9.1 Types of molecular bonds (Page 2/14)

University physics volume 3 Page 2 / 14

E_{transfer} = 5.14 eV - 3.62 eV = 1.52 eV .

The positive sodium ion and negative chloride ion experience an attractive Coulomb force. The potential energy associated with this force is given by

U_{coul} = - \frac{k e^{2}}{r_{0}},

where $k e^{2} = 1.440 eV-nm$ and $r_{0}$ is the distance between the ions.

As the sodium and chloride ions move together (“descend the potential energy hill”), the force of attraction between the ions becomes stronger. However, if the ions become too close, core-electron wave functions in the two ions begin to overlap. Due to the exclusion principle, this action promotes the core electrons—and therefore the entire molecule—into a higher energy state. The equilibrium separation distance (or bond length ) between the ions occurs when the molecule is in its lowest energy state. For diatomic NaCl, this distance is 0.236 nm. [link] shows the total energy of NaCl as a function of the distance of separation between ions.

Graph of energy in eV versus separation in nm. The curve starts at an x value of around 0.1 and a y value of between 3 and 4. The first branch dips down sharply till x equal to 0.236 nm and y equal to 4.26 eV. From the trough, the second branch rises gradually and almost evens out just above y equal to 0. The curve crosses the x axis at 0.941 nm. The area bounded by the curve is shaded. To the right of the first branch of the curve is another curve labeled Pauli repulsion. This is cut off at y = 0 and x approximately equal to 0.3. A third curve, has a slope, which is similar to the second branch of the first curve and is below it. This is labeled Coulomb potential. A horizontal line at y equal to 1.52 is labeled ionization minus electron affinity is equal to 1.52 eV. — Graph of energy versus ionic separation for sodium chloride. Equilibrium separation occur when the total energy is a minimum $(- 4.36 eV)$ .

The total energy required to form a single salt unit is

U_{form} = E_{transfer} + U_{coul} + U_{ex},

where $U_{ex}$ is the energy associated with the repulsion between core electrons due to Pauli’s exclusion principle. The value of $U_{form}$ must be negative for the bond to form spontaneously. The dissociation energy is defined as the energy required to separate the unit into its constituent ions, written

U_{diss} = − U_{form}

Every diatomic formula unit has its own characteristic dissociation energy and equilibrium separation length. Sample values are given in [link] .

Bond length
Molecule	Dissociation Energy $(eV)$	Equilibrium Separation $(nm)$ $(Bond length)$
$NaCl$	$4.26$	$0.236$
$NaF$	$4.99$	$0.193$
$NaBr$	$3.8$	$0.250$
$NaI$	$3.1$	$0.271$
$NaH$	$2.08$	$0.189$
$LiCl$	$4.86$	$0.202$
$LiH$	$2.47$	$0.239$
$LiI$	$3.67$	$0.238$
$KCl$	$4.43$	$0.267$
$KBr$	$3.97$	$0.282$
$RbF$	$5.12$	$0.227$
$RbCl$	$4.64$	$0.279$
$CsI$	$3.57$	$0.337$
$H-H$	$4.5$	$0.075$
$N-N$	$9.8$	$0.11$
$O-O$	$5.2$	$0.12$
$F-F$	$1.6$	$0.14$
$Cl-Cl$	$2.5$	$0.20$

The energy of salt

What is the dissociation energy of a salt formula unit (NaCl)?

Strategy

Sodium chloride (NaCl) is a salt formed by ionic bonds. The energy change associated with this bond depends on three main processes: the ionization of Na; the acceptance of the electron from a Na atom by a Cl atom; and Coulomb attraction of the resulting ions (

{Na}^{+} and {Cl}^{−}

). If the ions get too close, they repel due to the exclusion principle (0.32 eV). The equilibrium separation distance is

r_{0} = 0.236 nm .

Solution

The energy change associated with the transfer of an electron from Na to Cl is 1.52 eV, as discussed earlier in this section. At equilibrium separation, the atoms are

r_{0} = 0.236 nm

apart. The electrostatic potential energy of the atoms is

U_{coul} = - \frac{k e^{2}}{r_{0}} = - \frac{1.44 eV \cdot nm}{0.236 nm} = −6.10 eV .

The total energy difference associated with the formation of a NaCl formula unit is

E_{form} = E_{xfr} + U_{coul} + U_{ex} = 1.52 eV + (− 6.10 eV) + 0.32 eV = − 4.26 eV .

Therefore, the dissociated energy of NaCl is 4.26 eV.

Significance

The formation of a NaCl formula unit by ionic bonding is energetically favorable. The dissociation energy, or energy required to separate the NaCl unit into

{Na}^{+} and {Cl}^{−}

ions is 4.26 eV, consistent with [link] .

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Source: OpenStax, University physics volume 3. OpenStax CNX. Nov 04, 2016 Download for free at http://cnx.org/content/col12067/1.4

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