NEET Chemistry The Solid State MCQs

A hypothetical crystalline substance exhibits a unique crystal structure with the following unit cell dimensions: $a = b

eq c$,$\alpha = \beta = 90^\circ$, and$\gamma = 120^\circ$. This substance most likely belongs to which crystal system?

In a complex metal oxide crystallizing in the cubic system, the metal cations occupy the corners and face centers, while oxide anions occupy all the tetrahedral voids. What is the simplest formula of this compound?

A crystal system has $a

eq b

eq c$and$\alpha = \beta = \gamma

eq 90^\circ$. What is the Bravais lattice associated with this crystal system?

A solid 'X' dissolves readily in benzene but not in water. It does not conduct electricity in either solid or molten state. Upon heating, it undergoes sublimation. What is the most likely type of solid for 'X'?

A crystalline solid is hard, brittle, has a high melting point, and conducts electricity only in the molten state. Which type of solid is it most likely to be?

A hypothetical ionic compound MX$_2$ crystallizes in a fluorite structure. If the radius of M$^{2+}$ is 72 pm, what is the minimum radius of X$^−$ that would allow for this structure, considering the radius ratio for a coordination number of 8?

An ionic compound AB crystallizes in a rock salt structure with an edge length of 5.6 Å. If the radius of B$^−$ is 1.81 Å, what is the radius of A$^+$?

Lithium iodide (LiI) has a rock salt structure. Given that the ionic radii of Li$^+$ and I$^−$ are 76 pm and 220 pm respectively, estimate the density of LiI (in g/cm$^3$). [Atomic masses: Li = 6.94 g/mol, I = 126.9 g/mol; Avogadro's number = $6.022 imes 10^{23}$]

A hypothetical metallic element crystallizes in a face-centered cubic lattice with a density of $10.5 \ g/cm^3$ and an atomic radius of $1.34 \unicode{x212B}$. Assuming perfect close-packing, calculate the atomic mass of the element (in amu).

A metal crystallizes in a face-centered cubic lattice. The edge length of the unit cell is 408 pm. The density of the metal is $2.70 \, g/cm^3$. Calculate the atomic mass of the metal (in amu).