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How does fracking work? - Mia Nacamulli

  • 0:09 - 0:14
    Deep underground lies stores of once
    inaccessible natural gas.
  • 0:14 - 0:18
    This gas was likely formed
    over millions of years
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    as layers of decaying organisms
    were exposed to intense heat and pressure
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    under the Earth's crust.
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    There's a technology called
    hydraulic fracturing,
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    or fracking,
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    that can extract this natural gas,
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    potentially powering us
    for decades to come.
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    So how does fracking work,
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    and why it is a source
    of such heated controversy?
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    A fracking site can be anywhere
    with natural gas,
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    from a remote desert
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    to several hundred feet
    from your backyard.
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    It starts out with a long vertical hole
    known as a wellbore
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    drilled down through layers of sediment.
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    When the well reaches 2500 - 3000 meters,
    it's at its kickoff point
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    where it can begin the process
    of horizontal drilling.
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    It turns 90 degrees and extends
    horizontally for about 1.5 kilometers
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    through a compressed black layer
    called the shale rock formation.
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    A specialized perforating gun
    is then lowered and fired,
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    creating a series of small,
    inch-long holes
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    that burst through the well's casing
    into the rock layer.
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    About three to four months
    after the initial drilling,
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    the well is ready for fracking to begin.
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    Fracking fluid is pumped down
    into the well at a pressure so high,
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    it cracks the shale rock,
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    creating fractures through which
    the trapped gas and oil can escape.
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    The fluid itself is more than 90% water.
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    The rest is made up of concentrated
    chemical additives.
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    These vary depending on the specific
    characteristics of the fracking site,
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    but usually fall into three categories:
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    acids for clearing debris
    and dissolving minerals,
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    friction-reducing compounds to create
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    a slippery form of water
    known as slickwater,
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    and disinfectant to prevent
    bacteria growth.
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    Sand or clay is also mixed into
    the water to prop open the fissures
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    so the gas and oil can keep leaking out,
    even after the pressure is released.
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    It's estimated that all of fracking's
    intense pumping and flushing
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    uses an average of 3-6 million gallons
    of water per well.
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    That's actually not a lot compared
    to agriculture,
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    power plants,
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    or even golf course maintenance,
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    but it can have a notable impact
    on local water supply.
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    And disposing of used fracking water
    is also an issue.
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    Along with the trapped gas
    that's pumped up to the surface,
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    millions of gallons of flow-back liquid
    come gushing up.
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    This liquid containing contaminants
    like radioactive material,
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    salts,
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    heavy metals,
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    and hydrocarbons,
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    needs to be stored and disposed of.
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    That's usually done in pits on-site
    in deep wells
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    or off-site at water treatment facilities.
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    Another option is to recycle
    the flow-back liquid,
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    but the recycling process can actually
    increase levels of contamination
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    since the water is more toxic
    with each use.
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    Wells are typically encased
    in steel and cement
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    to prevent contaminants from leaking
    into groundwater.
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    But any negligence
    or fracking-related accidents
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    can have devastating effects.
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    Fracturing directly
    into underground water
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    hazardous underground
    seepage and leakage,
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    and inadequate treatment and disposal
    of highly-toxic waste water
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    can potentially contaminate
    drinking water around a fracking site.
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    There's also concern about
    the threat of earthquakes
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    and damaged infrastructure
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    from pressure
    and waste water injection.
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    Links between fracking
    and increased seismic activity
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    leave unresolved questions
    about long-term pressure imbalances
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    that might be happening
    deep beneath our feet.
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    Fracking's biggest controversy, though,
    is happening above the ground.
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    The general consensus is that burning
    natural gas is better for the environment
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    than burning coal
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    since the gas collected from fracking
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    emits only half
    the carbon dioxide as coal
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    per unit of energy.
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    The pollution caused
    by the fracking itself, though,
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    isn't negligible.
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    Methane that leaks out during the drilling
    and pumping process
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    is many times more potent
    than carbon dioxide
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    as a greenhouse gas.
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    Some scientists argue that methane
    eventually dissipates,
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    so has a relatively low long-term impact.
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    But a greater question hangs in the air.
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    Does fracking take time,
    money, and research
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    away from the development
    of cleaner renewable energy sources?
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    Natural gas is non-renewable,
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    and the short-run economic interests
    supporting fracking
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    may fall short in the face
    of global climate change.
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    Experts are still examining
    fracking's overarching effects.
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    Although modern fracking has been
    around since the 1940s,
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    it's boomed in the last few decades.
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    As other sources of natural gas decrease,
    the costs of non-renewable energies rise,
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    and cutting-edge technologies
    make it so accessible.
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    But many countries and regions
    have already banned fracking
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    in response to environmental concerns.
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    It's undeniable that fracking has reshaped
    the energy landscape around the world,
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    but for what long-term benefit
    and at what cost?
Title:
How does fracking work? - Mia Nacamulli
Description:

View full lesson: http://ed.ted.com/lessons/how-does-fracking-work-mia-nacamulli

Deep underground lie stores of once-inaccessible natural gas. There’s a technology, called hydraulic fracturing, or “fracking,” that can extract this natural gas, potentially powering us for decades to come. So how does fracking work and why is it a source of such heated controversy? Mia Nacamulli explains the ins and outs of fracking.

Lesson by Mia Nacamulli, animation by Sharon Colman.
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Video Language:
English
Team:
closed TED
Project:
TED-Ed
Duration:
06:04

English subtitles

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