Freshwater Unit Groundwater Honors PDF

Summary

This document provides an overview of freshwater and groundwater, covering topics such as water cycle, infiltration, transpiration, and groundwater. It includes diagrams and definitions of key concepts.

Full Transcript

Freshwater Unit: Groundwater
Water Cycle
This unending
circulation of Earth’s
water supply.
Infiltration
The movement of
surface water into
rock or soil through
cracks and pore
spaces.
Transpiration
The process by which
plants absorb water
and release it into the
atmosphere.
Groundwater
Water held underground in pores or crevices in soil or rock.
Aquifer
Underground soil or rock through which groundwater can easily move.

A permeable layer of rock and sediment that stores and carries
groundwater in enough quantities to supply wells.
Water Table
The top of the water in the soil or rock.

The surface below which the groundwater is saturated with
water.
Groundwater
Water Table

Zone of Aeration:
the area below the
surface that is above the
water table, where the pores
are not filled with water.
Groundwater
Water Table

Zone of Saturation:
the area below the
water table, where the pores
are filled with water.
 Groundwater
Water Table

Aquiclude:
a solid, impermeable
area underlying or overlying
an aquifer.
 Groundwater
Water Table

Aquitard:
impermeable beds that
hinder or prevent groundwater
movement.
Porosity: Permeability:
the percent of a the rate at which
material’s volume water or other liquids
that is pore space. pass through the pore
spaces of a rock.
 PERMEABILITY
A high permeability corresponds to a high rate of
infiltration

Materials that do not allow water to pass
through them are called IMPERMEABLE
Specific Retention (Capillary Water):
water that remains in the soil after
water is drained out
Specific Yield (Sy)
Sy is defined as the
proportion of water Sy = Vd / Vt
occupying void spaces that
drains under gravity. Vd = volume drained

Because some water is Vt = volume total
bound, or adsorbed, to the
aquifer particles or fractures,
the specific yield is always
lower than the porosity
Aquifer
Underground soil or rock through which groundwater can easily
move.
A permeable layer of rock or sediment that stores and carries
groundwater in enough quantities to supply wells.
 What affects
porosity,
permeability,
capillary
water?
High Quality Aquifer Characteristics
High Porosity: More water stored
High Permeability: water flows more quickly towards the well
Low Capillary Water (Specific Retention): less water is retained
(kept) in the sediment
High Specific Yield: more water is able to come out of the aquifer.
 Grain Size
Sediment ranges in size from
clay to boulders.
Grain Size Effect Porosity:
on Aquifer Unaffected by
sediment size
Characteristics
Permeability:
Increases with
increasing
sediment size
Capillary Water:
Decreases with
increasing
sediment size
 Capillary Water:
Adhesion and Cohesion

Cohesion: Water is attracted to
water.

Adhesion: Water is attracted to
other substances.
Permeability A thin layer of water will always be
vs. attracted to mineral grains.
Pore Space The smaller the connections between
Size the pore spaces, the harder it is for
water to flow due to the layer of water
attracted to the grains.
Thus, coarse-grained (larger)
sediments are usually more permeable
than fine-grained (smaller) sediments,
pebbles are more permeable than
clays.
Permeability
Surface Area vs Particle Size
Surface Area vs Grain Size
Surface area
increases as
grain size
decreases.

There is more
surface area for
water to adhere
to in smaller
sediment.
 Grain Sorting
The grain sorting refers to the range of sediment sizes.
Well sorted = small size range
Poorly sorted = large size range
 Grain Sorting Porosity: typically
Effect on Aquifer lower for poorly
sorted sediment.
Characteristics
Permeability:
typically lower for
poorly sorted
sediment
Capillary Water:
typically higher for
poorly sorted
sediment
Grain Packing (Overburden Stress)
A measure of how
close together the
grains are, which is
caused by weight of
overlying materials
pressing down.
 Grain Packing Porosity: typically
Effect on Aquifer higher for loosely
packed sediment.
Characteristics
Permeability:
typically higher for
loosely packed
sediment
Capillary Water: if
there is more
sediment in the same
volume capillary
water increases
 Grain Shape
A measure of how
spherical the
sediment grains
are.

Angular Rounded
Grain Shape on Porosity: typically
Aquifer higher for more
spherical grains.
Characteristics
Permeability:
typically higher for
more spherical grains

Capillary Water: if
there is more sediment
in the same volume
capillary water
increases
Unconfined Aquifer:
Unconfined aquifers are
those into which water
seeps from the ground
surface directly above the
aquifer.

Confined Aquifer:
Confined aquifers are those
in which an impermeable
dirt/rock layer exists that
prevents water from seeping
into the aquifer from the
ground surface located
directly above.
Well
A hole drilled or bored into
the earth to obtain water,
petroleum, natural gas, brine,
or sulfur.
Recharge:
the refilling of
groundwater from the
surface

Recharge Area:
a recharge area is the place
where water is able to
seep into the ground and
refill an aquifer because no
confining layer is present.

Discharge:
the movement of
groundwater from the
subsurface to the surface.
Water Budget:
water budgets account for the
inputs, outputs, and changes in
the amount of water of a
system (e.g. aquifer, lake, etc.)
by breaking the water cycle
down into components.

Water Budget = Input - Output
Water Budget:
water budgets account for the
inputs, outputs, and changes in
the amount of water of a
system (e.g. aquifer, lake, etc.)
by breaking the water cycle
down into components.

Water Budget = Input - Output
Surplus:
a surplus occurs when the
inputs in the water
budget of a system (e.g.
lake) are greater than the
outputs.

Surplus = Input > Output
Deficit:
a deficit occurs when the
outputs in the water
budget of a system (e.g.
lake) are greater than the
inputs.

Deficit = Output > Input
Usage:

When plants draw water
from the soil at times
when the need for
moisture is greater than
the rainfall.
Groundwater
Overdraft:

Groundwater
overdraft occurs
when groundwater
use exceeds the
amount of recharge
into an aquifer,
which leads to a
decline in
groundwater level.1
Direct Impacts of
Groundwater Overdraft1

Reduced water supply due to aquifer depletion or groundwater contamination
Increased groundwater pumping costs, and the costs of well replacement or
deepening
Saltwater intrusion (if near the ocean)

Indirect Impacts of
Groundwater Overdraft1

Land subsidence and infrastructure damage
Harm to groundwater-dependent ecosystems
Economic losses from a more unreliable water supply
Direct Impacts:
Reduced Water
Supply and Increased
Cost

Rural landowners and
small-scale farmers
are disproportionately
affected by overdraft
as they have fewer
financial resources to
dig new or deeper
wells or diversify their
water supply.1
Direct Impacts:
Saltwater Intrusion

Under natural conditions, the
seaward movement of
freshwater prevents saltwater
from encroaching on
freshwater coastal aquifers.1

Groundwater pumping can
reduce freshwater flow
toward coastal areas and
cause saltwater to be drawn
toward the freshwater zones
of the aquifer.1
Direct Impacts:
Saltwater Intrusion

Saltwater intrusion is one of the
main causes of groundwater
quality degradation and a major
challenge in the management of
groundwater resources in coastal
regions. Saltwater intrusion
causes an increase of salt
concentration in groundwater
which places limitations on its
uses. Excessive pumping always
leads to a dramatic increase in
saltwater intrusion.1
Indirect Impacts:
Subsidence
Indirect Impacts:
Subsidence

Land subsidence is a gradual settling
or sudden sinking of the Earth's
surface due to removal or
displacement of subsurface earth
materials.1

More than 80 percent of known land
subsidence in the U.S. is a
consequence of groundwater use,
and is an often overlooked
environmental consequence of our
land and water-use practices.1
Indirect Impacts:
Harm to groundwater-dependent
ecosystems

Groundwater dependent ecosystems
(GDEs) are ecosystems which require
access to groundwater on a
permanent or intermittent basis to
meet all or some of their water
requirements so as to maintain their
communities of plants and animals,
ecological processes and ecosystem
services.1
Indirect Impacts:
Groundwater dependent ecosystems

GDEs include aquifers, caves, lakes, palustrine
wetlands, lacustrine wetlands, rivers and vegetation.