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7.4: Molecular Shapes
https://chem.libretexts.org/Courses/University_of_Pittsburgh_at_Bradford/CHEM_0089_-_Concepts_of_Chemistry/07%3A_Chemical_Bonding/7.04%3A_Molecular_Shapes
The approximate shape of a molecule can be predicted from the number of electron groups and the number of surrounding atoms.
6.12: Molecular Shapes
https://chem.libretexts.org/Courses/BridgeValley_Community_and_Technical_College/Fundamentals_of_Chemistry/06%3A_Molecules_and_Compounds/6.12%3A_Molecular_Shapes
The approximate shape of a molecule can be predicted from the number of electron groups and the number of surrounding atoms.
12.8: Molecular Shapes
https://chem.libretexts.org/Courses/Los_Angeles_Trade_Technical_College/Foundations_of_Introductory_Chemistry-1/1.10%3A_Chemical_Bonds/12.8%3A_Molecular_Shapes
The approximate shape of a molecule can be predicted from the number of electron groups and the number of surrounding atoms.
9.7: Molecular Shapes
https://chem.libretexts.org/Courses/Los_Angeles_Trade_Technical_College/DMA_Chem_51_Su_19/2%3A_Beginning_Chemistry_(Ball)/09%3A_Chemical_Bonds/9.7%3A_Molecular_Shapes
The approximate shape of a molecule can be predicted from the number of electron groups and the number of surrounding atoms.
9.7: Molecular Shapes
https://chem.libretexts.org/Courses/Los_Angeles_Trade_Technical_College/DMA_Chem_51/2%3A_Beginning_Chemistry_(Ball)/09%3A_Chemical_Bonds/9.7%3A_Molecular_Shapes
The approximate shape of a molecule can be predicted from the number of electron groups and the number of surrounding atoms.
9.7: Molecular Shapes
https://chem.libretexts.org/Bookshelves/Introductory_Chemistry/Beginning_Chemistry_(Ball)/09%3A_Chemical_Bonds/9.07%3A_Molecular_Shapes
The approximate shape of a molecule can be predicted from the number of electron groups and the number of surrounding atoms.
12.T: Character Tables
https://chem.libretexts.org/Bookshelves/Physical_and_Theoretical_Chemistry_Textbook_Maps/Physical_Chemistry_(LibreTexts)/12%3A_Group_Theory_-_The_Exploitation_of_Symmetry/12.T%3A_Character_Tables
This page discusses classification groups in symmetry, including Nonaxial Groups (e.g., $C_1$ , $C_s$ , $C_i$ ) and Cyclic $C_n$ Groups (e.g., $C_2$ to $C_7$ ). It outlines molecular point gro...This page discusses classification groups in symmetry, including Nonaxial Groups (e.g., $C_1$ , $C_s$ , $C_i$ ) and Cyclic $C_n$ Groups (e.g., $C_2$ to $C_7$ ). It outlines molecular point groups $C_{2h}$ , $C_{3h}$ , $D_{nh}$ , and antiprismatic $D_{nd}$ groups, detailing symmetry operations, character tables, and irreducible representations (e.g., $A_g$ , $B_g$ ).
9.6 Molecular Shapes
https://chem.libretexts.org/Courses/Los_Angeles_Trade_Technical_College/Hybrid_Chem_51_v1/10%3A_Chemical_Bonds/9.6_Molecular_Shapes
The approximate shape of a molecule can be predicted from the number of electron groups and the number of surrounding atoms.
12.8: Molecular Shapes
https://chem.libretexts.org/Courses/Los_Angeles_Trade_Technical_College/Foundations_of_Introductory_College_Chemistry/13%3A_Chemical_Bonds/12.8%3A_Molecular_Shapes
The approximate shape of a molecule can be predicted from the number of electron groups and the number of surrounding atoms.
9.6: Molecular Shapes
https://chem.libretexts.org/Courses/Los_Angeles_Trade_Technical_College/LATTC_Hybrid_Chem_51/09%3A_Chemical_Bonds/9.6%3A_Molecular_Shapes
The approximate shape of a molecule can be predicted from the number of electron groups and the number of surrounding atoms.
Geometry of Complex Ions
https://chem.libretexts.org/Bookshelves/Inorganic_Chemistry/Supplemental_Modules_and_Websites_(Inorganic_Chemistry)/Coordination_Chemistry/Complex_Ion_Chemistry/Geometry_of_Complex_Ions
This page describes the shapes of some common complex metal ions. It goes on to look at some simple examples of stereoisomerism (geometric and optical) in complex ions

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