Ana Jesus scite author profile

As 21st century skills (e.g., creativity and collaboration) are informally developed by techsavvy learners in the Digital Age, technology-based strategies to develop such skills in nonformal and formal contexts are necessary to reduce the gap between academic and business organizations on the one hand, and the revolutionary wave of self-taught networked learners on the other. In light of this, the Gradual Immersion Method (GIM) was designed to enhance collaborative creativity using interactive devices and augmented reality (AR), to support creativity-based learning, such as in the integrated study of Science, Technology, Engineering, Arts and Mathematics (STEAM). The GIM consists of three intuitive modules wherein learners collaboratively achieve learning object goals through interaction with images and 3D models, in a sequential transition from 2D to 3D and then to AR. In this paper, the process is illustrated through the deployment of the GIM in the study of Surrealist art features, using the Art Movement Learning App (AMLA), an areaspecific technological solution based on the GIM, designed as foundation architecture for the investigation of a wide range of topics in an interactive manner.

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The Beja Layered Gabbroic Sequence (Ossa-Morena Zone, Southern Portugal): geochronology and geodynamic implications

Jesus

Munhá

Mateus

et al. 2007

Geodinamica Acta

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The Beja Igneous Complex (BIC) is a major geological feature in SW Iberian Variscides, consisting of three main units developed during different stages of the oblique collision between the Ossa Morena Zone (OMZ) upper plate and South Portuguese Zone (SPZ) lower plate, namely: (1) ca. 355 Ma to ca. 345 Ma Layered Gabbroic Sequence formed in early stages of collision magmatism; (2) the ca. 335-330 Ma to ca. 320 Ma Cuba-Alvito (gabbro-diorite) Complex formed throughout the late-collision magmatic event; and (3) the Baleizão Porphyry Complex corresponding to the period of post-collision magmatism, ca. 300 Ma. The new SHRIMP U-Pb age of 342±9 Ma reported here for amphibole-bearing pegmatite dykes cutting the layered gabbros is interpreted as dating the development of late fluid-rich melts in the Layered Gabbroic Sequence, synchronous with Fe-Cu-Co sulphide deposition. The close agreement between this data and available amphibole 40 Ar/ 39 Ar ages of BIC, Beja-Acebuches Ophiolite and other geological units of the OMZ southern border, may be taken as evidence for a moderate to rapid regional crustal uplift episode at ca. 340±5 Ma; this data, coupled with structural constraints, also allow to estimate the age for the transition between the D 2a -D 2b deformation phases of Variscan continental collision. A complex wedge system within the SW Iberian Variscides developed during this collision, involving the OMZ upper plate to the north and the SPZ passive margin in the lower plate. The Évora-Beja-Aracena Domain, located in the upper plate above the N-dipping subduction zone, is re-interpreted as a retro-wedge domain that was kinematically coupled to the SPZ pro-wedge and subduction system. Retro-wedge growth is linked to upper plate uplift (early collision) and a late-orogenic wedge thickening. The early stages of magmatism in the retro-wedge are related to asthenospheric mantle upwelling induced by the slab break-off. Regional LP-HT metamorphism and subsequent magmatic events in the retro-wedge domain were caused by long term high heat flow sustained by (1) mafic magma underplating, (2) stacking of high-heat producing upper-crustal lithologies, and reinforced (3) by (moderate to) rapid crustal uplifting. Mass advection and orogenic architecture were strongly affected by asymmetric removal towards the lower-part foreland basin and by transient mechanical properties of the wedge system associated with the anomalous thermal regime.

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Variscan ophiolite belts in the Ossa-Morena Zone (Southwest Iberia): Geological characterization and geodynamic significance

et al. 2010

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Structural Diagnosability of DES and Design of Reduced Petri Net Diagnosers

Ramírez-Treviño

Ruiz-Beltrán

Jesus

et al. 2012

IEEE Trans. Syst., Man, Cybern. A

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Evidence for underplating in the genesis of the Variscan synorogenic Beja Layered Gabbroic Sequence (Portugal) and related mesocratic rocks

et al. 2016

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Ana Jesus

Enhancing 21st Century Skills with AR: Using the Gradual Immersion Method to develop Collaborative Creativity

The Beja Layered Gabbroic Sequence (Ossa-Morena Zone, Southern Portugal): geochronology and geodynamic implications

Variscan ophiolite belts in the Ossa-Morena Zone (Southwest Iberia): Geological characterization and geodynamic significance

Structural Diagnosability of DES and Design of Reduced Petri Net Diagnosers

Evidence for underplating in the genesis of the Variscan synorogenic Beja Layered Gabbroic Sequence (Portugal) and related mesocratic rocks

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