Download Geology of the New Jersey Highlands and Valley and Ridge Provinces

Geology of the New Jersey
Highlands and Valley and
Ridge Provinces
Rich Volkert
New Jersey Geological Survey
Rock cycle
Present distribution of tectonic plates
Eurasian
plate
Arabian
plate
African
plate
Indian
plate
Part I
Geology of the
New Jersey Highlands
Highlands Physiographic
Province
ƒ Area of scenic and rugged terrain
encompassing 1,000 square miles
ƒ Mountainous uplands of northeasttrending ridges underlain by rocks
resistant to erosion
ƒ Broad, flat valleys (e.g., Pequest, Long,
Musconetcong, Vernon) underlain
by less resistant Proterozoic rocks
and/or younger shale and limestone
Wawayanda Mt.
1,496 ft.
¿
a
Franklin
Boonton
t
M
Chester
Washington
Pi e
dm
on t
p
m
u
J
y
n
n
Je
d
n
a
y
ll e dge
a
V Ri
Age of rocks in
the Highlands
(million years ago)
Distribution of Proterozoic rocks
in eastern North America
~960
~1300
*
Highlands (continued)
„
„
„
Most ancient part of State
„ Remnant of mountain belt
formed from colliding
tectonic plates (proto
North and South America)
Metamorphic Rocks
„ Characterized by parallel
alignment of minerals
(foliation)
„ High temperature/pressure
(1300o -1400o F, 5,000
atm, buried ~15-20 mi).
Rocks soft, easily folded
Exposed at the surface due to
uplift and the erosion of
overlying rocks
NJ Highlands
Zone of metamorphism
Geologic Map of the Highlands
ƒ Distribution of Proterozoic rocks
ƒ More than 30 different Proterozoic
rock units recognized (mainly
granites, gneisses, marble)
ƒ Complex folding and faulting
Area shown
Rock types of the Highlands
Granite
„
Widespread, common igneous rock crystallized from magma
„ underlies 50% of Highlands
„ medium to coarse grained, massive textured
„ Composed mainly of minerals quartz and feldspar
Byram granite
Lake Hopatcong granite
Mount Eve granite
Pompton Pink Granite
Smithsonian NMNH
Riverdale quarry
1 in.
-----
St Pauls, Paterson
Gneiss
„
Widespread, common metamorphic rock
„ Underlies 45% of Highlands
„ Formed from metamorphism of igneous or sedimentary rocks
Igneous gneiss
Sedimentary gneiss
Underlies 5% of Highlands
Metamorphosed marine limestone
Marble
Composed of calcium carbonate
Host rock for zinc deposits
Quarried for cement, fertilizer, ornamental stone
Limecrest quarry, Sparta
Faults
Compression
„
„
„
„
„
Fractures along which rocks have
broken and been offset
Faults form from compressional or
extensional forces, or both
May have high- or low-temperature
deformation features
Occur at all scales - variable
lengths and widths
Important conduits for water and
contaminant movement
Extension
Distribution of faults in the Highlands
New York
¿
a
Valley and
Ridge
Piedmont
Oakland
s
d
n
a
l
h
g
i
H
Morristown
Bernardsville
Boonton
po
a
m
a
R
lt
u
fa
t
n
o
m
d
e
i
P
¿
a
Low-temperature (brittle) faults
-----20 ft.
High-temperature (ductile) faults
Joints
ƒ
ƒ
ƒ
ƒ
Fractures along which there has been no movement
Mainly due to extensional forces; pressure release during uplift
Variably spaced from inches to several feet
Important conduits for water and contaminant movement
Folds
„
„
„
Bends in rock from compressional forces 1 billion years ago
Wide range in size (inches to thousands of feet)
Arched upward = anticline; arched downward = syncline
1ft.
--------
1 in.
----
Economic Geology of the Highlands
Iron ore
Zinc ore
Graphite ore
Radioactive ore
Mica deposits
Serpentine deposits
Crushed stone
- Deposits are >1billion years old
- Metamorphosed at high temperature
- Complexly folded and faulted
- More than 400 mines. Mostly underground, some surface
workings. Depths range from –10’s of ft. to -2,900 ft.
Iron ore (magnetite) 1710-1966
Zinc deposits (1770-1987)
Zinc ore
Zincite
Willemite
Franklin mine (1770-1954)
Franklinite
Sterling Hill mine (1772-1987)
Fluorescence
Fluorescence is due
to the presence of
manganese in the
atomic structure of
these minerals
Franklin and Sterling
Hill mines produced
>360 minerals, 33
unique to NJ
Willemite (green)
Calcite (red)
Graphite deposits (1848-1928)
Graphite ore
- Composed of metamorphosed carbon
from billion-year-old microorganisms
-13 mines, mainly in eastern Highlands
-mined from surface and shallow
underground workings
Annandale mill, Clinton Twp.
circa 1928
Radioactive ore - Mica deposits - Serpentine deposits
Radioactive ore (1900’s)
Mica (pre 1868)
Serpentine (1848-1900)
Crushed stone
Geologic Hazards in the Highlands
Earthquakes
Landslides and slope failure
Sinkholes
Abandoned mines
Radon
Earthquake activity
- Most common in the Highlands
- Mostly low magnitude
- Occur mainly along faults
- Caused by sudden release of energy
from locked crustal blocks along faults
Epicenter
*
Focus
Landslides and slope failure
Pattenburg
Lk Mohawk
Rock fall
Sinkholes
Form in soluble rock (marble or limestone)
from dissolution of rock by acidic water
H2O + CO2 = H2CO3
Abandoned mines
Ringwood
Byram Twp
Rockaway Twp
Jefferson Twp
Ringwood
Radon
Uranium has a geochemical affinity for
rocks with high potassium (granite)
Uranium has a valence charge of +6
(incompatible element)
Radioactive minerals
“Misfit” cation not easily incorporated in
atomic structure of earlier formed minerals.
Becomes concentrated in late stage
magmas, most commonly in granite
Uranium
238
Radium
226
Granite
Radon
222
Decay of uranium to radon gas
Part II
Geology of the
Valley and Ridge
Age
(~365)
Paleozoic rocks of the Highlands
and Valley and Ridge Provinces
- Northeast-trending ridges
- Broad, northeast-trending valleys
- Highest point 1803 ft.
- Sedimentary rocks deposited on
land and in shallow sea
-Rocks range in age from 540
to 365 million years
Million
years
ago
(~540)
Vernon Valley
Valleys underlain by relatively
soft and easily eroded shale
and limestone
Musconetcong Valley
Green Pond Mountain
Ridges underlain by resistant
conglomerate and sandstone
Kittatinny Mountain
“Puddingstone”
Depositional environment of sedimentary
rocks in the Valley and Ridge
conglomerate
limestone
sandstone
shale
Economic Geology of the Valley and Ridge
Copper (~1659-1911)
Pahaquarry mine (depth)?
Kittatinny Mountain
Silurian sandstone
Crushed stone
Limestone quarries
Lime, concrete,
fertilizer
Slate
Roofing
Chalkboards
Glacial geology of the Highlands
and Valley and Ridge Provinces
- Three major ice advances, each
of ~ 5,000 years duration:
~ 2 million to 800,000 years
~130,000 years
~21,000 years
- Ice as much as 2,000 ft thick
in northern NJ
- Advances separated by warmer
interglacial stages
Remnants of glaciation
Glacial polish
Striations
Glacial erratic
Sand & gravel
Glacially-influenced landscapes
Heaters pond
Vernon marsh
Great Meadows
Modern (post-glacial) erosional processes
Physical weathering
ƒ Physical breakdown of rock without chemical alteration
(frost wedging, plant roots, lichen, running water, human activity)
ƒ Enhanced by faulting and jointing of rock
ƒ Turns large rocks into small ones for removal by wind or
runoff, and then transport by streams
Chemical weathering
Hydrolysis
Oxidation
Carbonation
ƒ Chemical breakdown of constituent minerals in rock
ƒ Oxidation – breaks down iron and sulfur in minerals
ƒ Hydrolysis – removes Na, Ca, K and alters minerals to clay
ƒ Carbonation – dissolves calcite in marble
Groundwater cycle of the Highlands
and Valley and Ridge
Fractured bedrock aquifers
Precipitation
The New Jersey
Highlands
experiences the
greatest
precipitation in the
State due to
physiography and
other factors.
Clean water for drinking and recreation
Lunch time!