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Why don't oil and water mix? - John Pollard

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    Why does salt dissolve in water but oil doesn't?
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    Well, in a word, chemistry,
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    but that's not very satisfying, is it?
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    Well, the reason salt dissolves and oil does not
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    comes down to the two big reasons
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    why anything happens at all:
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    energetics
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    and entropy.
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    Energetics deals primarily
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    with the attractive forces between things.
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    When we look at oil or salt in water,
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    we focus on the forces between particles
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    on a very, very, very small scale,
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    the molecular level.
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    To give you a sense of this scale,
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    in one glass of water,
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    there are more molecules
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    than known stars in the universe.
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    Now, all of these molecules are in constant motion,
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    moving, vibrating, and rotating.
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    What prevents almost all of those molecules
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    from just flying out of the glass
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    are the attractive interactions between molecules.
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    The strength of the interactions
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    between water, itself, and other substances
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    is what we mean when we say energetics.
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    You can think of the water molecules engaging
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    in a constant dance,
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    sort of like a square dance
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    where they constantly and randomly exchange partners.
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    Put simply, the ability for substances
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    to interact with water,
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    balanced with how they disrupt
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    how water interacts with itself,
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    plays an important role in explaining
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    why certain things mix well into water
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    and others don't.
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    Entropy basically describes
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    the way things and energy can be arranged
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    based on random motion.
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    For example, think of the air in a room.
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    Imagine all the different possible arrangements
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    in space for the trillions of particles
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    that make up the air.
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    Some of those arrangments
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    might have all the oxygen molecules over here
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    and all the nitrogen molecules over there,
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    separated.
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    But far more of the possible arrangements
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    have those molecules mixed up with one another.
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    So, entropy favors mixing.
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    Energetics deals with attractive forces.
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    And so, if attractive forces are present,
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    the probability of some arrangements
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    can be enhanced,
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    the ones where things are attracted to each other.
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    So, it is always the balance of these two things
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    that determines what happens.
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    On the molecular level,
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    water is comprised of water molecules,
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    made up of two hydrogen atoms and an oxygen atom.
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    As liquid water, these molecules are engaged
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    in a constant and random square dance
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    that is called the hydrogen bonding network.
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    Entropy favors keeping
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    the square dance going at all times.
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    There are always more ways
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    that all the water molecules can arrange
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    in a square dance,
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    as compared to if the water molecules
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    did a line dance.
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    So, the square dance constantly goes on.
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    So, what happens when you put salt in the water?
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    Well, on the molecular level,
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    salt is actually made up of two different ions,
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    chlorine and sodium,
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    that are organized like a brick wall.
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    They show up to the dance
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    as a big group in formation
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    and sit on the side at first,
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    shy and a bit reluctant to break apart
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    into individual ions to join the dance.
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    But secretly, those shy dancers
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    just want someone to ask them to join.
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    So, when a water randomly bumps into one of them
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    and pulls them into the dance away from their group,
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    they go.
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    And once they go into the dance,
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    they don't come back out.
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    And in fact, the addition of the salt ions
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    adds more possible dance positions
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    in the square dance,
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    so it is favored for them to stay dancing with water.
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    Now, let's take oil.
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    With oil, the molecules are sort of interested
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    in dancing with water,
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    so entropy favors them joining the dance.
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    The problem is that oil molecules
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    are wearing gigantic ballgowns,
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    and they're way bigger than water molecules.
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    So, when an oil molecule gets pulled in,
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    their size is really disruptive to the dance
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    and the random exchange of partners
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    that the waters engage in,
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    a very important part of the dance.
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    In addition, they are not great dancers.
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    The water molecules try to engage
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    the oil molecules in the dance,
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    but they just keep bumping into their dresses
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    and taking up all the room on the dance floor.
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    There are way more ways the waters can dance
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    when the oil gets off the floor,
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    so the waters squeeze out the oil,
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    pushing it back to the bench with the others.
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    Pretty soon, when a large number of oils
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    have been squeezed over to the side,
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    they band together to commiserate
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    about how unfair the waters are being
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    and stick together as a group.
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    So, it is this combination
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    of the interactions between molecules
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    and the configurations available to them
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    when they're moving randomly
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    that dictates whether they mix.
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    In other words, water and oil don't mix
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    because they just don't make great dance partners.
Title:
Why don't oil and water mix? - John Pollard
Description:

View full lesson: http://ed.ted.com/lessons/why-don-t-oil-and-water-mix-john-pollard

Salt dissolves in water; oil does not. But why? You can think of that glass of water as a big, bumpin' dance party where the water molecules are always switching dance partners -- and they'd much rather dance with a salt ion. John Pollard explains how two chemistry principles, energetics and entropy, rule the dance floor.

Lesson by John Pollard, animation by Andrew Foerster.
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Video Language:
English
Team:
closed TED
Project:
TED-Ed
Duration:
05:03

English subtitles

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