In structure (a), four pairs of electrons give ______ electron geometry. The lone pair would cause lone pair-bonded pair repulsions and would have ______molecular geometry.

In structure (b), five pairs of electrons give ______electron geometry. The lone pair occupies an equatorial position to minimize lone pair-bonded pair repulsions, and the molecule would have  ______ molecular geometry.

In structure (c), six pairs of electrons give  ______ electron geometry. The two lone pairs would occupy opposite positions to minimize lone pair-lone pair repulsions, and the molecule would have  ______ molecular geometry.

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The image consists of three 3D molecular structure diagrams labeled as (a), (b), and (c). These diagrams show molecular geometries with various arrangements of atoms and lone pairs: (a) **Diagram (a):** The molecule features a central atom (likely in gray) with four surrounding green atoms arranged in a tetrahedral geometry. Above the central atom, a pair of light blue lobes represents a lone pair of electrons. (b) **Diagram (b):** Similar to (a), this molecule has a central atom with four surrounding green atoms. The structure includes a lone pair of electrons represented by a larger light blue lobe, suggesting a trigonal pyramidal shape due to the lone pair repulsion. (c) **Diagram (c):** This molecule also has a central atom with four surrounding green atoms. Three lobes of light blue, depicting three lone pairs, are present, indicating a T-shaped geometry due to the influence of the lone pairs on the overall molecular shape. Each diagram highlights the effect of lone pairs on molecular geometry, with the light blue lobes showing electron pairs that are not involved in bonding but influence the spatial arrangement of the bonded atoms.

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### Molecular Geometry Types 1. **Bent**: This shape occurs when there are two bonded pairs and one or two lone pairs on the central atom, creating a bent structure due to electron pair repulsion. 2. **Trigonal Bipyramidal**: Consists of a central atom with five bonded atoms. The geometry is characterized by three atoms in a plane with 120° angles, and two additional atoms above and below the plane. 3. **Octahedral**: Features a central atom bonded to six atoms located at the corners of an octahedron. All bond angles are 90°. 4. **Trigonal Planar**: Involves three atoms bonded in a flat triangular shape around the central atom, with 120° angles between them. 5. **Square Planar**: A central atom bonded to four atoms at the corners of a square plane. The angles between bonds are 90°, common in some transition metal complexes. 6. **Trigonal Pyramidal**: Resembles a pyramid with a triangular base. A central atom is bonded to three atoms, and one lone pair is typically on the central atom. 7. **Tetrahedral**: A central atom bonded to four other atoms, with bond angles of approximately 109.5°. 8. **Seesaw**: A variation of the trigonal bipyramidal arrangement where one equatorial position is occupied by a lone pair, causing a seesaw shape. 9. **Linear**: The simplest geometry with the central atom bonded to two other atoms in a straight line, with a bond angle of 180°. Each geometric arrangement results from the repulsion between electron regions (bonding and lone pairs), striving to minimize repulsion and maximize distance apart for stability.