Queens Tunnel Mineral Localities
Charles Merguerian
©2006
Updated 22 February 2006
Today, sparse bedrock exposures
exist in westernmost Queens where subsurface excavation of the Queens Tunnel
took place between 1996 and 1999. Although now largely covered by urban
structures, a few bedrock
exposures still can be found west of the tunnel, in
Queens. This proves that "If
a tree can grow in Brooklyn – a rock outcrop can be found
in Queens".
Suffice to say
that bedrock exposures have not been overly helpful in portraying bedrock
conditions before excavation of the Queens Tunnel.
A collaborative effort by (Merguerian 1999,
2000, 2001, 2002; Merguerian, Brock, and Brock 2001; Brock, Brock and Merguerian
2001; Merguerian and Ozdemir 2003) has redefined the bedrock stratigraphy of western Queens based on
detailed mapping and
study of the Queens Tunnel rocks.
The roughly five-mile long Queens
Tunnel is segmented by one major 116.7°
curve and three smaller curves (1.8°,
13.7°,
and 26.5°). The hamster-leg shape of the tunnel (a NE-trending leg of
10,000’ and a NW-trending leg of 15,522’) offers the geologist a broad
cross-sectional view of the geology of the region.
In the late Twentieth Century, Dukelabs geologists mapped the
Queens Tunnel and spent some free time collecting minerals along fault zones and
from pegmatites. Most of the minerals were found in individual and
reactivated faults with NNE and NNW trends (Merguerian, 2002). The
minerals described below were identified using a stereoscopic microscope and
standard physical property tests (luster, color, hardness, streak, cleavage,
crystal form, etc.) used by any self-respecting card-carrying geologist. We
await x-ray and optical tests for an "idontknowite" identified
stereoscopically.
The mineral locality descriptions provided below
are keyed to mapped areas of the Queens Tunnel. For example, Station 162+92 is found 16,292'
away from the main shaft (19B) at Maspeth. Stationing starts at Shaft 19B
in Maspeth and increases northeastward for 10,000' to Shaft 18B (Proposed)
beneath Woodside. Clicking will bring
you to a separate Gallery of Queens Tunnel
Microminerals taken under the stereoscope and to a Gallery of Queens Tunnel
Macrominerals taken with a digital camera. We
hope you enjoy them. The
hole through on 27 October 1999 marked and
important event for the future of NYC municipal water flow (*and emergency
plumbing contracts!)
Image: Courtesy Grow-Perini-Skanska, JV.
MINERALS OF THE QUEENS TUNNEL
Visit our Queens Tunnel Micromineral Gallery and our Queens Tunnel Macromineral Gallery
Updated 01 January 2006
030+75 – Deep lime green drusy and microcrystalline epidote in veins up to 1 cm thick on a substrate of altered mafic gneiss.
077+85 – Upon a substrate of heulandite, cream-colored stilbite in hemispherical masses 2 cm wide and as felted crystalline masses of single sheaf-like crystals. The stilbite is overgrown by calcite and by pyrite. Mineralization occurs in a NS-trending reverse fault cutting interlayered garnet-diorite orthogneiss and garnet amphibolite. Collected 9/9/99 and 2/8/00.
093+35, RW - Blue plagioclase euhedral 1-2
cm crystals (sweats) in gabbroic gneiss cut by pegmatite and normal fault.
Collected
~101+00 – Massive pyrite and quartz in a vein along NNW-trending fault.
~150+00 - Fallen block from left rib
containing greenish radiating masses of prehnite overgrown with apophyllite,
pyrite, and calcite crystals. Pointed
out by Joe Brown and collected
~151+00 – Apophyllite with pyrite and
calcite. Collected
~151+00 - Pyrite crystals in dacite host.
Collected
162+30, RW - Stilbite forming a base with
calcite crystals and cubic, clear chabazite microcrystals in a NNE-trending
reverse fault zone. Collected
165+92, RW – Yellowish stilbite as a base
to calcite crystals and drusy pyrite. The
stilbite crystals, found in N20°E,
71°SE
fault, grew as fibers perpendicular to the fracture.
Collected
166+65, RW – Yellowish stilbite, calcite,
and drusy pyrite crystals in N22°E,
77°NW-trending
fault zone. Collected
167+00, RW & LW - Major 35’-wide NNE
faulted pegmatite zone with box-work open cavities and greenish clay gouge.
Megascopically, stilbite blades are overgrown by 2-3 mm spherical masses
of pyrite. The multifaceted
spherical masses are superceded by calcite crystallization, all on a fractured
pegmatite or amphibole-gneiss matrix. Collected
169+37, RW & LW - Open cavities in fault
zone (N35°E,
68°NW)
through amphibolite in garnet schist containing deep orange stilbite.
The stilbite occurs in cavities a few cm in size as rounded sheaf-like
clusters. Micro-scale pyrite cubes coat the stilbite.
Some late-stage clear acicular stilbite blades occur locally.
Collected
188+86, LW - Stilbite in sheaf-like crystal
shapes at contact of pegmatite and biotite-chlorite schist. Another pocket
located next to another pegmatite at 188+96, LW.
Late plates of pyrite are found intergrown at late stages of stilbite
mineralization. Collected
190+15, RW - Light yellow crystalline
stilbite crystals occur in gouge-rich fractured pegmatite.
The stilbite crystals are overgrown on massive calcite.
Two generations of small, clear crystals (apophyllite and younger
analcime are predicted based on crystal shape) occur next.
The analcime crystals are particularly striking because of their facet
reflections and clarity. Locally,
cm-scale pseudo-cubic calcite crystals are found to overgrow the crystallized
matrix. Collected
190+52, RW - Clear interpenetrating calcite
crystals about 1 cm in size in N11°E,
67°NW
fault zone overgrow stilbite. Stilbite
crystals form a basal substrate found overgrown with massive stilbite then the
calcite. Late pyrite cubes here
overgrow a second generation of clear stilbite blades.
Collected
210+12, RW - Pegmatite matrix with openings
containing microcrystalline epidote and chlorite, 4 mm tabular pink apophyllite(?),
sphalerite, and stilbite. Collected
214+25, LW - Radiating masses of
orange-colored stilbite surrounded by white calcite in fracture fillings related
to a fault oriented N29°E,
72°SE.
The fault, which cuts mafic gneiss, has produced a crush breccia zone up
to 3 m wide. Mineralization is found
in thin veins a few mm thick to irregular nodules up to 10 cm long, all within
the brittle fault fabric. Collected