Magma chambers are an essential component in the construction of oceanic and continental lithosphere, and profoundly influence the thermal and mechanical behavior of the crust and mantle. The mechanical properties of a magma chamber change during cooling and crystallization, as accommodation of deformation changes from magmatic flow to solid-state processes. Thus, to understand the thermo-mechanical evolution of magma chambers, it is crucial to understand the relative importance of magmatic and solid-state flow, and the nature of the transition between them. This project is investigating such a transition preserved in the San Jose pluton, Baja California, Mexico. The pluton postdates the regional deformation, and so the transition from magmatic to solid-state flow reflects internal magma-chamber dynamics. Such transitions are rarely observed in post-tectonic plutons, and our results will benefit others who are working in more complex syntectonic examples. Detailed mapping and collection of spatially oriented samples is taking place along four transects in the pluton. X-ray compositional mapping, microstructural analysis and electron backscatter diffraction studies are being employed to track the chemical evolution of the deforming and crystallizing pluton, and to evaluate deformation mechanisms and the origins of the magmatic foliations. The project is supporting a PhD student, and several senior undergraduates at the University of Maine will participate as part of their Capstone Experience

Johnson, Scott E.

English

University of Maine

The University of MaineDigitalCommons@UMaineUniversity of Maine Office of Research andSponsored Programs: Grant Reports Special Collections1-8-2004Magmatic to Solid-State Fabric Transition in a Post-Tectonic Tonalite PlutonScott E. JohnsonPrincipal Investigator; University of Maine, Orono, johnsons@maine.eduFollow this and additional works at: https://digitalcommons.library.umaine.edu/orsp_reportsPart of the Geology Commons, Geophysics and Seismology Commons, and the VolcanologyCommonsThis Open-Access Report is brought to you for free and open access by DigitalCommons@UMaine. It has been accepted for inclusion in University ofMaine Office of Research and Sponsored Programs: Grant Reports by an authorized administrator of DigitalCommons@UMaine. For moreinformation, please contact um.library.technical.services@maine.edu.Recommended CitationJohnson, Scott E., "Magmatic to Solid-State Fabric Transition in a Post-Tectonic Tonalite Pluton" (2004). University of Maine Office ofResearch and Sponsored Programs: Grant Reports. 71.https://digitalcommons.library.umaine.edu/orsp_reports/71Final Report: 0087661Page 1 of 5Final Report for Period: 01/2001 - 12/2003 Submitted on: 01/08/2004Principal Investigator: Johnson, Scott E. Award ID: 0087661Organization: University of Maine       Title:Magmatic to Solid-State Fabric Transition in a Post-Tectonic Tonalite PlutonProject ParticipantsSenior PersonnelName: Johnson, ScottWorked for more than 160 Hours: YesContribution to Project: Name: Vernon, RonaldWorked for more than 160 Hours: YesContribution to Project: Participant under subcontract to the University of Southern California.Name: Fanning, MarkWorked for more than 160 Hours: NoContribution to Project: Performed SHRIMP U-Pb geochronology at the Australian National University.Name: Fletcher, JohnWorked for more than 160 Hours: NoContribution to Project: Collaborator at University in Baja California, Mexico.Name: Paterson, ScottWorked for more than 160 Hours: NoContribution to Project: Long-term collaborator in Baja studies.Post-docName: Upton, PhaedraWorked for more than 160 Hours: NoContribution to Project: Phaedra is a postdoctoral fellow at UMaine working with Peter Koons. She became involved owing to her expertise in numericalmodeling.Graduate StudentName: Melis, ErwinWorked for more than 160 Hours: YesContribution to Project: Erwin is one of my PhD students. His thesis project was largely funded by this grant. He intends to finish in 2004.Name: Gerbi, ChristopherWorked for more than 160 Hours: YesContribution to Project: Chris is one of my PhD students. Although he is working on a different project for his PhD, with different NSF funding, he becameinterested in numerical modeling of magma chanber growth - an important topic for the current proposal.Final Report: 0087661Page 2 of 5Undergraduate StudentName: Perry, EthanWorked for more than 160 Hours: NoContribution to Project: Ethan conducted an undergraduate research project on rocks collected in this project.Technician, ProgrammerOther ParticipantResearch Experience for UndergraduatesOrganizational PartnersUniversity of Southern CaliforniaR.H. Vernon at USC was subcontracted under this award.Other Collaborators or Contacts Activities and FindingsResearch and Education Activities:The mechanical properties of a magma chamber change during cooling and crystallization, as accommodation of deformation changes frommagmatic flow to solid-state processes. To understand the thermo-mechanical evolution of magma chambers, it is crucial to understand therelative importance of magmatic and solid-state flow, and the nature of the transition between them. This project investigated such a transitionpreserved in the San JosÚ pluton, Baja California, MÚxico. The pluton postdates the regional deformation, and so the transition from magmatic tosolid-state flow reflects internal magma-chamber dynamics. Such transitions are rarely observed in post-tectonic plutons. Some specific topicsthat have been evaluated include: (1) microstructural evidence for fast strain rates during pluton growth; (2) evidence for contact melting andwhether it plays a progressively more or less important role as the volume percent of melt decreases; (3) how rapidly the microstructural transition from melt-dominated to solid-statedeformation occurs from the interior of the pluton to its margins; (4) whether solid-state deformation in the pluton margins continued aftercomplete crystallization; (5) changes in deformation mechanisms and fabric-forming processes through time during crystallization; and (6)whether we can track deformation histories in rocks that have experienced the magmatic to solid-state flow transition.We have mapped several hundred square kilometers in and around the San Jose pluton, collected hundreds of samples for microstructural and chronological analysis, conducted numerical experiments designed to explore rates of pluton growth and foliation development during pluton emplacement, conducted electron microprobe analyses of relevantigneous and metamorphic rocks, presented 11 talks/posters at national meetings and published 5 papers in leading journals. We will presentadditional abstracts at the spring 2004 AGU, and PhD student Erwin Melis will have three chapters of his thesis submitted for publication bythe end of 2004.Findings:We have made several findings that we believe represent advances in the science. These are listed below in no particular order of importance.1) We evaluated the emplacement history of the San Jose pluton using what is probably the most detailed data sets of any pluton-emplacementpublication (Johnson et al., 2003). We have some of the best evidence ever published that the pluton expanded laterally during emplacement.This opens the question of whether a magma chamber can generate sufficient stress to cause ductile deformation of wall rocks duringemplacement - we are currently addressing this problem with 3D thermo/mechanical modeling.Final Report: 0087661Page 3 of 52) We developed a three-dimensional geometric model to quantify host-rock strain rates during dike-fed pluton expansion. Because dikes mustmaintain a critical width and velocity in order to propagate from source to sink without freezing, they must support a high volumetric magmaflow rate. We calculate, for example, that strain rates in a mechanically homogeneous aureole approach 10-7.5 s-1 around 1 km radius sphericalplutons filling at 179 m3 s-1 (Gerbi et al., in press).3) We have 2 papers in press discussing structural evidence for such high strain rates in pluton aureoles (Johnson et al., in press; Vernon et al.,in press). These two papers are the first that we are aware of in which natural microstructural observations are used to document brittledeformation at high temperature, melt-enhanced cataclasis, and very fast strain rates during pluton emplacement.Training and Development:The project has supported the PhD thesis research of Erwin Melis. Erwin has learned about advanced field mapping techniques, analyticaltechniques for geochronology and electron microprobe analysis, techniques for microstructural analysis of deformed rocks, and techniques for2D and 3D thermal modeling. Erwin has also had the opportunity to be a teaching assistant in our department, and has also presented talks andposters at national meetings, and in our department.Chris Gerbi is another PhD student affected by this project. Chris was responsible for developing numerical models for dike-fed pluton growth,which also introduced him to thermal modeling. Although this is a small part of Chris's thesis work, he has had the opportunity to present a talkon his numerical modeling at a national meeting and in our department, has also had the opportunity to be a TA in our department, and has eventaught his own section of introductory geology in our department as a Continuing Education offering.Ethan Perry is an undergraduate student who learned skills of microstructural analysis and electron microprobe analysis as part of anundergraduate research project that he conducted on rocks collected for this project.Outreach Activities:Journal PublicationsJohnson, S.E., Fletcher, J.M., Fanning, C.M., Vernon, R.H., Paterson, S.R. and Tate, M.C., "Structure, emplacement and lateral expansion ofthe San Jose tonalite pluton, Peninsular Ranges batholith, Baja California, Mexico.", Journal of Structural Geology, p. 1933, vol. 25, (2003).PublishedGerbi, C.C., Johnson, S.E. and Paterson, S.R., "Implications of rapid, dike-fed pluton growth for host-rock strain rates and emplacementmechanisms.", Journal of Structural Geology, p. , vol. 26, (2004). AcceptedJohnson, S.E., Vernon, R.H. and Upton, P., "Initiation of microshear zones and progressive strain-rate partitioning in the crystallizing carapaceof a tonalite pluton: microstructural evidence and numerical modeling.", Journal of Structural Geology, p. , vol. 26, (2004). AcceptedVernon, R.H., Johnson, S.E. and Melis, E.A., "Transition from magmatic to solid-state flow in the marginal deformation of an intruding pluton:the San Jose tonalite, Baja California, Mexico.", Journal of Structural Geology, p. , vol. 26, (2004). AcceptedJohnson, S E., Koons, P.O., Upton, P.,, "Transient Dilatancy in the Transport of Magma and Flareup Magmatic Events.", Eos Trans. AGU, p.V41A-08, vol. 86, (2003). PublishedJohnson, S.E., Vernon, R.H., Upton, P., Melis, E.A., "Evidence for fast magma chamber construction: the deformed carapace of the San Josetonalite pluton, Mexico.", Geological Society of America Abstracts, p. 93, vol. 34, (2003). PublishedJohnson, S.E., Vernon, R.H., and Upton, P., "Emplacement-related microstructures in the deformed carapace of a tonalite pluton: evidence forfast chamber construction.", Geological Society of America Abstracts, p. 23-8, vol. 35, (2003). PublishedSchmidt, K.L., Paterson, S.R. and Johnson, S.E., "The Jurassic eastern Peninsular Ranges batholith in Baja California, Mexico: new ages froman ancient continental arc.", Geological Society of America Abstracts, p. A-97, vol. 34, (2002). PublishedFinal Report: 0087661Page 4 of 5Johnson, S.E., Gerbi, C.C. and Paterson, S.R., 2001, "Modeling strain rates around rapidly growing plutons.", Geological Society of AmericaAbstracts, p. A-212, vol. 33, (2001). PublishedMelis, E.A. and Johnson, S.E., "Syndeformational melting in Mesozoic tonalites and metapelites from the Sierra San Pedro Martir area, BajaCalifornia, Mexico.", Geological Society of America Abstracts, p. A-83, vol. 33, (2001). PublishedMelis, E.A. and Johnson, S.E., "Microstructures in the post-tectonic San Jose pluton, baja California, Mexico: Evidence for both magmatic andsolid-state deformation and their bearing on pluton emplacement.", Geological Society of America Abstracts, p. A-19, vol. 33, (2001).PublishedAlbertz, M., Paterson, S.R., Okaya, D. and Johnson, S. E., "Constraints on geological strain rates in contact aureoles during plutonemplacement: insights from thermo-mechanical modeling.", Geological Society of America Abstracts, p. A-172, vol. 32, (2000). PublishedJohnson, S. E., Fanning, C.M., Albertz, M. and Paterson, S.R., "Testing pluton growth models: approaches and examples.", Geological Societyof America Abstracts, p. A-172, vol. 32, (2000). PublishedJohnson, S.E., Schmidt, K.L. and Tate, M.C., "Ring complexes in the Peninsular Ranges Batholith, Baja California, Mexico and southernCalifornia, USA: middle- to upper-crustal magma plumbing systems.", Lithos, p. 187, vol. 61, (2002). PublishedBooks or Other One-time PublicationsWeb/Internet SiteOther Specific ProductsProduct Type:Data or databases                       Product Description:All of the geological field data collected in this project is included in an ongoing GIS-based database for our Baja research.Sharing Information:If other researchers wish to have access to this data they are welcome.Product Type:Physical collection (samples, etc.)     Product Description:All samples and thin sections accumulated as part of this project are retained at the University of Maine.Sharing Information:Scientists wishing access to these collections are welcome.ContributionsContributions within Discipline: 1) The debate continues in the granite/structure communities about whether or not plutons can expand laterally during emplacement. We havepublished what is probably the most compelling evidence for lateral expansion during the emplacement of a mid-crustal tonalite pluton in BajaCalifornia. This raises the interesting question of stresses that can develop within magma chambers in instances where devolatization may notbe a viable mechanism.2) Debate continues regarding the primary mechanism for magma ascent and emplacement in Earth's crust, the two leading hypotheses beingdiapirism and dike-fed pluton growth. These two models apparently cannot be uniquely tested solely on the basis of structural geometry. In aFinal Report: 0087661Page 5 of 5publication that led to this proposal (Johnson et al., 2001, Geology, 29, 727-730) I discussed the fact that the rates of these two processes wouldbe markedly different, and quantified the rates at which wall rocks would need to deform during dike-fed pluton growth. This has led to a newgeometrical/numerical model for calculating strain rates during the growth of spheroids (Gerbi et al., in press).3) The marginal rocks of the San Jose pluton have been used to test whether or not microstructures could preserve evidence for very fast strainrates in an instance where lateral pluton expansion was know to occur. Our two papers on this subject (Johnson et al. and Vernon et al., inpress) represent landmark studies in the use of microstructures to infer strain rates. They also provide the first real evidence for contact meltingand melt-enhanced embrittlement in naturally deformed, melt-bearing rocks.4) Johnson et al. (in press), mentioned above, makes the case that strain-rate and stress incompatibilities across the interfaces of differentminerals can drive brittle deformation leading to ductile foliation development. To explore the physics of this process, I used 3-D mechanicalmodeling. The model results indicate that strain-rate and stress incompatibilities across biotite-plagioclase interfaces, given reasonable velocityboundary conditions, can be high enough to fracture a plagioclase stress-supporting framework. The finer-grained plagioclase in the fracturezones link with the adjacent biotite grains to set up a self-organizing foliation. This is the first time, to my knowledge, that this has beenexplored mechanically. The results are consistent with our observations in the margin of the San Jose pluton, and consistent with analogexperimental work in two-phase systems.Contributions to Other Disciplines:  Contributions to Human Resource Development: This projects has completely supported the PhD studies of Erwin A. Melis (completing in 2004), partially supported the PhD studies ofChristopher C. Gerbi (completing in 2004), and provided an undergraduate research project for Ethan Perry (graduated in 2003). In addition tothese students, the project has provided research opportunities for Phaedra Upton, who is a postdoctoral researcher working with Peter Koons inour Department.Contributions to Resources for Research and Education: This proposal provided partial funding for a field vehicle that is used in our Baja research, and partial funding for research microscopy facilitiesin our Department.Contributions Beyond Science and Engineering:  Categories for which nothing is reported: Activities and Findings: Any Outreach Activities Any BookAny Web/Internet SiteContributions: To Any Other DisciplinesContributions: To Any Beyond Science and Engineering

Magmatic to Solid-State Fabric Transition in a Post-Tectonic Tonalite Pluton

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Magmatic to Solid-State Fabric Transition in a Post-Tectonic Tonalite Pluton

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