An element crystallises in the foc lattice having edge length 400 pm. Calculate the maximum diameter which can be placed in interstitial sites with out disturbing the structure.

An element crystallises in the fee lattice having edge length 400 pm. Calculate the maximum diameter which can be placed in interstitial sites with out disturbing the structure.

A metal crystallises in body centred cubic lattice with edge length of the cube 287 pm. Calculate the radius of metal atom.

A given metal crystallises out with a cubic structure having edge length of 360 pm. If there are four metal atoms in one unit cell, what is the radius of one atom ?

An element crystallises in a structure having a f.c.c unit cell of an edge 200 pm. Calculate the density of element, if 20 gm the element contains 2.4 xx 10^(23) atoms.

NH_(4) X1 crystallises in bee lattice with edge length 383 pm. If the radius of NH_(4)^(+) ion is 154 pm ,calculate the radius of halide (X^(-) ) .

Density of a unit cell is represented as rho=("Effectiveno.ofatom(s)x Mass of a unit cell")/("Volume of a unit cell")=(Z.M.)/(N_(A).a^(3)) Where, mass of unit cell = mass of effective no. of atom(s) or ion(s). M = At. wt./formula wt. N_(A)="Avogadro’s no. "rArr 6.023xx10^(23) a = edge length of unit cell An element crystallizes in a structure having foc unit cell of an edge 200 pm. Calculate the density,if 100g this element contains 12 xx 10^(23) atoms :

If an element having atomic number 96 crystallises in cubic lattice with a density of 10.3gcm^(-3) and the edge length of 314 pm then, the structure of solid is

An element has a body centered cubic structure with a unit cell edge length of 400 pm. Atomic mass of an element is 24 gmol^(-1) What is the density of the element? (N_A = 6 times 10^23 mol^-1)

Silicon crystallises in foc lattice, a single crystal of high purity like diamond. Gram atomic weight of silicon is 28 g mol^(-) . Edge length of unit cell is 0.543nm. Calculate the number of silicon atoms per unit cell and density of unit cell.

For a spontaneous reaction, the free energy change must be negative. DeltaG=DeltaH-TDeltaS is the enthalpy change during the reaction. T is absolute temperature, and AS is the change in entropy during the reaction. Consider a reaction such as the formation ofan oxide . M+O_(2) MO Dloxygen is used wp in the course of this reaction. Gases have a more random structure (less ordered) than liquid or solids consequently gases have a higher entropy than liquids and solids, in this reaction (entropy or randomness) decreases, hence is negative. Thus, the temperature is raised the DeltaS becomes more negative. Since, TDeltaS is subtracted in the equation, then SG becomes less negative. Thus, the free energy changes increases with the increase in temperature. The free energy changes that occur when one mole of common reactant in this case dioxygen) is we may e plotted graphically against temperature for a number of reactions of metals to their oxides. The following plot is called an Ellingham diagram for metal oxide. Understanding of Ellingham diagram is extremely important for the efficient extraction of metals. Which of the following elements can be prepared by heating the oxide above 400^(@)C ?