C6h12o6 what type of solid

So this will be a molecular solid as well. Importante we have the element mg, so this will be an atomic solid.

Since MGI is an Adam and we look on the periodic table, we also noticed that M G is a metal, so this will be an atomic metallic solid in part e k c l. We noticed that we have positive and negative so opposite Lee charged ions bonded together, which forms in ionic bonds. So this is an ionic molecule, and so, therefore, this will form an ionic solid part. We know that courts is made up of silicon, which is one of the Adams that makes up a network solid. So courts is a network solid import.

We have an H four, which has a positive charge. We recognize that as ammonium and you know, three minus nitrate.

And so there's Air two opposite, Lee charged ions bonded together Polly Atomic ions, and so that will form in Ionic salted or teach. We just have a general sf two molecule, so that will form a molecular solid part. I organ is just an element. We know that since this is an Adam that will form an atomic solid in.

Since this is not carbon or silicon, we will not be a network solid and then organise noble gas. So it is not a metal, so we can only classify it as an atomic solid port. J Copper is an Adam Sewell Forman atomic solid, but we also noticed from the period periodic table that it is also a metal. Copper will form in atomic metallic solid. Finally, in parquet, we just have glucose, which is a molecule that will form a molecular solid.

A liquid is a nearly incompressible fluid that conforms to the shape of its container but retains a nearly constant volume independent of pressure.

As such, a liquid is one of the four fundamental states of matter the others being solid, gas and plasma. A liquid is made up of tiny vibrating particles of matter, such as atoms, held together by intermolecular bonds. Water is, by far, the most common liquid on Earth. Like a gas, a liquid is able to flow and take the shape of a container.

Most liquids resist compression, although others can be compressed. Unlike a gas, a liquid does not disperse to fill every space of a container, and maintains a fairly constant density. A distinctive property of the liquid state is surface tension, leading to wetting phenomena.

A liquid is a state of matter in which a substance changes its shape easily and takes the form of its container, and in which the substance retains a constant volume independent of pressure. As a result of this, a liquid does not maintain a definite shape, and its volume is variable. The characteristic properties of a liquid are surface tension, viscosity, and capillarity.

The liquid state has a definite volume, but it also has a definite surface. The volume is uniform throughout the whole of the liquid. Solids have a fixed shape and a definite volume, but they do not have a definite surface. The volume of a solid does not vary, but the volume of a liquid may vary. Click 'Join' if it's correct. Shania A. Chemistry 1 year ago. View Full Video Already have an account? Kevin Z.

Answer What type of solid will each of the following substances form? Discussion You must be signed in to discuss. Ionic crystals - The ionic crystal structure consists of alternating positively-charged cations and negatively-charged anions see figure below. The ions may either be monatomic or polyatomic. Generally, ionic crystals form from a combination of Group 1 or 2 metals and Group 16 or 17 nonmetals or nonmetallic polyatomic ions.

Ionic crystals are hard and brittle and have high melting points. Ionic compounds do not conduct electricity as solids, but do conduct electricity when molten or in aqueous solution. Metallic crystal - Metallic crystals consist of metal cations surrounded by a "sea" of mobile valence electrons see figure below. These electrons, also referred to as delocalized electrons, do not belong to any one atom, but are capable of moving through the entire crystal.

As a result, metals are good conductors of electricity. As seen in the table above, the melting points of metallic crystals span a wide range. Covalent network crystals - A covalent network crystal consists of atoms at the lattice points of the crystal, with each atom being covalently bonded to its nearest neighbor atoms see figure below.

The covalently bonded network is three-dimensional and contains a very large number of atoms. Network solids include diamond, quartz, many metalloids, and oxides of transition metals and metalloids. Network solids are hard and brittle, with extremely high melting and boiling points.

Being composed of atoms rather than ions, they do not conduct electricity in any state. Molecular crystals - Molecular crystals typically consist of molecules at the lattice points of the crystal, held together by relatively weak intermolecular forces see figure below. The intermolecular forces may be dispersion forces in the case of nonpolar crystals, or dipole-dipole forces in the case of polar crystals. Some molecular crystals, such as ice, have molecules held together by hydrogen bonds.

When one of the noble gases is cooled and solidified, the lattice points are individual atoms rather than molecules. In all cases, the intermolecular forces holding the particles together are far weaker than either ionic or covalent bonds. As a result, the melting and boiling points of molecular crystals are much lower.

Lacking ions or free electrons, molecular crystals are poor electrical conductors. Germanium lies in the p block just under Si, along the diagonal line of semi-metallic elements, which suggests that elemental Ge is likely to have the same structure as Si the diamond structure. Thus Ge is probably a covalent solid. Zn is a d-block element, so it is a metallic solid.

Arranging these substances in order of increasing melting points is straightforward, with one exception. We expect C 6 CH 3 6 to have the lowest melting point and Ge to have the highest melting point, with RbI somewhere in between.

The melting points of metals, however, are difficult to predict based on the models presented thus far.