Hydrosphere: The Earth's Water World PDF

Summary

This document provides an overview of the hydrosphere, the Earth's water. It covers basic concepts, the hydrologic cycle, and groundwater resources.

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Hydrosphere:
The Earth’s Water World
Basic Concepts
Related to
Hydrosphere
Basic Concepts
Related to
Hydrosphere
▫ HYDROSPHERE is the
discontinuous layer of
water on or near the
surface of the Earth.
▫ Hydrosphere includes the
liquid and frozen surface
waters, groundwater, and
 atmospheric water vapor.
3

Water covers about 71%
of the Earth’s surface.
4

Composition of the Earth’s Water Masses
Reservoir Volume Percent of
(in cubic km) Total

Oceans 1, 338, 000, 000 96.5%
Ice Caps, Glaciers, 24, 064, 000 1.74%
Permanent Snow
Ground Ice and Permafrost 300, 000 0.22%
Groundwater 23, 400,000 1.69%
Lakes 176, 400 0.013%

(c) Britannica 5

Composition of the Earth’s Water Masses
 Reservoir Volume Percent of
(in cubic km) Total

Soil Moisture 16, 500 0.001
Atmosphere 12, 900 0.001
Swamp Water 11, 470 0.008
Rivers 2, 120 0.0002
Biota 1, 120 0.0001

(c) Britannica 6
 The Hydrologic Cycle
What is hydrologic or water cycle? Why is it
important to us, human beings?

The Hydrologic
Cycle
▫ known as water cycle
▫ cycle that involves the
continuous circulation of
water in the Earth-
 atmosphere system
▫ includes many processes,
among them are
evaporation, condensation,
precipitation, transpiration,
and run-off
8
9

Evaporation
happens when a liquid
1
turns into a gas (water
vapor)
 2

The Hydrologic Cycle 10
 4

Precipitation
any liquid or solid
water 3
that falls to Earth as a
result of condensation in
the atmosphere
The Hydrologic Cycle 11
The Hydrologic Cycle
12

The Hydrologic Cycle 13

Transpiration
process of water vapor
5
being released from
plants and soil
 6
The Hydrologic Cycle 14
 8 Sublimation
process by which ice and
7
snow (a solid) changes
into vapor without going
through the liquid phase
The Hydrologic Cycle 15

Groundwater
Resources
 What is the importance of groundwater?

Groundwater
Resources
▫ refers to water that is
collected in porous layers
of underground formation
▫ water found underground
in the cracks and spaces
in soil, sand and rock
▫ stored in and moves
slowly through geologic
formations of soil, sand
and rocks called
AQUIFERS 17
Groundwater
Resources
▫ largest potential freshwater
source in the hydrologic cycle
▫ generally free of sediment, color,
 and disease organisms, although
polluted groundwater conditions
are considered irreversible
▫ POLLUTION and
OVERCONSUMPTION are some
of the threats to the quality and
quantity of groundwater 18
Groundwater Resources
▫ groundwater accumulation varies from one place to another ▫
Heavy rains or melting snow may cause the water table to rise
(RECHARGED).
▫ Heavy pumping of groundwater supplies may cause the water table to fall. ▫
Groundwater is brought to the surface naturally through a spring, or can
bedischarged into lakes and streams. 19
Groundwater
▫ It begins as surplus water which
infiltrates then percolates
downward as gravitational
water from zone to capillary
 water to zone of aeration – an
area that is less saturated and
is filled with both air and water.
▫ Water then goes to an area
where subsurface water
accumulates – known as zone
of saturation.
▫ Flooding occurs when the
ground below is saturated. 20
Groundwater
▫ The measure of the total pore space in the soil.is called
"porosity". It is defined as the ratio of the volume of the
voids or pore space divided by the total volume.
▫ The rate at which water flows through the soil is its
"permeability". It is related as to how connected the pore
spaces are.
 21

Groundwater
▫ Saturation zone stores
 water in its countless
pores and voids.
▫ An aquifer is a term for
a type of soil or rock
that can hold and
transfer water that is
completely saturated
with water. It has high
permeability and
porosity.
22
Groundwater
▫ An aquiclude or aquitard is a rock layer that does not conduct
water in usable amounts. Aquitard can have high porosity and
hold lots of water ▫ However, aquitard’s low permeability
unables it to transmit water from pore to pore. Therefore water
cannot flow within an aquitard very well. ▫ The upper limit of the
water that collects in the zone of saturation is the water table. 23
 24

Overuse of
Groundwater
▫ As water is pumped from a
well,
the surrounding water table
within an unconfined aquifer
may experience drawdown.
▫ Overpumping or
groundwater
mining – act of pumping
aquifers beyond their flow and
charge capacity - is becoming
common in different parts of
the world to sustain their
increasing water consumption.
25

Overuse of Groundwater
 ▫ Water removal from an
aquifer may cause it to lose its
internal support, thus leading to a phenomenon known as
land subsidence.
▫ Collapsed aquifers may not be rechargeable even if
surplus water becomes available. 26
 Groundwater:
Land Subsidence 27

Overuse of Groundwater
▫ Overpumping
of water in
coastal areas
may result to
saltwater/
seawater
intrusion. Once
contaminated,
the aquifer is
difficult to
reclaim.
28

Groundwater Resources
in the Philippines
What is the status of groundwater in the
Philippines?
Groundwater Resources
in the Philippines
▫ Based on Master Plan Study on
Water Resources Management in
1998, Region II has the highest
groundwater potential while Region
VII has the lowest groundwater
potential.
▫ Annual potential water of the
Philippines is 145, 990 million m³,
 with 14% of which is groundwater.
▫ extensively used for domestic,
industrial, and irrigation purposes
30

Groundwater Resources in the Philippines31
Groundwater Resources in the Philippines
▫ Despite the high annual average rainfall, the geography of the
country limits its water storage capacity.
▫ There is an incomplete understanding as to the thickness and
extent of Philippine aquifers. 32
Groundwater Resources
in Metro Cebu
▫ major source for most of Metro
Cebu and the entire province
▫ limited catchment basins for
groundwater due to its
topography
▫ covers a total area of 180 square
kilometers
 ▫ groundwater extraction is higher
than the recharge

33 (c) Philippine Institute for Development Studies and JICA Report

Groundwater Resources in Metro Cebu
34
(c) Philippine Institute for Development Studies and JICA Report

The Ocean Basins
What are ocean basins? What are the different
geological parts of the Earth’s ocean basins?
▫ covers about 71% of the Earth’s surface
▫ place where much of the Earth’s oxygen is produced
 (through phytoplankton)
36

Introduction to Oceans
 ▫ plays a vital role in controlling
both the climate and the weather at the Earth’s surface
▫ absorbs much of the excess carbon dioxide37
Introduction to Oceans
 ▫ major source of food
38

Geological Structure of Ocean Basins
 ▫ oldest rocks in the ocean were not found in
the center, as might be expected, but at the ocean margins
▫ ocean basins form when two plates spread apart and new crust is formed at
the mid-ocean ridge
▫ edge of the ocean basin, and generally its deepest part, is the bottom of the
continental rise which is also where the oceanic lithospheric plate 39
Depth and Shape of Ocean Basins ▫ deep
ocean is
nearly as rugged in
its bathymetry as
the terrain we see
on land
▫ undersea
mountains are in
general longer the
valley floors wider
and the canyons
often deeper than
 the equivalent
features on land
40

Depth and Shape of Ocean Basins
▫ CONTINENTAL SHELF is the area of seabed around a large
landmass where the sea is relatively shallow compared with the
open ocean; geologically part of the continental crust.
▫ It is usually less than 150 m deep; most of its sediments are
derived from the physical erosion of the land; often has rich
fisheries and hydrocarbons41
Depth and Shape of
Ocean Basins
▫ CONTINENTAL SLOPE – located
between the outer edge of the
continental shelf and the deep
ocean floor
▫ ABYSSAL PLAIN- flat seafloor
area at an abyssal depth (3-6 km)
generally adjacent to a continent
▫ SEAMOUNT- undersea mountains
of about 1 km higher compared to
their surrounding seafloor;
biological hotspot that supports a
wide array of marine life;
considered as a navigational hazard 42
 world GREAT CHAGOS BANK
(British Indian Ocean

▫ Some seamounts are
tall enough to reach the
surface as oceanic
islands or atolls ▫
Flat-topped
seamounts are
MAUNA KEA (USA) – tallest mountain in the

called GUYOTS. AUSTRALIA-TASMANIA AREA
when measured from its underwater base (over 10km) KŌKŌ GUYOT – largest guyot in the
world
 Territory) – largest atoll in the world

43

Depth and Shape of Ocean Basins ▫ OCEAN RIDGES
are continuous
submarine
mountain chain
extending
approximately
80,000 km
(50,000 miles)
 through all the
world’s oceans
▫ TRENCHES are
the deepest
valleys on Earth;
they are narrow,
steep-sided 44

Physical Properties
of the Ocean
What are the major elements present in the ocean?
Physical Properties of the Ocean
Sulfur (as 905
sulfates)
Element Concentration in
Seawater Calcium 412
(mg/L)
Potassium 380
Chloride 19 500
Sodium 10 770 ❑ Seawater is made up principally of
sodium chloride and magnesium
Magnesium 1 290 sulfate, with significant amounts of
potassium, calcium, and
bicarbonate.
❑ The chemicals that make up the the sea, and they are involved in
salt in seawater were originally a variety of chemical, geological,
derived from the chemical and biological reactions as they
weathering of rocks of land. reach the sea.
❑ They flow as a dilute solution into
(c) Holden (2017) 46

Physical Properties of
the
 ▫ Although the ratio of
Ocean most chemical
elements in the
seawater is constant
over all the world’s
oceans, its actual
concentration varies
on the location and
rate of evaporation.
▫ The concentration of
salt in the ocean is
expressed as parts
per thousand (ppt)
 or in salinity units.
47

Temperature and
Salinity Structure of
the Oceans
Temperature Structure
▫ The surface of the ocean
of the Oceans gains heat by radiation
from
the Sun, particularly in lower
 latitudes, and by conduction
and convection from warm
air flowing over the waves.
▫ Heat is lost by evaporation,
reradiation to space, and by
conduction to cold air
above.
▫ Water, specially oceans acts
as a major storage of the
energy of the Sun.
49

Temperature and Salinity
Changes in Oceans
▫ water density increases with increasing
salinity and decreasing temperature
▫ Thermocline - oceanic water layer in
which water temperature decreases
rapidly with increasing depth
▫ Halocline - which is the layer where
 salinity concentration also rapidly changes.

50

Temperature and
Salinity Structure of
the Oceans
▫ Pycnocline is the boundary
separating two liquid layers of
different densities.
▫ Because the pycnocline zone is
extremely stable, it acts as a
barrier for surface processes.
▫ Water density varies throughout
the ocean and the water at the
bottom of the ocean is densest.
51

Global Surface Salinity by NASA
52

Global Average Sea
Temperature by Earth
Observer and National
Oceanographic Data Center
 53

Global Average Sea Temperature and
Salinity by National Oceanographic and Atmospheric
Administration
 54

Deep Ocean Currents
▫ The large-scale deep circulation of
the world’s oceans is not driven by
wind but by density variations.
▫ The density of seawater is
controlled by its salinity and
temperature. The resulting
circulation is called the
THERMOHALINE CIRCULATION.
▫ When a body of water becomes
denser than the water surrounding
 it, it sinks.
▫ Water that sinks away into the
deep has to be balanced by water
upwelling to the surface 55
Deep Ocean Currents
▫ Regions of upwelling are important because the upwelled water
contains an abundance of plant nutrients, nitrate and phosphate,
which, when they reach the surface layers where there is
sufficient light, result in a vast bloom of phytoplankton which in
turn sustains major fisheries.
 56

Global Ocean
Conveyor Belt
▫ The GLOBAL OCEAN CONVEYOR
 BELT is a constantly moving system
of deep-ocean circulation driven by
temperature and salinity.
▫ The ocean conveyor gets its “start”
in the Norwegian Sea, where warm
water from the Gulf Stream heats
the atmosphere in the cold northern
latitudes.
▫ This loss of heat to the atmosphere
makes the water cooler and denser,
causing it to sink to the bottom of
the ocean. 57
 Global Ocean
Conveyor Belt
▫ As more warm water is transported
north, the cooler water sinks and
moves south to make room for the
incoming warm water.
▫ This cold bottom water flows south
of the equator all the way down to
Antarctica.
▫ Eventually, the cold bottom waters
returns to the surface through
mixing and wind-driven upwelling,
continuing the conveyor belt that
encircles the globe. 58
Global Ocean
Conveyor
Belt
▫ Heat and nutrients
move around the
world in about a
1000-year cycle.
▫ The heat carried
north helps keep the
Atlantic ocean
warmer in the winter
time, which warms
the nearby countries
as well.
59
60

Global Ocean
Conveyor Belt
▫ Global warming may cause
sufficient freshwater to be
released from the melting of ice
in the northern latitudes to slow
or even to stop the formation of
the North Atlantic Deep Water
by reducing salinity to the level
where it is insufficiently dense
to sink.
▫ This would have a dramatic
cooling effect on the climate of
north-west Europe. 61
Surface Ocean
Currents
▫ The surface currents are
driven by the prevailing
winds.
▫ The trade winds that blow
out of the south-east in the
southern hemisphere and
out of the north-east in the
northern hemisphere drive
the Northern and Southern
Equatorial Currents, which
 move in a westerly direction
parallel to the equator.
62

Surface Ocean
Currents
▫ These currents are
deflected
by the continents when
they
reach the coastal areas.
▫ In addition to the
continents
deflecting the water, the
Coriolis Effect also causes
water to deflect to the right
in the northern hemisphere
and to the left in the
southern hemisphere.

63

Surface Ocean
Currents
▫ The center of some of
the gyres contains large
amounts of debris such
as plastic which has
been carried there by
the surface ocean
currents after being
dumped into the oceans
by humans.
▫ Example of this is the
GREAT PACIFIC
GARBAGE PATCH.64
Garbage Accumulation in World’s
Oceans
65
Plastic Pollution Data by University of Oxford
 Biological Productivity
of Oceans
What is the contribution of the oceans to the
world’s biological productivity?

Biological
Productivity
▫ The highest productivity in the
oceans occurs in those areas
where
 the supply of dissolved nutrients is
greatest.
▫ The most productive areas of the
ocean are the areas of coastal
upwelling which have abundant life.
▫ Although most of the life in the
oceans are found near the surface,
several kinds of flora and fauna also
thrive in ocean bottoms, like in
hydrothermal vents. 68
Biological
Productivity
▫ In all the waters of every
ocean, one organism preys on
another.
▫ At the base of this food chain
further explanation of food
chains) are the phytoplankton,
the primary producers, while
at the top of the pyramid are
the carnivores: sharks, tuna
and of course now also
humans.
69
Global Plankton Range
 70

Effects of Climate
Change on Oceans What
is the effect of climate change to the world’s
oceans?
Effects of Climate Change to World’s Oceans
 ▫ The major global temperature
change is in the oceans not on land: 93% of
the additional heat since the 1970s has been absorbed by the oceans,
leading to an average increase of almost 2°C to global surface temperature
of world’s oceans. 72
Effects of Climate Change to World’s Oceans
 ▫ Increasing ocean temperatures
affect marine species and ecosystems.
▫ Rising temperatures cause coral bleaching and the loss of breeding
grounds for marine fishes and mammals. 73
 74

Effects of Climate
Change to World’s
Oceans
▫ Rising ocean temperatures
also affect the benefits
humans derive from the
ocean – threatening food
security, increasing the
prevalence of diseases and
 causing more extreme
weather events and the
loss of coastal protection.

75

Effects of Climate Change
to World’s Oceans
▫ The increase in CO2 in the atmosphere is
also having a direct effect to OCEAN
ACIDIFICATION. Carbon dioxide is a weak
acid, which is readily soluble in seawater.
▫ As the amount of CO2 in the atmosphere
 has increased from 280 ppm (pre-
industrial) to 400 ppm in 2015, some of
this excess CO2 has dissolved in surface
waters, making it more acidic (current
change of -0.05 pH).
▫Organisms that use CaCO3 to build their
skeletons, to grow. 76
Ocean Acidification
Ocean Acidification
Effects of Climate Change
to World’s Oceans
▫ As the temperature of the surface
ocean increases, it also decreases the
amount of oxygen that can dissolve in
the water.
▫ Some parts of the ocean, called
oxygen
minimum zones (OMZ), are already
very
close to running out of oxygen
 altogether.
▫ The largest OMZs are under the east
central Pacific (200–2000 m) and at
similar depths in the northern Indian
ocean. 79

Hydrosphere:
The Earth’s Water World