Introduction of Lattice Enthalpy
A chemical reaction is a process that involves a rearrangement of the molecular or ionic structure of a substance. In this article, we shall discuss ionic solids and what Lattice Enthalpy is. The crystalline structure of ionic compounds is strong and rigid. It takes enough energy to break their bond. Ionic compounds are solids that have high boiling and melting points. The strong bonds between oppositely charged ions lock them into a network or lattice within the crystalline structure. Lattice Enthalpy is the change when this structure is formed or is broken.
What is Lattice Enthalpy?
In simple words, Lattice Enthalpy is the change in Enthalpy connected with the formation of one mole of an ionic compound from its gaseous ions, other things remaining standard. It is the energy required to entirely separate one mole of an ionic compound into gaseous ions. We can even say that Lattice Enthalpy is a measure of the strength of an ionic compound. Lattice is a strong network, mesh, or web and enthalpy is the heat content, total heat, or a thermodynamic quantity equal to the internal energy of a system and the product of its volume and pressure.
We can describe Lattice Enthalpy in the following two ways:
We can say that the enthalpy is the change when 1 mole of sodium chloride (or any other substance) was formed from its scattered gaseous ions. In the case of sodium chloride case, that would be -787kJ mol-1.
The second definition describes it as the enthalpy when 1 mole of sodium chloride (or any other substance) is broken up to form its scattered gaseous ions. In the case of sodium chloride case, it would be +787kJ mol-1.
So, the breaking up and the formation both get a reference as Lattice Enthalpy.
What are the Factors of Lattice Enthalpy?
As you know by now, Lattice Enthalpy is the change in enthalpy associated with the formation of one mole of an ionic compound from its gaseous ions under normal conditions. One of the key Lattice Enthalpy questions is the two principal factors that affect it. They are -
Charges on the Ions - Sodium chloride (NaCl) and magnesium oxide (MgO) have the same arrangement of ions in the lattice. However, their lattice enthalpies differ. The Lattice Enthalpy of MgO is greater than that of NaCl. The reason is in MgO, two +ions attract two –ions, whereas, in NaCl, the attraction is between one +ion and one –ion.
The Radius of the Ions - the Lattice Enthalpy of MgO is increased in relation to NaCl as the magnesium ions are smaller than sodium ions. It means that the ions are close together in the lattice of MgO, and this increases the strength of the attractions. Note that oxide ions are always smaller than chloride ions.
Can Lattice Enthalpy be Positive or Negative?
As mentioned earlier, Lattice Enthalpy is about forming up as well as breaking down. If we talk about the requirement of energy to split up the lattice into scattered gaseous ions- it is breaking down. In NaCl, the break-down or lattice dissociation enthalpy is +787 kJ mol-1.
When talking about lattice formation, the energy released when a lattice is created from its scattered gaseous state- is forming up. In the case of NaCl, the build-up or lattice formation enthalpy is -787 kJ mol-1.
Hence, the lattice dissociation enthalpies are always positive and the lattice formation enthalpies are always negative.
How to Calculate Lattice Enthalpy?
It is essential to note that you cannot measure the enthalpy change starting from a solid crystal that converts it into its gaseous ions. It is tougher to calculate the reverse scenario where you start with the gaseous ions and measure the change when the ions convert to solid-state. However, you can calculate lattice enthalpies in two different ways:
First, you can use a Hess law cycle or Born-Haber cycle that involves enthalpy changes that can be measured. Lattice enthalpies obtained through this method are known as experimental values.
Secondly, you can do it the physics way by working out how much energy would be released to make a lattice when ions (as point charges) come together to form a lattice. The calculation is about lattice energies and the values obtained are known as theoretical values.
Cross-section energy is the energy change on the arrangement of one mole of an ionic compound from its constituent particles in the vaporous state. It is a proportion of the firm powers of tight spot particles. Grid energy is applicable to numerous viable properties including solvency, hardness, and instability. The grid energy is normally derived from the Born–Haber cycle.
Grid Energy and Cross-Section Enthalpy
The development of a precious stone cross-section is exothermic, i.e., the worth of ΔHlattice is negative since it relates to the combining of boundlessly isolated vaporous particles in a vacuum to shape the ionic grid.
Sodium Chloride Precious Stone Cross-Section
The idea of cross-section energy was initially produced for rocksalt-organized and sphalerite-organized mixtures like NaCl and ZnS, where the particles involve high-even gem grid locales. On account of NaCl, grid energy is the energy delivered by the response
Na+ (g) + Cl− (g) → NaCl (s)
which would add up to - 786 kJ/mol.
The connection between the molar cross-section energy and the molar grid enthalpy is given by the accompanying condition:
A few reading materials and the normally utilized CRC Handbook of Chemistry and Physics characterize grid energy (and enthalpy) with the contrary sign, for example as the energy needed to change over the precious stone into endlessly isolated vaporous particles in a vacuum, an endothermic cycle. Following this show, the cross-section energy of NaCl would be +786 kJ/mol. The cross-section energy for ionic precious stones, for example, sodium chloride, metals like iron, or covalently connected materials, for example, a jewel is significantly more noteworthy in extent than for solids, for example, sugar or iodine, whose unbiased particles associate exclusively by more fragile dipole-dipole or van der Waals powers.
Hypothetical Medicines
The cross-section energy of an ionic compound relies on charges of the particles that contain the strong. All the more unpretentiously, the family members and outright sizes of the particles impact ΔHlattice.
Conceived Landé Condition
In 1918 Born and Landé recommended that grid energy could be gotten from the electric capability of the ionic cross-section, a terrible potential energy term.
NA is the Avogadro constant;
M is the Madelung consistent, identifying with the calculation of the precious stone;
z+ is the charge number of cation;
z− is the charge number of anion;
e is the rudimentary charge, equivalent to 1.6022×10−19 C;
ε0 is the permittivity of free space, equivalent to 8.854×10−12 C2 J−1 m−1;
r0 is the distance to the nearest particle; and
n is the Born type, a number somewhere in the range of 5, still up in the air tentatively by estimating the compressibility of the strong or determined hypothetically.
The Born–Landé condition shows that the grid energy of a compound relies upon various elements as the charges on the particles increment the grid energy increments (turns out to be more negative), at the point when particles are nearer together the cross-section energy increments (turns out to be more negative) Barium oxide (BaO), for example, which has the NaCl structure and in this manner a similar Madelung steady, has a bond sweep of 275 picometers and cross-section energy of - 3054 kJ/mol, while sodium chloride (NaCl) has a bond span of 283 picometers and grid energy of - 786 kJ/mol.
Kapustinskii Condition
The Kapustinskii condition can be utilized as a less complex method of inferring cross-section energies where high accuracy isn't needed.
Impact of Polarization
For ionic mixtures with particles possessing grid destinations with crystallographic point bunches C1, C1h, Cn, or Cnv (n = 2, 3, 4, or 6) the idea of the cross-section energy and the Born–Haber cycle must be extended. In these cases, the polarization energy Epol related to particles on polar grid locales must be remembered for the Born–Haber cycle and the strong development response needs to begin from the generally energized species. For instance, one might think about the instance of iron-pyrite FeS2, where sulfur particles possess a cross-section site of point evenness bunch C3. The grid energy characterizing response then, at that point, peruses
Fe2+ (g) + 2 pol S− (g) → FeS2 (s)
where pol S− represents the spellbound, vaporous sulfur particle. It has been shown that the neglect of the impact prompted a 15% distinction among hypothetical and trial thermodynamic cycle energies of FeS2 that diminished to just 2% when the sulfur polarization impacts were incorporated.
FAQs on Lattice Enthalpy of an Ionic Solid
1. What is the lattice enthalpy of an ionic solid?
Lattice enthalpy is the enthalpy change that occurs when one mole of an ionic compound is formed from its constituent gaseous ions. For example, the lattice enthalpy of formation for NaCl is the energy released when Na⁺(g) and Cl⁻(g) ions combine to form one mole of solid NaCl(s). It can also be defined with the opposite sign as the energy required to completely separate one mole of an ionic solid into its gaseous ions. This value is a key measure of the strength of the ionic bonds in the crystal lattice.
2. What are the main factors that affect the lattice enthalpy of an ionic compound?
Two primary factors determine the magnitude of lattice enthalpy:
- Ionic Charge: The greater the charge on the ions, the stronger the electrostatic attraction between them, resulting in a higher (more exothermic) lattice enthalpy. For example, MgO (with Mg²⁺ and O²⁻ ions) has a much higher lattice enthalpy than NaCl (with Na⁺ and Cl⁻ ions).
- Ionic Radius: The smaller the distance between the ions (i.e., smaller ionic radii), the stronger the attraction. This leads to a higher lattice enthalpy. For instance, LiF has a higher lattice enthalpy than KCl because the Li⁺ and F⁻ ions are smaller than K⁺ and Cl⁻ ions, allowing for closer packing.
3. Why does Iron(III) chloride (FeCl₃) have a greater lattice enthalpy than Iron(II) chloride (FeCl₂)?
Iron(III) chloride (FeCl₃) has a greater lattice enthalpy because the iron ion in FeCl₃ is Fe³⁺, which has a higher positive charge than the Fe²⁺ ion in FeCl₂. According to Coulomb's Law, the force of attraction between charged particles is directly proportional to the product of their charges. The higher charge on the Fe³⁺ ion leads to a much stronger electrostatic attraction with the chloride (Cl⁻) ions in the crystal lattice, releasing more energy upon formation and thus resulting in a significantly more negative (or larger in magnitude) lattice enthalpy.
4. Why can't lattice enthalpy be measured directly, and how is it determined instead?
Lattice enthalpy cannot be measured directly in a single laboratory experiment because it is practically impossible to form one mole of a crystalline solid directly from its gaseous ions or to break it apart into gaseous ions in one step. Instead, it is calculated indirectly using the Born-Haber cycle. This cycle applies Hess's Law, constructing a thermodynamic loop that connects the formation of the ionic solid from its elements to its constituent gaseous ions through a series of measurable steps, such as enthalpy of atomisation, ionisation energy, and electron affinity.
5. What does the lattice enthalpy value of Sodium Chloride (NaCl) signify?
The lattice enthalpy of formation for sodium chloride (NaCl) is approximately -787 kJ/mol. This large negative value signifies that a substantial amount of energy is released when one mole of gaseous sodium ions (Na⁺) and one mole of gaseous chloride ions (Cl⁻) come together to form a stable, solid crystal lattice. This indicates that the ionic bonds in NaCl are very strong and that the resulting solid is highly stable compared to its separate gaseous ions.
6. What is the key difference between lattice enthalpy and lattice energy?
While often used interchangeably, lattice enthalpy (ΔH) and lattice energy (ΔU) are technically different. Lattice energy (ΔU) is the change in internal energy during the formation of an ionic lattice from gaseous ions. Lattice enthalpy (ΔH) is related to it by the equation ΔH = ΔU + PΔV. For solids, the change in volume (ΔV) is very small, so the PΔV term is negligible. Consequently, the numerical values of lattice enthalpy and lattice energy are almost identical, but lattice enthalpy is the more precise term in a constant pressure context.
7. How is lattice enthalpy calculated theoretically?
Theoretically, lattice enthalpy (or more accurately, lattice energy) can be calculated using equations derived from electrostatic principles. The most well-known is the Born-Landé equation. This formula calculates the lattice energy by considering:
- The charges on the cation and anion.
- The distance between the ions in the crystal.
- The arrangement of ions in the lattice, represented by the Madelung constant.
- A term that accounts for repulsive forces.
This theoretical value can then be compared to the experimental value obtained from the Born-Haber cycle to assess the degree of ionic character in a bond.
