Kean University Geology 4265 Field Trip 3, Prof. Smart Geology of Wissahickon Creek Afternoon: Bell's Mill Road Area Afternoon In the afternoon we will map the area around Bells Mill road, and get a first-hand look at the accretion of Avalonia and its forearc sediments to the Grenville Age Coast, forming the Taconic Orogeny. Park at the parking lot east of Wissahickon Creek. You will take at least one marked, fist-size or greater rock sample, strike and dip if possible, a GPS reading, an outcrop photo, and a rock close-up photo, for every useful (not floating) outcrop. BEFORE YOU LEAVE THE PARKING LOT, BE SURE YOU HAVE A PENCIL, NOTEBOOK, AND THESE PAGES. ALSO BE CERTAIN THAT THERE IS A CLEAR PROTRACTOR AVAILABLE FOR YOUR USE. Lunch discussion: Here is a figure from your Introduction to Geology Textbook, Chernicoff et. al. Let’s review the Taconic Orogeny. Rodinia breaking up Avalonia Terrane E. Cambrian Plates reverse, in E. Ordovician Laurentia moves toward Avalonia Africa moves toward both Mid – L. Ordovician, Avalonia and island arc dock with Laurentia, beginning the new Appalachians Lunch discussion continued: Tectonic Setting. More pictures from Chernicoff et al. Earth So far we have seen rocks we expect from a forearc basin ophiolites, i.e. metamorphosed sediments (Wissahickon), plus basaltic rocks (the Amphibolites we saw this morning), and peridotites. The India and Asia collision is an instructive starting analogy. 1 2 3 4 Rocks thrust up over margin of Laurentia CHECK your Brunton deviation. Prof. Smart will instruct you. Start collecting data. EAST SIDE OF STREAM Walk south, carefully crossing Bell's Mill Road, and walk on the path to the first outcrop of rock on your left (not right on Bell's Mill Road, your instructor will show you). Stop 1. Wissahickon Formation: schist and quartzite. This originated as Flysch: alternating mud and sands, formed as turbidites and tempestites in the ocean between prior to the Taconic collision 400 to 450 mya. These lithified to interbedded layers of shale and sandstone. The sands are often graded, allowing right-side-up determinations. As Avalonia collided with North America along the eastern edge of the Grenville highlands, the forearc sediments of the Wissahickon were compressed, folded and heated, causing both structural and chemical changes. Take a strike and dip of the general orientation of the quartzites. You will have to average over the folds. Also obtain the latitude and longitude with the GPS. Plot everything on your topo map, using landmarks. As always, collect a marked sample. STOP 2 is across Bell's Mill Road, back at the parking lot. It is the first outcrop on the right. These are serpentine phyllites containing talc. NOTE THE "FEEL". Chemically the rocks here are like lower ocean lithosphere, i.e. the upper mantle. These peridotites, possibly from the base of an ophiolite suite, have been metamorphosed by hot circulating ocean water. Take a strike and dip for the phyllite, and find the limits of the layer on this side of the stream. Take GPS readings for the limits of the serpentinites. Plot the surface contacts with the serpentinite. Mapping Suggestions: USE PENCIL and a protractor. Once we have strikes and dips, show contacts between layers as a line on your topo worksheet. Use land marks on the topo cutout below to place your strike and dip symbols and a formation symbol your instructor will provide. For Stop 1, use the formation symbol Czw for Wissahickon Schist and Quartzite. For Stop 2, a Serpentine Phyllite, use Pzum. CONTACTS: Usually we are not certain where a contact is because the contact is not exposed. We can make a good guess based on where we do see rocks and by using changes in topography that reflect the differing ability of the rocks to withstand weathering. With the scale of the topo worksheet given, the width of a pencil line is close to our uncertainty. We can also infer the orientation of the contact from the strike for sedimentary and non-foliated metamorphic rock. This usually doesn't work for igneous rocks. STOP 3. If we continue north, we begin to see Wissahickon quartzite and schist again. We have walked over another contact that we can put on our map. Get the strike and dip and a GPS position, and mark a line along strike for the contact at some point between outcrops that you choose. Stop 4. Further along the stream a dike of granodiorite cuts into the Wissahickon Formation. Trace the strike of this as it crosses the stream. We will see it again on the other side of Wissahickon. A close-up of the granodiorite Stop 5. Past the Granodiorite are additional small outcrops of Wissahickon Formation. Take GPS coordinates and note their position on your topo using landmarks. Collect strikes and dips, and marked rock samples. Use the symbol Ssg. Stop 6. Next continue up toward the strong right bend in the stream. Note the shattered rock on the floor of the path. This should alert you to the possibility of a fault. Remember the shattered rock you saw on either side of the small fault in the Allentown Dolomite on trip two. This fracture zone is much larger. This is the Rosemont Fault, the suture zone between the lower Paleozoic Wissahickon Group, and the Grenville Craton of the Laurentian continent just to the north. Take GPS coordinates. Also note your position on your topo map. Follow the trail around the bend and turn left to cross the bridge over Wissahickon Creek. Note Chestnut Hill College on your right. Turn left into the park: take the small path along the north stream bank to the bridle path "Forbidden Drive" ahead. Turn left on the bridle path and walk to the first quarry on your right. WEST SIDE OF STREAM STOP 7. Baltimore Gneiss. This rock is part of the Grenville Craton we saw on the second field trip. Get the strike of the southern margin and a GPS position of the exposed southern extent near the bridal path. Look for additional outcrops near the stream bank to initially orient the suture. Note the limits on your topo using landmarks. We are north of the suture zone separating the Wissahickon Formation from the Baltimore Gneiss, the Rosemont Fault. To further orient the fault, we could find the location of the separation between the Wissahickon and Baltimore Formations along the Schuylkill River to the west of here; the line for this fault strikes about S75W. Start at the lat and lon of the southernmost extent of Baltimore Gneiss on this side, and draw a line to show the southern boundary of the Baltimore Gneiss. Discussion. Finish Mapping as a team: Okay, now you are on your own. You should be able to re-find the rocks you saw earlier on this side of the stream. For each rock bed you find, take GPS readings, a strike and dip, and a rock sample carefully labeled. You can see some ridges of rock crossing the stream; these will help you with the strike. Work your way back to the road. Do not cross the road, wait there for your instructor. Don't be shy about strikes and dips for the Wissahickon Formation, the quartzites will work fine. Plot all contacts, formation symbols, and strikes and dips on your topo. Then draw a cross section.