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Home > Explore! > Bedrock Geology > Field Localities > Red Beach Granite

Red Beach Granite

The town of Red Beach, Maine, south of Calais on Route 1, is named for the striking natural brick-red color of its stones. The body of underlying red bedrock, named the Red Beach Granite, is several miles across. Two sites on the shore of the St. Croix River offer convenient public access to the Red Beach Granite.

Saint Croix Island International Historic Site entrance sign

Site 1: Saint Croix Island International Historic Site

The first French settlement in North America was on St. Croix Island in 1604. This historical site is commemorated on the mainland with displays on both sides of the border. At the U.S. facility on Route 1 in Red Beach, eight miles south of Calais, the National Park Service has made significant improvements (Figure 1) recently as part of the 400th anniversary celebration in 2004.

sculpture
Figure 1		 boulders on Red Beach
Figure 2

Below the new displays, along the shore beside the boat launch, there is a bedrock outcrop and many blocks and stones of Red Beach Granite (Figure 2). Some of these blocks were left from quarrying operations in the late 1800's and early 1900's when Maine granite was used for buildings and monuments up and down the eastern seaboard. Among the buildings which incorporate Red Beach Granite is the American Museum of Natural History in New York.

close-up of Red Beach granite
Figure 3		 Some of the blocks remaining here have clean surfaces where the texture of the granite (Figure 3) can be seen. Close examination shows that, as for all true granites, three predominant minerals make up the rock. Quartz is light gray and translucent. One type of feldspar (plagioclase) is milky white. The other type of feldspar (alkali feldspar) is orangey-red. It is the red feldspar that gives the rock its distinctive color. In addition there are very tiny flecks of black mica, found mostly with quartz, that comprise a few percent of the rock.

Granite is an igneous rock that forms by slow cooling and solidification from molten rock (magma). The magma is produced by melting at depth and intrudes into the overlying rocks without breaking the surface. As it solidifies underground, the various mineral grains grow from the melt to produce the interlocking mosaic of grains we see in the rock today. Since granite must form underground, the fact that we see it at the surface today means that through geologic time a significant amount of overlying rock has been removed by erosion.


Robbinston rest area signpost Robbinston boat launch

Site 2: Rest Area and Boat Launch, Robbinston

About 3½ miles south of Site 1 there is a scenic roadside rest area and boat launch in Robbinston. Visitors may walk to the shore to see stony red beaches (Figure 4) and bedrock outcrops (Figure 5) of Red Beach Granite. A close look (Figure 6) shows that the rock here is slightly different from the rock at Site 1. It is still made up of the same three essential minerals: quartz, white feldspar, and red feldspar, but the individual grains are much smaller than in the rock at Site 1. Furthermore, the tiny black minerals here are needle-shaped hornblende rather than flakes of black mica as at Site 1. On the basis of such details, the Red Beach Granite has been subdivided into six different bodies that formed by successive magma intrusions over a short span of time (Abbott, 1986).

red beach at Robbinston boat launch
Figure 4		 outcrop of Red Beach granite
Figure 5		 close-up of fine-grained granite
Figure 6

The reason that the rock here has a finer grain size than the rock at Site 1 is that here the magma solidified more rapidly. This means that the enclosing rock must have been cooler, and was probably closer to the earth's surface when it formed. The tiny holes in the rock at Site 2 (called miarolitic cavities) are where gas bubbles exsolved from the magma as it was solidifying. Only at relatively low pressures, as the magma rises near the earth's surface, can gas bubbles be released, in much the same way that carbonation is released by taking the cap off a soda bottle.

Thin, red dikes (Figure 7) cut through the granite. These dikes are even finer-grained than the granite (Figure 8), with grains too small to see without magnification. Their microscopic grain size is similar to that of volcanic rocks and requires very rapid cooling. Such dikes are thought to represent the remnant portion of magma remaining after the granite had mostly solidified. This last bit of magma was injected into a thin crack and cooled instantaneously to a very fine-grained rock.

wide view of red dike
Figure 7		 close-up of red dike
Figure 8		 breccia zone
Figure 9

Thin zones of broken rock (Figure 9) (called breccia) are old fault zones that probably formed as the granite was cooling. These zones do not accommodate much sideways movement, and do not extend very far through the rock.

Importance of the Red Beach Granite

Perry conglomerate
Figure 10		 The Red Beach Granite holds a special place in the geology of eastern Maine because of its relationships to surrounding rocks. It intrudes into deformed sedimentary and volcanic rocks of the Eastport Formation, so it must be younger than the Eastport Formation. The Red Beach Granite is overlain, in turn, by sandstone and conglomerate of the Perry Formation (Figure 10), which contains cobbles that were eroded from the Red Beach Granite. This relationship demonstrates that the granite must have intruded, cooled, been uplifted, and eroded before the Perry Formation was deposited.

The sequence of events including eruption of volcanic rocks, deformation of the earth's crust, and intrusion of Red Beach Granite is a part of the formative process of the Appalachians called the Acadian orogeny. The subsequent, relatively quiet time of erosion and accumulation of the Perry Formation marks the end of this mountain-building episode. Therefore, the Red Beach Granite dates the climax of the Acadian orogeny in eastern Maine. Fossils indicate that the Eastport Formation formed near the beginning of the Devonian Period and the Perry Formation formed near the end of the Devonian Period. So the Middle Devonian age implied for the Red Beach Granite is generally taken as the age of the Acadian orogeny in eastern Maine. Recent calibrations measuring the decay of natural radioactive elements (Tucker and others, 1998) date the Devonian time period to span 362 to 418 million years ago.

Ice Age Features

glacial striations
Figure 11		 The rocks at Site 2, especially the outcrops near the boat launch, have grooves and scratches (Figure 11) on their top surfaces that were caused by movement of glacier ice during the last Ice Age, about 14,000 years ago. Stones that were frozen in the base of the continental ice sheet were dragged across the bedrock, causing the surface marks. The alignment of these marks is parallel to the direction the glacier was moving, in this case an east-southeasterly direction with a compass bearing of about 120°.

References Cited

Abbott, R. N., Jr., 1986, Preliminary report on the bedrock geology of the Red Beach, Robbinston, and Devils Head 7.5-minute quadrangles, Maine: Maine Geological Survey, Open-File No. 86-73, map scale 1:24,000, 36 p. report.

Tucker, R. D., Bradley, D. C., Ver Straeten, C. A., Harris, A. G., Ebert, J. R., and McCutcheon, S. R., 1998, New U-Pb zircon ages and the duration and division of Devonian time: Earth and Planetary Science Letters, v. 158, p. 175-186.

Web text and photos by Henry N. Berry IV

Originally published on the web as the October 2003 Site of the Month.

Last updated on October 6, 2005