Middle Proterozoic uplift events in the Dunbar dome of northeastern Wisconsin, USA
- Published:
- Volume 91, pages 138–150, (1985)
- Cite this article
Abstract
Isotopic ages of granitic and metamorphic rocks exposed in the Dunbar structural dome of northeastern Wisconsin identify a protracted series of tectonic and “hydrothermal” events that culminated in major regional uplift during Middle Proterozoic (Keweenawan; ca 1,100 Ma) continental rifting and volcanism. The major rock-forming events and the structural development of the dome occurred during the interval 1,862+/−4 Ma to 1,836+/−6 Ma. Whole-rock Rb-Sr ages are partly reset in response to a widely recognized but cryptic event in Wisconsin and Michigan at about 1,630 Ma. The scale and systematic character of the whole-rock resetting strongly suggests the presence of a fluid phase derived in situ from water dissolved in the silicates or externally from a subthrust plate of low-grade metamorphic rocks. The regional nature of the 1,630-Ma disturbance possibly indicates that it is related to a major tectonic event such as an active plate margin far to the south. Rb-Sr biotite ages for the Dunbar dome (this study), the southern complex of the Marquette district (Van Schmus and Woolsey 1975) and the Felch trough area (Aldrich and others 1965) provide a remarkably coherent pattern that reflects multiple episodes of differential uplift. Younger events superimposed on a regional 1,630-Ma imprint are recorded at 1,330 Ma and 1,140 Ma. The 1,330 Ma disturbance could reflect stabilization following intrusion of the Wolf River batholith at 1,485 Ma. The 1,140-Ma uplift event occurred during Keweenawan rifting and volcanism as a result of stresses imposed on a mosaic of fault-bounded blocks with possible subcrustal influence. The remarkably small variance in the 1,140-Ma biotite age peak argues for rapid uplift and cooling, and hence rapid erosion. Detritus from the uplift probably was being shed into nearby tectonic basins most of which did not survive subsequent uplift and erosion.
This is a preview of subscription content, log in via an institution to check access.
Access this article
Subscribe and save
- Starting from 10 chapters or articles per month
- Access and download chapters and articles from more than 300k books and 2,500 journals
- Cancel anytime
Buy Now
Price excludes VAT (USA)
Tax calculation will be finalised during checkout.
Instant access to the full article PDF.
Similar content being viewed by others
Explore related subjects
Discover the latest articles, books and news in related subjects, suggested using machine learning.References
Afifi Afifa, Doe BR, Sims PK, Delevaux MN (1984) U-Th-Pb isotopic chronology of sulfide ores and rocks in the Early Proterozoic metavolcanic belt of northern Wisconsin. Econ Geol 79:338–353
Aldrich LT, Davis GL, James HL (1965) Ages of minerals from metamorphic and igneous rocks near Iron Mountain, Michigan. J Petrol 6:445–472
Banks PO, Cain JA (1969) Zircon ages of Precambrian granitic rocks, northeastern Wisconsin. J Geol 77:208–220
Banks PO, Rebello DP (1969) Zircon age of a Precambrian rhyolite, northeastern Wisconsin. Geol Soc Am Bull 80:907–910
Claesson S (1980) A Rb-Sr isotope study of granitoids and related mylonites in the Tannas augen gneiss nappe, southern Swedish Caledonide. Geol Foreningens i Stockholm Forhandlingar 102:403–420
Dodson MH (1979) Theory of cooling ages. In: Jager E, Hunziker JC (eds) Lectures in isotope geology. Springer, Berlin Heidelberg New York, pp 194–202
Dott RH (1983) The Proterozoic red quartzite enigma in the north-central U.S.— Resolved by plate collision? Geol Soc Am Mem 160:129–141
Dott RH, Dalziel IWD (1972) Age and correlation of the Precambrian Baraboo Quartzite of Wisconsin. J Geol 80:552–568
Hanson GN, Gast PW (1967) Kinetic studies in contact metamorphic zones. Geochim Cosmochim Acta 31:1119–1153
Hart SR (1964) The petrology and isotopic-mineral age relations of a contact zone in the Front Range, Colorado. J Geol 72:493–525
Hickman MH, Glassley WE (1984) The role of metamorphic fluid transport in the Rb-Sr isotopic resetting of shear zones: evidence from Nordre Stromfjord, West Greenland. Contrib Mineral Petrol 87:265–281
Hoppe WJ, Montgomery CW, Van Schmus WR (1983) Age and significance of Precambrian basement samples from Illinois and adjacent states. J Geophys Res 88:7276–7286
Klasner JS, Osterfeld D (1984) Gravity models of gneiss domes and a granite pluton in northeastern Wisconsin. 30th Inst Lake Superior Geol (abstr):24
Köhler H, Müller-Sohnius D (1980) Rb-Sr systematics on paragneiss series from the Bavarian Moldanubicum, Germany. Contrib Mineral Petrol 71:387–392
Krogh TE (1973) A low-contamination method for hydrothermal decompositions of zircon and extraction of U and Pb for isotopic age determinations. Geochim Cosmochim Acta 37:485–494
Ludwig KR (1979a) A program in Hewlett-Packard BASIC for X-Y plotting and line-fitting of isotopic and other data. US Geol Surv Open-file Rept 79-1641:1–33
Ludwig KR (1979b) A computer program in Hewlett-Packard BASIC for plotting and processing U-Pb isotope data on “Concordia” diagrams. US Geol Surv Open-file Rept 79-1692:1–32
Morey GB, Sims PK (1976) Boundary between two Precambrian W terranes in Minnesota and its geologic significance. Geol Soc Am Bull 87:141–152
Morey GB, Sims PK, Cannon WF, Mudrey MG Jr, Southwick DL (1982) Geologic map of the Lake Superior region, Minnesota, Wisconsin, and Northern Michigan. Minn Geol Surv State Map Ser S-13
Naeser CW (1979) Thermal history of sedimentary basins: fissiontrack dating of subsurface rocks. SEPM Spec Pub 26:109–112
Peterman ZE (1979) Strontium isotope geochemistry of Late Archean to Late Cretaceous tonalites and trondhjemites. In: Barker F (ed) Developments in petrology: Dacites, trondhjemites, and related rocks. Eisevier Sci Pub, pp 133–147
Peterman ZE, Sims PK (1984) Middle Proterozoic events in northeast Wisconsin and adjacent Michigan as defined by Rb-Sr biotite ages. 30th Inst Lake Superior Geol (abstract): 50–52
Peterman ZE, Zartman RE, Sims PK (1980) Tonalitic gneiss of early Archean age from northern Michigan. Geol Soc Am Spec Pap 182:125–134
Peterman ZE, Zartman RE, Sims PK (1985) A protracted Archean history in the Watersmeet gneiss dome northern Michigan. US Geol Surv Bull 1655 (in press)
Roddick JC, Compston W (1977) Strontium isotope equilibration: a solution to a paradox. Earth Planet Sci Lett 34:238–246
Schulz KJ, Sims PK, Peterman ZE (1984) Geochemistry of the Dunbar gneiss-granitoid dome, northeastern Wisconsin. In: Guide to the geology of Early Proterozoic rocks in northeastern Wisconsin. 30th Inst Lake Superior Geol:24–42
Silver LT, Green JC (1972) Time constants for Keweenawan igneous activity. Geol Soc Am Abs with Progs 4:665–666
Sims PK (1976) Precambrian tectonics and mineral deposits, Lake Superior region. Econ Geol 71:1092–1118
Sims PK, Peterman ZE (1980) Geology and Rb-Sr ages of middle Precambrian granitic rocks, northern Wisconsin. Geol Soc Am Spec Pap 182:139–146
Sims PK, Card KD, Morey GB, Peterman ZE (1980) The Great Lakes tectonic zone — a major crustal structure in central North America. Geol Soc Am Bull 91:690–698
Sims PK, Peterman ZE, Schulz KJ (1984) Dunbar gneiss-granitoid dome. In: Guide to the geology of Early Proterozoic rocks in northeastern Wisconsin. 30th Inst Lake Superior Geol 1–23
Sims PK, Peterman ZE, Schulz KJ (1985a) Dunbar gneiss-granitoid dome: Implications for Proterozoic tectonic evolution of northern Wisconsin. Geol Soc Am Bull (in press)
Sims PK, Peterman ZE, Zartman RE, Benedict FC (1985b) Geology and geochronology of granitoid and metamorphic rocks of Late Archean age in northwestern Wisconsin. US Geol Surv Prof Pap 1292-C:C1-C17
Smalley PC, Field D, Raheim A (1983) Resetting of Rb-Sr wholerock isochrons during Sveconorwegian low-grade events in the Gjerstad augen gneiss. Telemark, southern Norway. Isotope Geosci 1:269–282
Smith EI (1983) Geochemistry and evolution of early Proterozoic, post-Penokean rhyolites, granites, and related rocks of south-central Wisconsin, USA. Geol Soc Am Mem 160:113–128
Spear FS, Selverstone J (1983) Water exsolution from quartz: Implications for the generation of retrograde metamorphic fluids. Geology 11:82–85
Steiger RH, Jäger E (1977) Subcommission on geochronology, convention on the use of decay constants in geo- and cosmochronology. Earth Planet Sci Lett 36:359–362
Studemeister PA (1984) The redox state of iron: a powerful indicator of hydrothermal alteration. Geosci Can 10:189–194
Van Schmus WR (1978) Geochronology of the southern Wisconsin rhyolites and granites. Geosci Wisc 2:19–24
Van Schmus WR (1980) Chronology of igneous rocks associated with the Penokean orogeny in Wisconsin. Geol Soc Am Spec Pap 182:159–168
Van Schmus WR, Bickford ME (1981) Chapter 11. Proterozoic chronology and evolution of the midcontinent region, North America. In: Kroner A (ed) Precambrian plate tectonics. Elsevier Sci Pub: 261–296
Van Schmus WR, Woolsey LL (1975) Rb-Sr geochronology of the Republic area, Marquette County, Michigan. Can J Earth Sci 12:1723–1733
Van Schmus WR, Green JC, Halls HC (1982) Geochronology of Keweenawan rocks of the Lake Superior region: A summary. Geol Soc Am Spec Pap 156:165–171
Van Schmus WR, Thurman EM, Peterman ZE (1975a) Geology and Rb-Sr chronology of middle Precambrian rocks in eastern and central Wisconsin. Geol Soc Am Bull 86:1255–1265
Van Schmus WR, Medaris LG, Banks PO (1975b) Geology and age of the Wolf River batholith, Wisconsin. Geol Soc Am Bull 86:907–914
Wiggins LB, Brett R (1977) Pelican River Cu-Zn deposit, Wisconsin: Metamorphic conditions in Penokean time. Geol Soc Am Abs With Progs 9:1226–1227
Winnett TL (1981) Middle Precambrian (Precambrian X) thermal history of northern Michigan. Unpublished MS Thesis, Ohio State University p 106
Zartman RE, Stern TW (1967) Isotopic age and geologic relationships of the Little Elk Granite, north Black Hills, South Dakota. US Geol Surv Prof Pap 575D:D157-D163
Zen E, Hammarstrom JM (1984) Magmatic epidote and its significance. Geology 12:515–518
Rights and permissions
About this article
Cite this article
Peterman, Z.E., Sims, P.K., Zartman, R.E. et al. Middle Proterozoic uplift events in the Dunbar dome of northeastern Wisconsin, USA. Contr. Mineral. and Petrol. 91, 138–150 (1985). https://doi.org/10.1007/BF00377761
Received:
Accepted:
Issue date:
DOI: https://doi.org/10.1007/BF00377761
Share this article
Anyone you share the following link with will be able to read this content:
Sorry, a shareable link is not currently available for this article.
Provided by the Springer Nature SharedIt content-sharing initiative