Living on the Fault Line
The
couple checked with Burns’s parents, who live in nearby Basking Ridge,
and they, too, had heard and felt something, which they thought might
have been an earthquake. A call by Burns some 20 minutes later to the
Bernardsville Police Department—one of many curious and occasionally
panicky inquiries that Sunday morning, according to the officer in
charge, Sergeant John Remian—confirmed their suspicion: A magnitude 2.6
earthquake, its epicenter in Peapack/Gladstone, about seven miles from
Bernardsville, had hit the area. A smaller aftershock followed about two
and a half hours later.
After
this year’s epic earthquakes in Haiti, Chile, Mexico, Indonesia, and
China, the 2.6 quake and aftershock that shook parts of New Jersey in
February may seem minor league, even to the Somerset County residents
who experienced them. On the exponential Richter Scale, a magnitude 7.0
quake like the one that hit Haiti in January is almost 4 million times
stronger than a quake of 2.6 magnitude. But comparisons of magnitude
don’t tell the whole story.
Northern
New Jersey straddles the Ramapo Fault, a significant ancient crack in
the earth’s crust. The longest fault in the Northeast, it begins in
Pennsylvania and moves into New Jersey, trending northeast through
Hunterdon, Somerset, Morris, Passaic, and Bergen counties before
terminating in New York’s Westchester County, not far from the Indian
Point Energy Center, a nuclear power plant. And though scientists
dispute how active this roughly 200 million-year-old fault really is,
many earthquakes in the state’s surprisingly varied seismic history are
believed to have occurred on or near it. The fault line is visible at
ground level and likely extends as deep as nine miles below the surface.
During the past 230 years or so, New Jersey has been at the epicenter of nearly 170 earthquakes,
according to data compiled by the New Jersey Geological Survey, part of
the United States Department of Environmental Protection. The
largest known quake struck in 1783, somewhere west of New York City,
perhaps in Sussex County. It’s typically listed as 5.3 in magnitude, though
that’s an estimate by seismologists who are quick to point out that the
concept of magnitude—measuring the relative size of an earthquake—was
not introduced until 1935 by Charles Richter and Beno Gutenberg. Still,
for quakes prior to that, scientists are not just guessing.
“We
can figure out the damage at the time by going back to old records and
newspaper accounts,” says Won-Young Kim, a senior research scientist at
Columbia University’s Lamont-Doherty Earth Observatory in Palisades, New
York, directly across the New Jersey border. “Once the amount and
extent of contemporary damage has been established,” Kim says, “we’re
then able to gauge the pattern of ground shaking or intensity of the
event—and from there extrapolate its probable magnitude.”
Other earthquakes of magnitude 5 or higher have been felt in New Jersey, although their epicenters laying near New York City. One—which
took place in 1737 and was said to have been felt as far north as
Boston and as far south as northern Delaware—was probably in the 5 to
5.5 range. In 1884, an earthquake of similar magnitude occurred off New
York’s Rockaway Beach. This well-documented event pulled houses off
their foundations and caused steeples to topple as far west as Rahway.
The shock wave, scientists believe, was felt over 70,000 square miles,
from Vermont to Maryland.
Among
the largest sub-5 magnitude earthquakes with epicenters in New Jersey,
two (a 3.8 and a 4.0) took place on the same day in 1938 in the
Lakehurst area in Ocean County. On August 26, 2003, a 3.5 magnitude
quake shook the Frenchtown/Milford area in Hunterdon County. On February
3 of last year, a 3.0 magnitude quake occurred in the Morris County
town of Mendham. “A lot of people felt this one because of the intense
shaking, although the area of intensity wasn’t very wide,” says
Lamont-Doherty’s Kim, who visited the site after the event.
After
examining the known historical and geological record, Kim and other
seismologists have found no clear evidence that an earthquake of greater
than 5.3 to 5.5 magnitude has taken place in this area going back to
1737. This doesn’t mean, of course, that one did not take place in the
more remote past or that one will not occur in the future; it simply
means that a very large quake is less likely to occur here than in other
places in the east where the seismic hazard is greater, including areas
in South Carolina and northeastern New York State.
Given
this low-hazard, high-vulnerability scenario, how far along are
scientists in their efforts to predict larger magnitude earthquakes in
the New Jersey area? The answer is complex, complicated by the state’s
geographical position, its unique geological history, the state of
seismology itself, and the continuing debate over the exact nature and
activity of the Ramapo Fault.
Over
millions of years, New Jersey developed four distinct physiographic
provinces or regions, which divide the state into a series of diagonal
slices, each with its own terrain, rock type, and geological landforms.
The
northernmost slice is the Valley and Ridge, comprising major portions
of Sussex and Warren counties. The southernmost slice is the Coastal
Plain, a huge expanse that covers some three-fifths of the state,
including all of the Shore counties. Dividing the rest of the state are
the Highlands, an area for the most part of solid but brittle rock right
below the Valley and Ridge, and the lower lands of the Piedmont, which
occupy all of Essex, Hudson, and Union counties, most of Bergen,
Hunterdon, and Somerset, and parts of Middlesex, Morris, and Passaic.
For
earthquake monitors and scientists, the formation of these last two
provinces—the Highlands and the Piedmont—are of special interest. To
understand why, consider that prior to the appearance of the Atlantic
Ocean, today’s Africa was snuggled cozily up against North America and
surrounded by a single enormous ocean. “At that point, you could have
had exits off the New Jersey Turnpike for Morocco,” says Alexander
Gates, professor of geology and chair of the department of Earth and
Environmental Sciences at Rutgers-Newark.
Under
the pressure of circulating material within the Earth’s super-hot
middle layer, or mantle, what was once a single continent—one that is
thought to have included today’s other continents as well—began to
stretch and eventually break, producing numerous cracks or faults and
ultimately separating to form what became the Atlantic Ocean. In our
area, the longest and most active of these many cracks was the Ramapo
Fault, which, through a process known as normal faulting, caused one
side of the earth’s crust to slip lower—the Piedmont—relative to the
other side—the Highlands. “All this occurred about 225 million years
ago,” says Gates. “Back then, you were talking about thousands of feet
between the Highlands and the Piedmont and a very active Ramapo Fault.”
The
Earth’s crust, which is 20 to 25 miles thick, is not a single, solid
shell, but is broken into seven vast tectonic plates, which drift atop
the soft, underlying mantle. Although the northeast-trending Ramapo
Fault neatly divides two of New Jersey’s four physiographic provinces,
it does not form a so-called plate boundary, as does California’s
infamous San Andreas Fault. As many Californians know all too well, this
giant fault forms the boundary between two plates—to the west, the
Pacific Plate, and to the east, the North American Plate; these rub up
against each other, producing huge stresses and a regularly repeating
pattern of larger earthquakes.
This
second bit of uncertainty is especially troubling for some people,
including some in the media who want a neat story. To get around it,
they ignore the differences between plate settings and link all of New
Jersey’s earthquakes, either directly or implicitly, to the Ramapo
Fault. In effect, such people want the Ramapo Fault “to look like the
San Andreas Fault,” says Gates. “They want to be able to point to one
big fault that’s causing all of our earthquakes.”
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