PALEOMAGNETISM AND ROCK MAGNETISM OF CARBONATE ROCKS FROM THE HELENA SALIENT, SOUTHWEST MONTANA

1. PALEOMAGNETISM AND ROCK MAGNETISM OF CARBONATE ROCKS FROM THE HELENA SALIENT, SOUTHWEST MONTANA Ben Baugh

2. Introduction • North American cordilleran fold and thrust belt • Helena salient • Wyoming salient • Vertical-axis rotation: paleomagnetism • (Grubbs and Van der Voo, 1976; Eldredge and Van der Voo, 1988; Jolly and Sheriff, 1992) • * Sampling Mississippian carbonates, this study aims to investigate curvature of the Helena salient (Harlan et al., 2008) (Weil and Sussman, 2004)

3. Geology of Western Montana • Fold and thrust belt propagation • 72 -56 Ma (Hoffman et al., 1976) • Pre-folding diorite sills • 77 Ma (Harlan et al. , 2008) • Montana transverse zone • Lewis and Clark shear zone • Boulder Batholith • 78-68 Ma (Tilling et al., 1968) • Helena Embayment • Pre-cambrian reentrant • (Harrison et al., 1974) (Harlan et al., 2008) (Eldredge and Van der Voo, 1988)

4. Objectives 1.) Are carbonates of the Helena salient remagnetized? 2.) Quantify vertical-axis rotation, if any Establish age of magnetization Use reference direction to quantify vertical-axis rotation 10 µm (McCabe and Elmore, 1989) (Weil and Sussman, 2004)

5. Field Area Eldredge and Van der Voo (1988)

7. Sampling • Paleozoic carbonates • Madison Group carbonates • (20 sites) • Mission Canyon Limestone • Lodgepole Limestone • Cambrian Meagher limestone • (1 site) • Devonian Jefferson carbonates • (3 sites)

8. Mission Canyon (Mississippian) LodgepoleLs Meagher Ls (Cambrian) 9 sites – Madison Group 1 site – Meagher Ls

9. Mission Canyon (Mississippian) LodgepoleLs Jefferson Fm (Devonian) Pilgrim Fm (Cambrian) 5 sites – Madison Group 3 sites – Jefferson Fm

10. Mission Canyon (Mississippian) LodgepoleLs 6 sites – Madison Group

11. Methods: • Thermal Demagnetization (°C): • 144 specimens • NRM, 100, 200, 275, 350, 400, 440, 480, 520 • Magnetic Hysteresis • Ms, Mrs, Hc and Hcr • Aids in Characterizing magnetic grain size • Magnetic Susceptibility • Degree of magnetization induces by applied magnetic field

12. Directional data analysis: Fold Test • Determines age of magnetization relative to folding • Pre-tilting • Post-tilting • Syn-tilting • McElhinny (1964) • Incremental fold test • Applied to all folds • Tauxe and Watson (1994) • Treats directions as Eigen vectors • Applied to Turner anticline (Weil and Sussman, 2004)

13. Results: • Demagnetization • Stable, but weak magnetizations • 16/23 sites resulted in enough samples to generate site means • Devil’s Fence: 6/9 • Three Forks: 6/8 • Turner: 4/6

14. Results: • Devil’s Fence and Turner anticlines reveal two apparent components of magnetization: • Lower hemisphere component, steep inclinations • Upper hemisphere component, shallow inclination Devil’s Fence

15. Fold Tests: Devils Fence anticline • Two apparent components • Lower hemisphere component passes the fold test at 90-100% untilting • Pre-tilting • Grand mean direction: • D = 35°, I = 72°, α95 = 8°

16. Fold Tests: Three Forks anticline • One apparent magnetization component • Two sites reversed • Sites 22 and 24 • Site 23 split into two components • passes the fold test at 100% untilting • Pre-tilting • Grand mean direction: • D = 37°, I = 70°, α95 = 23°

17. Fold Tests: Turner anticline • Two apparent magnetization components • Lower hemisphere component passes the fold test at 100% untilting • Pre-tilting interpretation • Grand mean direction: • D = 224°, I = 69°, α95 = 29°

18. Age of Magnetization: • Fold tests: pre-deformational • Upper limit 77 Ma (Harlan et al., 2008) • Steep, lower hemisphere component • K-group: Late Cretaceous remagnetization • Shallow, upper hemisphere component • M-group: Mississippian primary detrital magnetization

19. Expected directions: • Calculated using paleopole location, and location of study area • Angular distance: • p = cos­-1 [(sinpsins + cospcoss cos(Øp-Øs)] • Declination • Dx= cos­-1 (sinp - sins cosp/ cosssinp) • Inclination • Ix = tan-1(2cot p) Mississippian Late Cretaceous Paleopoles from McFadden and McElhinny (1995)

20. Vertical-axis rotations: K-group • Devil’s Fence: • 59° ± 25 clockwise • Three Forks: • 62° ± >60° clockwise • Turner: • 111° ± >60° counter-clockwise

21. Vertical-axis rotations: M-group • Restoration of K-group to Cretaceous expected direction • 22 ± 18° - 59 ± 14° clockwise rotation • Timing difficult to constrain K-group K-group

22. Combined with Eldredge and Van der Voo (1988) Results: • Clockwise rotation along southern margin • Counter-clockwise rotation along northern margin • Clockwise rotation within the Elkhorn plate

23. Camparison with previous studies outside the Helena salient • Wolf Creek, MT • Late Cretaceous Two Medicine Formation • (Jolly and Sheriff, 1992) • Transverse Zone • Late Cretaceous Diorite sills • (Harlan et al., 2008) • Sawtooth Range • Mississippian Madison Group • (O’Brien et al., 2007)

24. Hysteresis Results • Wide Hcr/Hc range, Narrow Mrs/Ms range • M-group and K-group Plot along SP+PSD, and SP+SD mixing lines • Consistent with remagnetized limestones (Suk et al., 1993; Xu et al., 1998; Channell and McCabe, 1994)

25. Bulk Magnetic Susceptibility • Decreasing Trend • West-to-east • Remagnetization event affected rocks more intensely towards the foreland? • M-group most negatively susceptible • Least amount of ferromagnetic material

26. Conclusions • Remagnetization • Remagnetized prior to deformation Late Jurassic- Late Cretaceous • Some areas retain primary Mississippian magnetizations • No remagnetization trends observed

27. Conclusions • Vertical-axis rotation • Clockwise along southern margin • Counter-clockwise along northern margin • Clockwise rotation within the Elkhorn plate • Primary component may reveal a pre-remagnetization rotation • Rotation minimal beyond transverse zones

28. Acknowledgements • Advisor: Bernie Housen • Committee: Liz Schermer and Chris Suzcek • Russ Burmester • Field assistant: Steve Shaw • Fellow graduate students • Funding: • GDL Foundation • Graduate School RSP grant • Geology Department

29. Questions?

31. Remagnetized carbonates in Canadian Rockies • Enkin et al. (2000) • Cambrian-Jurassic carbonates • Cretaceous age chemical remanent magnetization (CRM) • Front range: normal polarity • Foothills: Reverse polarity • Proposed mechanism for such a trend: ~100 Km (Enkin et al., 2000)

32. Remagnetized sedimentary rocks in Appalachia • Early Paleozoic sedimentary rocks • Widespread Pennsylvanian-Permian remagnetization • Hinterland: Post-folding • Foreland: Pre-folding • Central belt: Syn-folding • Fluids migrated faster than fold and thrust belt propagation during a unique geochemical setting (Stamatakos et al., 1996) HINTERLAND FORELAND Post-tilting Syn-tilting Pre-tilting

33. Remagnetized carbonates in the Sawtooth Range • O’brien et al. (2007) • Madison Formation • Castle Reef dolomite • Allan Mountain limestone • Late Jurassic – Early Tertiary remagnetization (CRM) • Pre-tilting • Two folds syn-tilting • Chemical and Petrographic analysis • Elevated 87Sr/86Sr values • Externally derived fluids • Hydrocarbon migration • No remagnetization trends • All reverse polarity • Vertical-axis rotation not evaluated

34. Methods: Magnetic Hysteresis • Plotting Mrs/MsvsHcr/Hchelps characterize grain size of ferrimagnetic material • Primary magnetizations • Single-domain + multi-domain (SD-MD) mixing line • Remagnetized carbonates • Single domain + superparamagnetic (SD-SP) mixing line (Dunlop, 2002)

35. Directional data analysis: Getting a site mean Direction on stereoplot Multiple samples from site plotted Generate site mean Interpret ChRM • Fold test criteria: • Devil’s Fence and Turner anticlines: α95 < 20° • Three Forks: α95 < 25° • Minimum of four samples per site (n≥4) • Two sites (Sites 16 and 23) split into a group of three and a group of two • Grand-mean direction: Mean generated for a cluster of site-means