide melt model curves, suggesting that these two ore types are
related by mss fractionation.
In summary, the Garson breccia ores are mss cumulates that settled quickly at the base of
the SIC via a gravity filtration process, and were mobilized as a metamorphic mss by
ductile plastic flow during D1 and D2. Despite minor local hydrothermal mobilization of
some metals, the study confirms findings from other studies that highly deformed Ni-Cu-
PGE deposits, such as the Garson deposit, can provide important information on the
genesis of the deposits.
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MacBird!: a history and feminist critique of Barbara Garson’s radical playTodd, Susan Gayle 22 October 2009 (has links)
Barbara Garson’s controversial play, MacBird!, was written and produced during the Vietnam War era and Johnson administration. The satirical Shakespeare adaptation equates LBJ with Macbeth, the villainous tragic hero who murders his king in order to gain the Scottish crown. The implication that Johnson was responsible for the assassination of JFK created a fury of controversy among critics and the public, as well as the political leaders who were parodied.
The play was first published and circulated in 1966 as an underground leaflet. In 1967, it was produced off-Broadway with a cast that featured actors Rue McClanahan, William Devane, Cleavon Little, and Stacy Keach, who won an Obie Award for his performance of the title role. The show launched the careers of these actors. Critics were divided in their reviews of the play’s literary merit, but all seemed to agree that the piece was shocking and significant because it flew in the face of patriotism and of reverence for presidential authority. At the time of its production, acclaimed theater critic Robert Brustein named MacBird! “the most explosive play” of the Sixties theater movement. This dissertation presents the history of the play, within its social and political setting, from its inception through its production and abrupt disappearance at the peak of its success, which coincided with the assassination of Robert Kennedy. Relying upon methodology that includes primary and secondary sources, as well as interviews with the playwright and others involved in the play, this work presents the publication and production history of MacBird!, public and White House response to the play, a contextual analysis under a feminist lens, and a final chapter on MacBird! as a precursor to feminist adaptations of canonical works, Sixties-era Macbeth adaptations, and the notable women whose work intersected in MacBird! MacBird! was a tremendous event in theater history; it belongs at the fore of adaptation studies, particularly Shakespeare and feminist adaptation studies; it is a prime model of performance as a political tool and therefore earns a central place in performance studies; and because it is an attack on patriarchal power and a rare example of a Sixties radical play written by a woman, Barbara Garson needs to be recognized among remarkable women of theater. / text
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