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Natural Capital: Sustaining Life on Earth

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Title: Natural Capital: Sustaining Life on Earth


1
Natural Capital Sustaining Life on Earth
  • Earth is an open system in terms of energy
    energy flows through an ecosystem
  • All energy is ultimately in the form of heat
  • Earth is a closed system in terms of matter
    matter is recycled in an ecosystem
  • There is no away

2
Components of Ecosystems
3
Trophic Levels
4
The Nitrogen Cycle
5
The Nitrogen Cycle
  • The most complex of the biogeochemical cycles
  • N2 78 of the troposphere, chemically
    unreactive, cannot be used/absorbed directly in
    this form by multicellular plants or animals.
    Even though this is a large source of nitrogen,
    must be converted before it can be of use to
    living organisms.
  • Nitrogen cycle steps nitrogen fixation,
    nitrification, assimilation, ammonification and
    denitrification

6
The Nitrogen Cycle
  • Nitrogen Fixation atmospheric nitrogen (N2)is
    converted to ammonia, NH3
  • By cyanobacteria in soil/water and Rhizobium in
    root nodules of legumes (peas, clover, beans,
    etc.)
  • Nitrification
  • NH3 converted by aerobic bacteria to NO2-
    (nitrite)
  • NO2- converted by bacteria to NO3-(nitrate, most
    useful form)
  • Assimilation Plant roots absorb nitrates that
    are then converted into organic compounds like
    proteins and DNA. And of course, animals eat
    plants.
  • Ammonification N-rich organic compounds, wastes,
    caste-off particles, dead bodies, etc., are
    converted into simpler N-containing inorganic
    compounds (e.g., NH3)
  • By decomposer bacteria
  • Denitrification NH3 gt NO3- and NO2- gt N2O and
    N2
  • Mostly by anaerobic bacteria in waterlogged soil,
    bottom sediments of lakes, swamps, bogs and
    oceans

7
Significant Human Interventions
  • Internal combustion engine exhaust (i.e., fossil
    fuel burning) adds NO (nitric oxide) to the
    atmosphere when N2 reacts with O2. NO can react
    with oxygen to form NO2 (nitrogen dioxide), which
    can then react with water vapor to form HNO3
    (nitric acid), a significant component of acid
    rain.
  • Farming/agriculture and cities N-rich
    fertilizers from farms and sewage from
    municipalities runs off into bodies of water.
    This stimulates the growth of algae and aquatic
    plants which then die and are broken down by
    aerobic decomposers. This aerobic decomposition
    reduces the dissolved oxygen (DO) content in the
    water, impacting fish and other aquatic animals
  • Mining for N-rich minerals from the earths crust
    and soil
  • Nitrogen is can be depleted from topsoil when we
    over-harvest or over-graze plants and then burn
    or clear grasslands and forests
  • Cattle waste and inorganic N-fertilizers are
    broken down by bacteria into N2O (nitrous oxide).
    This is a heat-trapping gas and can contribute to
    the warming of the atmosphere.

8
The Carbon Cycle (Terrestrial)
9
The Carbon Cycle (Marine)
10
The Carbon Cycle
  • Cycles closely with hydrogen and oxygen,
    especially as an essential component of organic
    molecules (e.g., carbohydrates) and inorganic
    molecules (e.g., CO2)
  • Aerobic respiration C6H12O6 6O2 gt 6 CO2 6H2O
    38 ATP
  • Photosynthesis 6CO2 6H2O light energy gt
    C6H12O6 6O2
  • CO2 0.036 of the troposphere (lowest part of
    atmosphere) gases, is also easily dissolved in
    H2O
  • CO2 enters the atmosphere by burning fossil
    fuels, aerobic respiration and volcanic activity
  • CO2 is a heat-trapping gas, and an important
    component of the earths thermostat
  • More CO2 exacerbates the greenhouse effect

11
The Carbon Cycle
  • The oceans help regulate the CO2 in the
    atmosphere
  • When oceans take in CO2, there is a cooling
    effect due to the heat-trapping ability of CO2
  • Some CO2 stays dissolved in sea water
  • Some is removed by photosynthesis (aquatic
    plants, algae and phytoplankton)
  • Some reacts with sea water gt CO3-2 and HCO3-
    which can react with Ca2 to form CaCO3
  • CaCO3 is used by marine organisms for shells and
    skeletons
  • These organisms live, die, sink, are buried for
    many years, and over time, under pressure, the
    CaCO3 turns into limestone on the ocean floor

12
The Carbon Cycle
  • The long term storage units for carbon are the
    ocean floor (limestone) and limestone and other
    sedimentary rocks and soils on the continents
  • The shorter term units are the atmosphere and
    oceans
  • The average residence times of CO2 in these
    units are 3 years (atmosphere), 25-30 years
    (soils) and 1500 years (oceans)
  • CO2 is released from the oceans as H2O
    temperature increases
  • Warm waters cannot absorb as much CO2 as cooler
    waters
  • There is a positive feedback loop between CO2
    levels and atmospheric temperatures -
    implications for global climate change

13
Significant Human Interventions
  • There are two major interventions that lead to
    increasing levels of CO2 in the atmosphere
  • Vegetation removal/deforestation
  • Fossil fuel and wood burning
  • Reasons for concern
  • Enhanced/magnified natural greenhouse effect
  • Altered global food production due to shifting
    climate belts
  • Altered wildlife habitat due to changes in
    temperature and precipitation
  • Altered species interactions
  • Rise in sea levels due to thermal expansion of
    water as troposphere temperature increases
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