This site can explain everything pertaining to the strengths of ceramics, first an excerpt then the site:
Abstract The key features of the processes underlying the failure of ceramics are considered for a wide temperature range. The brittleness and high-temperature plasticity of ceramics are correlated with their crystal chemistry. The general issues related to the strength of ceramics are treated in terms of synergetics, which deals with the spatiotemporal ordering and self-organization in nonequilibrium systems. The strength of ceramics is shown to be governed by its structure on different scales-from atomic to macroscopic. The conclusion is drawn that, in the strict sense, strength is not a property of the material; rather it characterizes its quality.
* http://www.springerlink.com/content/lf6yr4pjf5wmh425/
An empirical formula is a brutto formula; a molecular formula explain the structure of a molecule.
Q 3. How did the scientists explain the relationship between the colors observed and the structure of the atom?
why is the atomic symbol and the molecular formula of copper the same?its because of the formula being for copper its the same as the... idk how to explain
Molecular orbital theory predicts that ground state diatomic oxygen has two unpaired electrons (it is a diradical) which occupy its pi orbitals. These unpaired electrons produce a magnetic moment and are responsible for the paramagnetic property of diatomic oxygen.
One of the C2H2Cl2 structures is non-polar because the chlorine atoms are symmetrically arranged on opposite sides of the molecule, canceling out any dipole moments. The other two structures are molecular dipoles because the chlorine atoms in these arrangements are not symmetrically placed, creating an overall dipole moment for the molecule.
An empirical formula is a brutto formula; a molecular formula explain the structure of a molecule.
Chemists explain differences in properties or behavior by looking at the molecular structure of substances. Variation in molecular structure can lead to differences in physical, chemical, and biological properties. By understanding how atoms are arranged and interact within molecules, chemists can explain why substances exhibit different characteristics.
The HF MO diagram is important for understanding how the bonding occurs in the HF molecule. It shows how the atomic orbitals of hydrogen and fluorine combine to form molecular orbitals, which determine the bonding and structure of the molecule. This diagram helps explain the strength and nature of the bond between hydrogen and fluorine in HF.
The co molecular orbital diagram is important for understanding how carbon monoxide forms bonds and its electronic structure. It shows how the orbitals of carbon and oxygen atoms combine to create new molecular orbitals, which determine the strength and nature of the bond between the two atoms. This diagram helps explain the unique properties of carbon monoxide, such as its stability and ability to bind strongly to metal ions.
Look at some bricks or bathroom tiles, or at the porcelain enamel around the burner plates of a stove. You'll probably see small breaks in their surfaces. These breaks are evidence of one disadvantage of some ceramics: they are so rigid that they crack. One advantage is that they have strength. These ceramics contain silicon or aluminum, which can form small, rigid structures that bond together when water is removed.
The N2O resonance structure helps explain the molecular properties of nitrous oxide by showing how the electrons are distributed within the molecule. This understanding is important because it affects the molecule's stability, reactivity, and overall behavior in chemical reactions.
Homotropic molecules have chemically identical H's. As in the molecule can be cut in half and the hydrogens are all of the same molecular strength.
Drawing a protein structure involves representing the arrangement of atoms in a protein molecule. This is important in molecular biology because it helps scientists understand the protein's function, interactions, and role in biological processes. By visualizing the structure, researchers can study how proteins work and develop new drugs or treatments targeting specific proteins.
The molecular orbital diagram is important for understanding the electronic structure of a molecule because it shows how atomic orbitals combine to form molecular orbitals. In the case of the CN- ion, the diagram helps to explain the bonding and antibonding interactions between the carbon and nitrogen atoms, as well as the overall stability of the molecule.
The XeF4 molecular orbital diagram is important for understanding how xenon tetrafluoride bonds and its electronic structure. It shows how the atomic orbitals of xenon and fluorine atoms combine to form molecular orbitals, which determine the bonding and stability of the compound. This diagram helps explain the unique properties of XeF4 and how its electrons are distributed in the molecule.
If you use balls to explain the structure of a molecule you have made a model.
The n2 MO diagram in molecular orbital theory is significant because it helps to explain the bonding and electronic structure of molecules. It shows how atomic orbitals combine to form molecular orbitals, which determine the stability and properties of the molecule. This diagram is crucial for understanding the behavior of electrons in chemical reactions and predicting the reactivity of molecules.