Deck 9: Molecular Geometry: Shape Determines Function

A) linear
B) trigonal planar
C) tetrahedral
D) trigonal bipyramidal
E) octahedral

A) CF₄
B) NF₃
C) F₂O
D) NF₂^-
E) NH₃

A) 90^o
B) 180^o
C) 109^o
D) 120^o
E) 105^o

A) the same as the H-O-H angle in water.
B) exactly 109.5 $\degree$ .
C) greater than 109.5 $\degree$ .
D) less than 109.5°.
E) 120°.

A) linear
B) trigonal planar
C) tetrahedral
D) trigonal bipyramidal
E) octahedral

A) bonding pair-bonding pair < lone pair-bonding pair < lone pair-lone pair
B) bonding pair-bonding pair < lone pair-lone pair < lone pair-bonding pair
C) lone pair-lone pair < lone pair-bonding pair < bonding pair-bonding pair
D) lone pair-lone pair < bonding pair-bonding pair < lone pair-bonding pair
E) lone pair-bonding pair < bonding pair-bonding pair < lone pair-lone pair

A) The molecular shape or geometry is determined by the positions of the atoms in the molecule.
B) In VSEPR theory, the shape or geometry of a molecule is determined by electron-electron repulsion.
C) The steric number of a central atom is the sum of the number of bonds around the atom.
D) The steric number has five values from 2 to 6.
E) The electron-pair geometry is determined by the positions of the bonds and lone pairs in a molecule.

A) The ss geometry has fewer lone-pair bonding-pair interactions at 90^o.
B) The ss geometry has fewer lone-pair bonding pair interactions at 120^o.
C) The ss geometry has fewer bonding-pair bonding-pair interactions at 120^o.
D) The ss geometry has fewer bonding-pair bonding-pair interactions at 90^o.
E) The ss geometry has fewer lone-pair lone-pair interactions at 90^o.

A) The electron-pair geometry identifies the relative positions of the bonding regions of electrons and the lone pairs of electrons around a central atom in a molecule.
B) The molecular geometry identifies the relative positions of the atoms around a central atom in a molecule.
C) If there are no lone pairs, then the electron-pair geometry and the molecular geometry are the same.
D) The molecular geometry differs from the electron-pair geometry when the number of atoms around the central atom is smaller than the number of regions of electron density.
E) Statements A-D are all correct.

A) VSEPR is an acronym for valence-shell electron-pair repulsion.
B) In VSEPR theory, the shape or geometry of a molecule is determined by electron-electron repulsion.
C) The steric number of a central atom is the sum of the number of bonds and lone pairs around the atom.
D) The steric number has five values from 2 to 6.
E) The molecular shape or geometry always is the same as the electron-pair geometry.

A) electron-proton attractive forces.
B) electron-electron attractive forces.
C) electron-electron repulsive forces.
D) proton-proton repulsive forces.
E) electron-nucleus attractive forces.

A) linear
B) trigonal planar
C) tetrahedral
D) trigonal bipyramidal
E) octahedral

A) H-C -H in CH₄
B) H-C -H in C₂H₄
C) H-C -H in H₂CO
D) H-C -C in C₂H₂
E) H-C -O in H₂CO

A) SO₂
B) N₂O
C) HCN
D) CO₂
E) BeH₂

A) The molecular shape or geometry can differ from the electron-pair geometry.
B) In VSEPR theory, the shape or geometry of a molecule is determined by electron-electron repulsion.
C) The steric number of a central atom is the sum of the number of bonds and lone pairs around the atom.
D) The steric number has five values from 2 to 6.
E) Statements A-D are all correct.

A) linear
B) trigonal planar
C) tetrahedral
D) trigonal bipyramidal
E) octahedral

A) Physical properties of a substance are not affected by the shape of the molecules.
B) The shape of a molecule refers to the three-dimensional arrangement of the atoms in space.
C) Solubility of a substance in a solvent is affected by the shape of the molecules.
D) Taste and aroma of a substance are affected by the shape of the molecules.
E) Biological activity and chemical reactivity of a substance are affected by the shape of the molecules.

A) linear
B) trigonal planar
C) tetrahedral
D) trigonal bipyramidal
E) octahedral

A) linear
B) trigonal planar
C) tetrahedral
D) trigonal bipyramidal
E) octahedral

A) have polar bonds.
B) are polar.
C) are nonpolar.
D) cannot vibrate.
E) are liquids.

A) NH₃
B) PCl₅
C) KrF₄
D) CH₃COOH
E) SiH₄

A) pentagonal
B) tetrahedral
C) trigonal bipyramidal
D) trigonal planar
E) square pyramidal

A) KrF₄
B) COCl₂
C) SeO₃^2-
D) NH₄⁺
E) O₃

A) H₂O
B) HCN
C) ICl₃
D) OCS
E) CO₂

A) H₂O
B) H₂S
C) ICl₃
D) I₃^-
E) SO₂

A) square planar
B) square pyramidal
C) trigonal pyramidal
D) tetrahedral
E) seesaw

A) linear
B) bent
C) tetrahedral
D) trigonal pyramidal
E) trigonal planar

A) tetrahedral
B) square pyramidal
C) seesaw
D) square planar
E) T-shaped

A) NCl₃
B) PCl₃
C) SbCl₃
D) ICl₃
E) COCl₂

A) 90^o
B) 180^o
C) 109^o
D) 120^o
E) 105^o

A) carbon-oxygen
B) carbon-sulfur
C) carbon-nitrogen
D) carbon-hydrogen
E) carbon-bromine

A) H-C
B) H-N
C) H-O
D) H-Cl
E) H-F

A) carbon-oxygen
B) carbon-sulfur
C) carbon-nitrogen
D) carbon-hydrogen
E) carbon-chlorine

A) linear
B) bent
C) trigonal bipyramidal
D) tetrahedral
E) trigonal pyramidal

A) SiF₄
B) KrF₄
C) SF₄
D) C₂H₄
E) C₂H₂

A) ICl₃
B) BrF₅
C) PCl₅
D) PH₃
E) SiF₄

A) ICl₃
B) BrF₅
C) PCl₅
D) PH₃
E) SiF₄

A) SCN^-
B) NO₂^-
C) SO₃^2-
D) NH₄⁺
E) SO₂^2-

A) O₃
B) H₂O
C) SO₂
D) I₃^-
E) S₃

A) sp²
B) sp³
C) sp³d
D) sp
E) sp³d²

A) PCl₅ and SiCl₄
B) POCl₃, SO₂Cl₂, and SO₃
C) POCl₃ and SO₂Cl₂
D) PCl₅, POCl₃, SOCl₂, SO₃, and SiCl₄
E) PCl₅, SF₆, SO₃, and SiCl₄

A) CF₂Cl₂
B) CF₃Cl
C) CF₄
D) CFCl₃
E) CHFCl₂

A) I
B) II
C) III
D) Only two of these are correct statements.
E) All three are correct statements.

A) SO₂
B) OCS
C) CS₂
D) NH₃
E) CO₂

A) SO₂
B) OCS
C) ICl₃
D) I₃^-
E) C₂H₂

A) sp³
B) sp³d
C) sp³d²
D) sp
E) sp²

A) sp³, sp³, sp²
B) sp³, sp³, sp³
C) sp³, sp², sp³
D) sp², sp², sp³
E) sp³, sp², sp²

A)
B)
C)
D)

A) CH₂Cl₂
B) CH₃Cl
C) CHCl₃
D) CCl₄
E) CH₄

A) C₂H₂
B) H₂CO
C) H₂S
D) C₂H₄
E) C₂H₂Cl₂

A) C₆H₅F (fluorobenzene)
B) C₆H₅Br (bromobenzene)
C) C₆H₅Cl (chlorobenzene)
D) C₆H₅I (iodobenzene)
E) C₆H₅CH₃ (methylbenzene)

A) sp³
B) sp³d
C) sp³d²
D) sp²
E) sp

A) sp
B) sp²
C) sp³d
D) sp³d²
E) sp³

A) CF₄
B) SiH₄
C) CHCl₃
D) CS₂
E) CO₂

A) NH₃
B) PH₃
C) AsH₃
D) SbH₃
E) BiH₃

A) Valence bond theory describes a bond as the overlap of atomic orbitals between two atoms.
B) Enhanced electron density between two positively charged nuclei attracts the nuclei together and forms the bond.
C) Hybridization of atomic orbitals is necessary to account for the molecular geometry.
D) In valence bond theory, hybridization determines the molecular shape or geometry.
E) Statements A-D are all correct.

A)
B)
C)
D)

A) C₂H₂
B) H₂CO
C) CH₃Cl
D) C₂H₄
E) C₂H₂Cl₂

A) A second resonance structure is needed to describe benzene.
B) All the $\pi$ bonds originate from p atomic orbitals.
C) Benzene does not have a dipole moment.
D) The carbon atomic orbitals are sp² hybridized.
E) Benzene has both long and short carbon-carbon bonds.

A) CH₃CH₂OH
B) CH₃OH
C) C₂H₄
D) CH₃OCH₃
E) C₂H₂

A) A sigma bond has the region of high electron density aligned along the bond axis, which is the line connecting the two atoms.
B) A pi bond has regions of high electron density lying above and below the bond axis, which is the line connecting the two atoms.
C) A pi bond commonly is formed from the overlap of two unhybridized atomic 2p orbitals.
D) In the trigonal planar geometry, the sigma bonds are formed from the overlap of an sp² hybridized orbital with another orbital.
E) The molecule acetylene, C₂H₂, has five sigma bonds and one pi bond.

A) sp²
B) sp³
C) sp³d
D) sp
E) sp³d²

A) A pi bond is twice as strong as a sigma bond.
B) A pi bond has cylindrical symmetry about the internuclear axis.
C) A double bond, as in ethylene, consists of a pi bond and a sigma bond.
D) A pi bond, as in ethylene, is described by the overlap of hybridized atomic orbitals.
E) Hydrogen forms pi bonds when it bonds to other atoms.

A) The region of high electron density lies along the bond axis connecting the nuclei of the two atoms.
B) The bond can be described by the overlap of sp hybrid orbitals from each atom.
C) The bond can be described by the overlap of sp² hybrid orbitals from each atom.
D) The bond can be described by the overlap of p atomic orbitals from each atom.
E) The bond can be described by the overlap of a p atomic orbital from one atom with an sp² hybrid orbital from the other atom.

A) trigonal bipyramid and sp.
B) trigonal planar and sp³.
C) trigonal planar and sp².
D) tetrahedral and sp³.
E) linear and sp.

A) trigonal planar; sp
B) tetrahedral; sp³
C) tetrahedral; sp²
D) seesaw; sp²
E) seesaw; sp³

A) The region of electron density lies along the bond axis connecting the nuclei of the two atoms.
B) The bond can be described by the overlap of sp hybrid orbitals from each atom.
C) The bond can be described by the overlap of sp² hybrid orbitals from each atom.
D) The bond can be described by the overlap of sp³d hybrid orbitals from each atom.
E) The bond can be described by the overlap of an sp² hybrid orbital from one atom with an sp³ hybrid orbital from the other atom.

A) sp²
B) sp³d²
C) sp³d
D) sp³
E) sp

A) A sigma bond has the region of high electron density aligned along the bond axis, which is the line connecting the two atoms.
B) A pi bond has regions of high electron density lying above and below the bond axis, which is the line connecting the two atoms.
C) A pi bond commonly is formed from the overlap of two unhybridized atomic 2p orbitals.
D) In the trigonal planar geometry, the sigma bonds are formed from the overlap of an sp² hybridized orbital with another orbital.
E) Statements A-D are all correct.

A) trigonal planar; sp
B) tetrahedral; sp³
C) tetrahedral; sp²
D) seesaw; sp²
E) bent; sp³

A) sp²
B) sp³
C) sp³d
D) sp
E) sp³d²

A) sp; sp
B) sp; sp²
C) sp²; sp³
D) sp³; sp²
E) sp²; sp

A) sp; sp
B) sp; sp²
C) sp²; sp³
D) sp³; sp²
E) sp²; sp

A) Regions of high electron density lie above and below the bond axis connecting the nuclei of the two atoms.
B) The bond can be described by the overlap of sp hybrid orbitals from each atom.
C) The bond can be described by the overlap of sp² hybrid orbitals from each atom.
D) The bond can be described by the overlap of sp³ hybrid orbitals from each atom.
E) The bond can be described by the overlap of a p atomic orbital from one atom with an sp² hybrid orbital from the other atom.

A) trigonal planar; sp
B) tetrahedral; sp³
C) tetrahedral; sp²
D) seesaw; sp²
E) seesaw; sp³

A) trigonal bipyramid and sp.
B) trigonal planar and sp³.
C) trigonal planar and sp².
D) tetrahedral and sp³.
E) linear and sp.

A) IF₆⁺
B) SiF₄
C) BrF₅
D) SbF₅
E) XeF₄

A) square planar and sp.
B) trigonal planar and sp.
C) tetrahedral and sp³.
D) trigonal planar and sp².
E) T-shaped and sp².

A) sp; sp
B) sp; sp²
C) sp²; sp³
D) sp³; sp²
E) sp³; sp