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5.1.3: Molecular orbitals from d orbitals
https://chem.libretexts.org/Courses/University_of_California_Davis/Chem_124A%3A_Fundamentals_of_Inorganic_Chemistry/05%3A_Molecular_Orbitals/5.01%3A_Formation_of_Molecular_Orbitals_from_Atomic_Orbitals/5.1.03%3A_Molecular_orbitals_from_d_orbitals
An example of a $\pi$ bond between two $d$ orbitals is that formed by two $d_{xz}$ orbitals along the $z$ axis (shown in Figure $\PageIndex{3}$ ). $d$ orbitals can also form $\pi$ bonds u...An example of a $\pi$ bond between two $d$ orbitals is that formed by two $d_{xz}$ orbitals along the $z$ axis (shown in Figure $\PageIndex{3}$ ). $d$ orbitals can also form $\pi$ bonds using $p$ orbitals with compatible symmetry, as shown in Figure $\PageIndex{3}$ . For example, when two atoms bond along the $z$ axis, the $d_{xy}$ orbitals and the two $d_{x^2-y^2}$ orbitals can form $\delta$ bonds (Figure $\PageIndex{4}$ ).
8.2.2: Predicting UV-visible Absorption
https://chem.libretexts.org/Courses/Kutztown_University_of_Pennsylvania/CHM_320%3A_Advanced_Inorganic_Chemistry_textbook/08%3A_LFT_for_Other_Geometries___Spectroscopic_Properties/8.02%3A_Absorption_Spectra_and_Magnetic_Properties/8.2.02%3A_Predicting_UV-visible_Absorption
If the the metal is bound to ligands that are $\pi$ -acceptors, electrons from the MO's that are mostly metal in character can become excited to higher-energy orbitals that are mostly ligand in chara...If the the metal is bound to ligands that are $\pi$ -acceptors, electrons from the MO's that are mostly metal in character can become excited to higher-energy orbitals that are mostly ligand in character. Right: MLCT transitions are possible with $\pi$ -acceptor ligands when electrons from MOs that are mostly metal in character are excited to orbitals that are mostly ligand in character (the $\pi^*$ orbitals from ligands).
2.2.1: Particle in a Box
https://chem.libretexts.org/Courses/Tennessee_State_University/Inorganic_Chemistry_(CHEM_5000_4200)/01%3A_Map-_Inorganic_Chemistry-I_(LibreTexts)/02%3A_Atomic_Structure/2.02%3A_The_Schrodinger_equation_particle_in_a_box_and_atomic_wavefunctions/2.2.01%3A_Particle_in_a_Box
The particle in the box is a model that can illustrate how a wave equation works. Although it does not represent a real situation, when we limit our model to just one dimention (the x-dimention, for i...The particle in the box is a model that can illustrate how a wave equation works. Although it does not represent a real situation, when we limit our model to just one dimention (the x-dimention, for instance) the Schrödinger equation becomes significantly simplified. Although it is a bit of nonsense, it is quite useful for gaining an understanding of the Schrödinger equation.
Making Soap from Olive Oil
https://chem.libretexts.org/Courses/Saint_Marys_College_Notre_Dame_IN/CHEM_118_(Under_Construction)/CHEM_118_Laboratory/Making_Soap_from_Olive_Oil
Pre-Lab Assignment: Watch the pre-lab video below (or click here). Read the Saponification Lab Handout. Write the procedure in your notebook. Take the pre-lab quiz.
1.1.2: Inorganic vs Organic Chemistry
https://chem.libretexts.org/Courses/Earlham_College/CHEM_361%3A_Inorganic_Chemistry_(Watson)/01%3A_Intro_Review_and_Effective_Nuclear_Charge/1.01%3A_Introduction_to_Inorganic_Chemistry/1.1.02%3A_Inorganic_vs_Organic_Chemistry
The division between the fields of Inorganic and Organic chemistry has become blurred. For example, let's look at one of the major classes of catalysts used for organic synthesis reactions; organometa...The division between the fields of Inorganic and Organic chemistry has become blurred. For example, let's look at one of the major classes of catalysts used for organic synthesis reactions; organometalic catalysts. Organometallic catalysts like these, and all organometallic compounds, contain metals that are bonded to carbon or carbon-containing molecules. So, are they "inorganic" because they contain metals, or "organic" because they contain carbon?
CHEM 431 Readings
https://chem.libretexts.org/Courses/Saint_Marys_College_Notre_Dame_IN/CHEM_431%3A_Inorganic_Chemistry_(Haas)/CHEM_431_Readings
CHEM 431: Inorganic Chemistry Fall 2020: Dr. Kathryn Haas Home ● Readings ● Course Info & Tools
3.2.4: Ligand Close Packing
https://chem.libretexts.org/Courses/Kutztown_University_of_Pennsylvania/CHM_320%3A_Advanced_Inorganic_Chemistry_textbook/03%3A_Simple_Bonding_Theory/3.02%3A_Valence_Shell_Electron-Pair_Repulsion/3.2.04%3A_Ligand_Close_Packing
Ligand Close Packing (LCP) theory is complimentary to VSEPR, except that LCP focuses on repulsions between pendant atoms ("outer" atoms that are not directly bonded to one another), rather than focusi...Ligand Close Packing (LCP) theory is complimentary to VSEPR, except that LCP focuses on repulsions between pendant atoms ("outer" atoms that are not directly bonded to one another), rather than focusing on the chemical environment around the central atom in a molecule. Both LCP and the VSEPR models were developed by Robert Gillespie.
13.2: Predicting UV-visible Absorption
https://chem.libretexts.org/Courses/University_of_Florida/CHM2047%3A_One-Semester_General_Chemistry_(Kleiman)/08%3A_8_Coordination_Chemistry/13%3A_Absorption_Spectra_and_Magnetic_Properties/13.02%3A_Predicting_UV-visible_Absorption
If the the metal is bound to ligands that are $\pi$ -acceptors, electrons from the MO's that are mostly metal in character can become excited to higher-energy orbitals that are mostly ligand in chara...If the the metal is bound to ligands that are $\pi$ -acceptors, electrons from the MO's that are mostly metal in character can become excited to higher-energy orbitals that are mostly ligand in character. Right: MLCT transitions are possible with $\pi$ -acceptor ligands when electrons from MOs that are mostly metal in character are excited to orbitals that are mostly ligand in character (the $\pi^*$ orbitals from ligands).
2.4.1: Particle in a Box
https://chem.libretexts.org/Courses/Barry_University/CHE360%3A_Inorganic_Chemistry/02%3A_Atomic_Structure/2.04%3A_The_Schrodinger_equation_particle_in_a_box_and_atomic_wavefunctions/2.4.01%3A_Particle_in_a_Box
The particle in the box is a model that can illustrate how a wave equation works. Although it does not represent a real situation, when we limit our model to just one dimention (the x-dimention, for i...The particle in the box is a model that can illustrate how a wave equation works. Although it does not represent a real situation, when we limit our model to just one dimention (the x-dimention, for instance) the Schrödinger equation becomes significantly simplified. Although it is a bit of nonsense, it is quite useful for gaining an understanding of the Schrödinger equation.
WiSEWiki Project
https://chem.libretexts.org/Courses/Saint_Marys_College_Notre_Dame_IN/CHEM_342%3A_Bio-inorganic_Chemistry/Start_Here/Three_Major_Projects/WiSEWiki_Project
Through the Sophia program, you have the opportunity to discuss topics with your Science and Engineering faculty and peers which are important to your success, but are not part of a traditional chemis...Through the Sophia program, you have the opportunity to discuss topics with your Science and Engineering faculty and peers which are important to your success, but are not part of a traditional chemistry curriculum. As a significant part of this project, you will research a scientist who represents a group that is underrepresented in science, and you will contribute to a Wikipedia article about them.
6.20: Ionic Compounds and Molecular Orbitals
https://chem.libretexts.org/Courses/Barry_University/CHE360%3A_Inorganic_Chemistry/06%3A_Molecular_Orbitals/6.20%3A_Ionic_Compounds_and_Molecular_Orbitals
In the middle of the spectrum are the cases of polar covalent bonds (e.g., heteronuclear diatomics), in which atomic orbitals of unequal energies contribute unequally to molecular orbitals, resulting ...In the middle of the spectrum are the cases of polar covalent bonds (e.g., heteronuclear diatomics), in which atomic orbitals of unequal energies contribute unequally to molecular orbitals, resulting in uneven distribution of electron density across the molecule. The chlorine $3s$ and $3p_z$ orbitals have compatible symmetry, yet only the $3p_z$ orbital (-13.8 eV) is close enough in energy to interact with the Na $3s$ ; still the energy difference is large enough to make bonding weak.

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