317,510 research outputs found
Gale Morant Slave Trade Papers: York Estate - Accounts 1791
Gale and Morant family papers relating to Jamaican slave plantations. The Gale and the Morant families came to Jamaica separately in the 17th century soon after the island was seized in 1655. Major John Gale (1637-1689) was buried there, as was John Morant who died in 1683. Various marriages linked their families, as they both acquired plantations, large estates, and great wealth. In 1754, John Morant owned 4631 acres in Clarendon and 3582 acres in Vere. Five members of the Gale family owned more than 6000 acres of the island. The Jamaican estates were handed down to subsequent generations of the family.See online Archive Catalogue available at the University of Exeter website
Anion coordination and anion-templated assembly: Highlights from 2002 to 2004
This review article highlights advances made in abiotic anion coordination chemistry from 2002 to 2004. The structure of this review is that similar to the previous reviews in this series that covered 1997-2001 [P.A. Gale, Coord. Chem. Rev. 199 (2000) 181; P.A. Gale, Coord. Chem. Rev. 213 (2001) 79; P.A. Gale, Coord. Chem. Rev. 240 (2003) 191]. The first section examines anion receptors that do not contain metal ions. This is followed by a review of metal containing anion receptors and finally the role of anions in directing the self-assembly of complex molecular architectures are presented in the final section
Gale Morant Slave Trade Papers: York Estate General Accounts - Current Account 1811
Gale and Morant family papers relating to Jamaican slave plantations. The Gale and the Morant families came to Jamaica separately in the 17th century soon after the island was seized in 1655. Major John Gale (1637-1689) was buried there, as was John Morant who died in 1683. Various marriages linked their families, as they both acquired plantations, large estates, and great wealth. In 1754, John Morant owned 4631 acres in Clarendon and 3582 acres in Vere. Five members of the Gale family owned more than 6000 acres of the island. The Jamaican estates were handed down to subsequent generations of the family.See online Archive Catalogue available at the University of Exeter website
2,5-Diamidopyrrole clefts and other new anion receptors
This presentation covers work on pyrrole conating anion receptors in the Gale Group up to October 200
Cyclic and Acyclic Pyrrole Based Anion Receptors
This presentation covers work on pyrrole containing anion receptors in the Gale group
Gale Morant Slave Trade Papers: Miscellaneous Mount Hindmost Accounts - Letter dated 8th June 1810
Gale and Morant family papers relating to Jamaican slave plantations. The Gale and the Morant families came to Jamaica separately in the 17th century soon after the island was seized in 1655. Major John Gale (1637-1689) was buried there, as was John Morant who died in 1683. Various marriages linked their families, as they both acquired plantations, large estates, and great wealth. In 1754, John Morant owned 4631 acres in Clarendon and 3582 acres in Vere. Five members of the Gale family owned more than 6000 acres of the island. The Jamaican estates were handed down to subsequent generations of the family.See online Archive Catalogue available at the University of Exeter website
Gale Morant Slave Trade Papers: Miscellaneous Mount Hindmost Accounts - Current Account 1828
Gale and Morant family papers relating to Jamaican slave plantations. The Gale and the Morant families came to Jamaica separately in the 17th century soon after the island was seized in 1655. Major John Gale (1637-1689) was buried there, as was John Morant who died in 1683. Various marriages linked their families, as they both acquired plantations, large estates, and great wealth. In 1754, John Morant owned 4631 acres in Clarendon and 3582 acres in Vere. Five members of the Gale family owned more than 6000 acres of the island. The Jamaican estates were handed down to subsequent generations of the family.See online Archive Catalogue available at the University of Exeter website
Anion and ion-pair receptor chemistry: highlights from 2000 and 2001
This review article highlights advances made in abiotic anion coordination chemistry in 2000 and 2001. The structure of this review is that similar to the previous reviews in this series that covered 1997, 1998 and 1999 [P.A. Gale, Coord. Chem. Rev. 199 (2000) 18 1; P.A. Gale, Coord. Chem. Rev. 213 (2001) 79]. The review also includes examples of ion-pair receptors. The first section examines anion receptors that do not contain metal ions. This is followed by a review of metal containing anion receptors in which the metal can function as: (i) a coordination site for the anion; (ii) an agent withdrawing electron density from the receptor; (iii) an organisational element in the receptor; (iv) a sensor; and (v) a co-bound guest in ion-pair receptor. Examples of the role of anions in directing the self-assembly of complex molecular architectures are presented in the final section
Sequence of infilling events in Gale crater, Mars: Results from morphology, stratigraphy, and mineralogy
Gale Crater is filled by sedimentary deposits including a mound of layered deposits,
Aeolis Mons. Using orbital data, we mapped the crater infillings and measured their
geometry to determine their origin. The sediment of Aeolis Mons is interpreted to be
primarily air fall material such as dust, volcanic ash, fine-grained impact products, and
possibly snow deposited by settling from the atmosphere, as well as wind-blown sands
cemented in the crater center. Unconformity surfaces between the geological units are
evidence for depositional hiatuses. Crater floor material deposited around Aeolis Mons
and on the crater wall is interpreted to be alluvial and colluvial deposits. Morphologic
evidence suggests that a shallow lake existed after the formation of the lowermost part of
Aeolis Mons (the Small yardangs unit and the mass-wasting deposits). A suite of several
features including patterned ground and possible rock glaciers are suggestive of periglacial
processes with a permafrost environment after the first hundreds of thousands of years
following its formation, dated to ~3.61 Ga, in the Late Noachian/Early Hesperian.
Episodic melting of snow in the crater could have caused the formation of sulfates and
clays in Aeolis Mons, the formation of rock glaciers and the incision of deep canyons and
valleys along its flanks as well as on the crater wall and rim, and the formation of a lake in
the deepest portions of Gale
Cladistic revision of Cretaceous Brachylepadomorpha and Verrucomorpha dataset
This dataset supports the publication by Andy S. Gale & S U. Vidovic "The origins of major sessile cirripede groups; a revision of Cretaceous Brachylepadomorpha and Verrucomorpha" in Journal of Systematic Palaeontology
DOI: 10.1080/14772019.2023.2258370
This dataset comprises the TNT script to run a cladistic analysis of sessile cirripede groups and bootstrap resampling with 1000 replicates; the output files from TNT; the supporting Nexus file; and an R script for post-analysis of the tree to calculate the Gap Excess Ratio (GER).
The cladistic analysis comprises 48 characters, one of which is continuous, all others were treated as unordered with equal weights. The TNT script also contains instructions to run an implied weights analysis.
To successfully execute the TNT script, the user will need to include the correct file path to their own copy of Stats.run, a TNT script for calculating the ensemble consistency index and retention index.
TNT scripts can be given a .tnt extension and can be read by TNT and Mesquite. Nexus files can be given a .nex extension and can be read by Mesquite and TNT. R files can be given a .r extension and can be run in RStudio. The output log can be read in plain text, .tre and .nex output files can be opened by all the software used in this study.
Contributions to this dataset:
Gale made intellectual contributions with respect to the anatomy, systematics and stratigraphic occurrence of sessile cirripede groups. Gale: co-designed the analysis; wrote the characters; coded the matrix.
Vidovic made intellectual contributions with respect to cladistic analysis and post-analysis. Vidovic: wrote the dataset; co-designed and executed the analysis; wrote the scripts and functions; created the files; edited the characters; coded the matrix.</span
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