VSEPR and Bond Hybridization - AP Chemistry

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Question

What is the bond angle in the following structure?

COH2

Answer

CO2H is trigonal planar, so the bond angles will be 120 only.

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Question

What is the bond angle in the following structure?

COH2

Answer

CO2H is trigonal planar, so the bond angles will be 120 only.

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Question

What is the hybridization on the sulfur molecule in the following molecule?

H2S

Answer

the sulfur has 2 atoms bonded (the H) and 2 pairs of electrons, which is a total of 4 electron domains. The hybridization of the sulfur therefore is sp3

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Question

What is the molecular shape of the following molecule?

SF6

Answer

when a central atom of a molecule has 6 electron domains coming off of it (none of which are lone pairs of electrons), it is considered octahedral

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Question

What is the molecular shape of ?

Answer

NH3 is trigonal pyramidal because it has 4 electron domains, one of them being a lone pair of electrons and the other three being H atoms. When this is arranged in a three-dimensional space, it is trigonal pyramidal in shape.

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Question

is an example of what type of molecular geometry?

Answer

SF4 has 6 electron domains coming off of it- 4 F molecules and 2 lone pairs of e–. This is an example of see-saw shape.

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Question

What is/are the approximate bond angle(s) in the following molecule?

COH2

Answer

COH2:

:O:

||

H—C—H

This is a trigonal planar molecule, which only has bond angles of 120o

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Question

What are the shapes of the following compounds:

(a) SF6

(b) XeF4

(c) NH3

(d) CH4

(e) PCl5

Answer

(a) Octahedral: six charge clouds and six atoms (b) Square planar: six charge clouds and four atoms (c) Trigonal pyramidal: four charge clouds and three atoms (d) Tetrahedral: four charge clouds and four atoms (e) Trigonal bipyramidal: ﬁve charge clouds and ﬁve atoms

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Question

What is the shape of the SO2 molecule?

Answer

The answer to this question can be determined by drawing a Lewis structure of the molecule. The S atom is central, with an O atom on each side. Adding in double bonds to each O atom and placing lone pairs on the O atoms give them each an octet, which leaves 2 more lone pairs of electrons to go on the S atom, creating a bent shape.

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Question

VSEPR theory predicts that a BF3 molecule will be which of the following shapes?

Answer

Molecules with three atoms around a central atom such as BF3 are trigonal planar because electron repulsion is minimized by positioning the three attachments toward the corners of an equilateral triangle.

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Question

Which of the following is not a characteristic of a preferred Lewis structure?

Answer

Multiple bonds, although they may be stronger, are not necessarily favored in a Lewis structure. It is dependent on the atoms involved. Thus, this is not a criterion used in determining a preferred Lewis structure.

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Question

What is the molecular geometry of the molecule?

Answer

There are three bonding electron pairs around the central atom and one non-bonding pair, for a total of 4 electron groups. They arrange spontaneously to be furthest apart according to VSEPR theory, which corresponds to when they form a trigonal pyramidal shape.

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Question

The most similar electronic geometry will be observed between which pair of compounds?

Answer

It is important to note that electronic geometry includes the orientation fo lone pairs, while molecular geometry considers only the geometry of the atoms present in the compound.

Methane, or CH4, has four hydrogen atoms bound to a central carbon, resulting in a tetrahedral geometry.

BF3 has three fluorine atoms bound to a central boron, resulting in a trigonal planar geometry.

Be(Cl)2 has two chlorine atoms bound to a central beryllium, resulting in a linear geometry.

Water, or H2O, has two hydrogen atoms bound to a central oxygen atom with two lone pairs. The molecular geometry is bent, but the electronic geometry is tetrahedral.

Ammonia, or NH3, has three hydrogens bound to a central nitrogen atom with one lone pair. The moelcular geometry is trigonal pyramidal, but the electronic geometry is tetrahedral.

Ammonia, water, and metahne all have the same electronic geometries (tetrahedral), giving us our final answer.

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Question

Rank the following compounds in order of increasing bond angle:

$CO_2$ , $CH_4$ , $SF_6$ , $NH_3$ , $BF_3$

If there are multiple bond angles in a single molecule, only consider the smaller bond angle

Answer

$CO_2$ has two bonding regions and no lone pairs around the central atom, so it has a linear geometry, so its bond angle is $180^{\circ}$ .

$CH_4$ has four bonding regions and no lone pairs around the central atom, so it has a tetrahedral geometry with bond angles of $109.5^{\circ}$ .

$SF_6$ has six bonding regions and no lone pairs around the central atom, so it has an octahedral geometry with bond angles of $90^{\circ}$ and $180^{\circ}$ . For the sake of ranking, we will only consider the smaller angle.

$NH_3$ has three bonding regions and one lone pair around the central atom, so it has a trigonal pyramidal geometry with bond angles of $107^{\circ}$ .

$BF_3$ has three bonding regions and no lone pairs around the central atom, so it has a trigonal planar geometry with bond angles of $120^{\circ}$ .

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Question

Molecule $XMe_5$ has a trigonal bipyramidal shape. What type of hybridization describes its bonds?

Answer

Trigonal bipyramidal geometries arise from the hybridization of one s orbital, three p orbitals, and one d orbital, hence the name $sp^3d$ .

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Question

Consider the following reaction, called the Sabatier reaction:

$CO_2+4H_2\rightarrow CH_4\hspace{1 mm}+2H_2O$

What are the molecular geometries of the products?

Answer

$CH_4$ has four bonding regions and no lone pairs, so it has a tetrahedral geometry. $H_2O$ has two bonding regions, but it also has two lone pairs, so it has a bent geometry.

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Question

What is the hybridization of the molecular bonds and molecular geometry of $NH_3$ ?

Answer

Nitrogen is a Group 5 element, so when it is bound to three hydrogen atoms, it will have a lone pair.

$NH_3$ has four areas of electron density (three bonds and one lone pair), so its bonds are $sp^3$ hybridized.

Because of the lone pair, $NH_3$ has a trigonal pyramidal geometry.

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Question

Consider the following reactions that lead to the production of dichloromethane, $CH_2Cl_2$ :

$CH_4+Cl_2\rightarrow CH_3Cl +HCl$

$CH_3Cl+Cl_2\rightarrow CH_2Cl_2+HCl$

What is the Cl-Cl bond angle of the product, dichloromethane?

Answer

$CH_2Cl_2$ has four bonding regions and no lone pairs, so it has a tetrahedral geometry. The bond angles between all of the bonded atoms is $109.4^{\circ}$ .

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Question

Consider the following reaction, which occurs at high temperatures with a silver catalyst:

$CH_3OH \rightarrow H_2CO + H_2$

What is the change in the geometry of the carbon atom between the reactant and the product?

Answer

In the reactant, , the carbon is bound to three hydrogens and one oxygen, and it has no lone pairs, so it has a tetrahedral geometry. In the product, , the carbon is bound to two hydrogens and one oxygen, so it must be double bonded to the oxygen in order to have a complete octet. Therefore, it has a trigonal planar geometry.

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Question

$N_{2}(g)+3H_{2}(g) \rightleftharpoons 2NH_{3}(g)$

Figure 1: Ammonia gas formation and equilibrium

What type of geometry does ammonia exhibit?

Answer

Ammonia exhibits a tetrahedral electron pair geometry. It has three bonded pairs (between nitrogen and each hydrogen), and one lone pair (on nitrogen). This combination forms a trigonal pyramidal molecular geometry.

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