Chemistry Exam > Chemistry Videos > Inorganic Chemistry > Atomic Inversion - Chemical Bonding
Atomic Inversion - Chemical Bonding Video Lecture | Inorganic Chemistry
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FAQs on Atomic Inversion - Chemical Bonding Video Lecture - Inorganic Chemistry
| 1. What is atomic inversion in chemical bonding? |  |
Ans. Atomic inversion in chemical bonding refers to the process in which the electron density of an atom gets inverted or reversed during a chemical reaction. This inversion can occur when a highly electronegative atom displaces a less electronegative atom from its usual position in a molecule or compound.
| 2. How does atomic inversion affect the stability of a compound? | |
Ans. Atomic inversion can significantly affect the stability of a compound. When an atom undergoes inversion, it disrupts the original bonding pattern and can lead to the formation of new bonds or the breaking of existing bonds. This change in bonding can alter the energy state of the compound, potentially making it more or less stable depending on the specific circumstances of the reaction.
| 3. Is atomic inversion a common occurrence in chemical reactions? | |
Ans. Atomic inversion is not a common occurrence in all chemical reactions, but it can happen in certain cases. It is more likely to occur when there is a large difference in electronegativity between the atoms involved in the reaction. For example, in reactions involving highly electronegative elements like oxygen or fluorine, the displacement of less electronegative atoms can result in atomic inversion.
| 4. What are some examples of atomic inversion in chemical bonding? | |
Ans. One example of atomic inversion is the reaction between water (H2O) and hydrogen peroxide (H2O2) to form hydronium ions (H3O+). In this reaction, the oxygen atom in water displaces one of the hydrogen atoms in hydrogen peroxide, resulting in the inversion of the oxygen atom's electron density. Other examples include reactions involving halogens, such as chlorine or bromine, displacing less electronegative atoms in compounds.
| 5. Can atomic inversion lead to the formation of new compounds? | |
Ans. Yes, atomic inversion can lead to the formation of new compounds. When an atom's electron density is inverted, it can create new bonding possibilities with other atoms or molecules. This can result in the formation of different compounds compared to the starting materials. Atomic inversion plays a crucial role in various chemical reactions, including substitution reactions and acid-base reactions.
Text Transcript from Video
everyone's professor Davis here
answering a question that was posed on
the YouTube channel can a means be Kyle
centers and why is it that we often
treat them as though they're not even
though they clearly have a tetrahedral
electron domain geometry to begin
answering this question I've drawn
ammonia molecule here with nitrogen
represented in blue and its lone pair
electrons represented by the pink
coloured substituents so we have three
hydrogen's and one lone pair about this
nitrogen center and although this is not
chiral or even apparently chiral
molecule I want to show you first the
phenomenon that we're going to rely on
to explain this simply using something
like ammonia what happens here is lone
pair electrons on the nitrogen center
are contained in sp3 hybridized orbitals
and because they have a little bit of
that s character there that means that
that lone pair of electrons can actually
move through the center of this molecule
to the other side of the nitrogen so
unlike the chemical bonds it can
relocate itself to the opposite side now
let's take a look at what happens when
that occurs as you can see the three
hydrogen's are flipping back and forth
sort of like an umbrella being inverted
and this is the effect that causes most
nitrogen containing compounds to be a
chiral even though they actually do have
two sets of enantiomers now let me show
you using a chiral Center what that
looks like
so shown here is our nitrogen-containing
molecule but I replaced the hydrogen's
with three different colored
substituents again we have our nitrogen
center in blue our lone pairs of
electrons shown as the pink and then
three distinct substituents leading to a
chiral center however recall that the
lone pair of electrons can go through
the center causing it to flip back and
forth if this exchange happens rapidly
on the timescale of our experiments in
the lab we'll have a mixture of these
two handed versions of our nitrogen
molecules no matter what we do even if
we could isolate one of the two it would
rapidly begin interconverting with the
other enantiomer which means that
although a means may be technically
chiral centers it's very difficult to
make an enantiomeric we pure sample of
one and only in rare cases do we see
this happen I hope this has answered
your question and we'll see you next
time we upload
answering a question that was posed on
the YouTube channel can a means be Kyle
centers and why is it that we often
treat them as though they're not even
though they clearly have a tetrahedral
electron domain geometry to begin
answering this question I've drawn
ammonia molecule here with nitrogen
represented in blue and its lone pair
electrons represented by the pink
coloured substituents so we have three
hydrogen's and one lone pair about this
nitrogen center and although this is not
chiral or even apparently chiral
molecule I want to show you first the
phenomenon that we're going to rely on
to explain this simply using something
like ammonia what happens here is lone
pair electrons on the nitrogen center
are contained in sp3 hybridized orbitals
and because they have a little bit of
that s character there that means that
that lone pair of electrons can actually
move through the center of this molecule
to the other side of the nitrogen so
unlike the chemical bonds it can
relocate itself to the opposite side now
let's take a look at what happens when
that occurs as you can see the three
hydrogen's are flipping back and forth
sort of like an umbrella being inverted
and this is the effect that causes most
nitrogen containing compounds to be a
chiral even though they actually do have
two sets of enantiomers now let me show
you using a chiral Center what that
looks like
so shown here is our nitrogen-containing
molecule but I replaced the hydrogen's
with three different colored
substituents again we have our nitrogen
center in blue our lone pairs of
electrons shown as the pink and then
three distinct substituents leading to a
chiral center however recall that the
lone pair of electrons can go through
the center causing it to flip back and
forth if this exchange happens rapidly
on the timescale of our experiments in
the lab we'll have a mixture of these
two handed versions of our nitrogen
molecules no matter what we do even if
we could isolate one of the two it would
rapidly begin interconverting with the
other enantiomer which means that
although a means may be technically
chiral centers it's very difficult to
make an enantiomeric we pure sample of
one and only in rare cases do we see
this happen I hope this has answered
your question and we'll see you next
time we upload
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Nov 16, 2024 Last updated |
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