Molecular geometry is the name of the geometric shape used to describe the shape of a molecule. The five molecular geometries are linear, trigonal planar, bent, tetrahedral, trigonal pyramidal, and seesaw.
You cannot. Different ions have different molecular masses.
A spectrum is a function of the light source. A gas will absorb / emit light based on its molecular bonds, and different gases have different bonds.
There are a number of different things in paint, so coming up with a molecular weight isn't possible. The solvents and dryers are blended with all kinds of pigments from as almost as many sources as their are colors. That's thousands of different chemicals in the pigments alone.
C2H6 (ethane) is neither a mixture nor an element. It is a molecular compound since it contains different atoms but is not mixed with other compounds.
I think the word you're looking for is osmosis. Water with different ionic or molecular concentrations will move toward equilibrium.
linear
Trygonal pyramid
Five and six coordinate geometries are special because of the number of valence electrons. Five coordinate geometries have ten valence electrons while six coordinate geometries have six.
Linear
Linear
Double bods count as one pair, and it only shows one pair in the molecular shape
Lone electron pairs give the geometry a triangular base.
Ethylene, or C2H4 has two trigonal planar type molecular geometries and its center is tetrahedral. Also, the angular geometry of the H-C=C bond in ethylene is 121.3 degrees.
The location in three-dimensional space of the nucleus of each atom in a molecule defines the molecular shape or molecular geometry. Molecular shapes are important in determining macroscopic properties such as melting and boiling points, and in predicting the ways in which one molecule can react with another. A number of experimental methods are available for finding molecular geometries, but we will not describe them here. Instead we will concentrate on several rules based on Lewis diagrams which will allow you to predict molecular shapes.To provide specific cases which illustrate these rules, "ball-and stick" models for several different types of molecular geometries are shown in Table 1. The atoms (spheres) in each ball-and-stick model are held together by bonds (sticks). These electron-pair bonds determine the positions of the atoms and hence the molecular geometry.
Electrons. The areas in which we are likely to find electrons around the atom we call electron density. This is valuable in determining stuff like molecular geometries and how atoms chemically interact with eachother.
Objet Geometries was created in 1999.
Lone electron pairs give the geometry a triangular base, while double bonds make the molecular geometry bent or angular.