solution crystal

solution

0 2 4

3.2 3.6 4.0 4.4

E ne rgy (e V )

Vibronic number

0 2 4

3.2 3.6 4.0 4.4

E ne rgy (e V )

Vibronic number crystal

solution crystal solution

Figure 32: Analysis of the vibronic peaks of anthracene shown in Fig. 8.13 as considered in Exercise 8.11.

the 0–0, 0–1, 0–2, and 0–3 transitions, and a linear fit according to eqn 8.3 gives the vibrational energy as 0.18 eV. (See Fig. 32.)

Two other features can also be identified in the absorption spectrum of the crystal at 3.18 and 3.35 eV. These have the same splitting as the other progression and therefore involve similar types of vibrations. The most probable cause is a splitting of the electronic states in the crystal due to its lower symmetry, eg by the Davydov effect. (See Pope and Swenberg, Electronic processes in organic crystals and polymers, 2nd edn, Oxford University Press, 1999, Section I.D.5, pp 59–66.)

(8.12) When the ‘mirror symmetry’ rule works, we expect the emission spectrum to be a mirror image of the absorption spectrum about the 0–0 transition.

(See, for example, Figs 8.10 or 8.17.) We thus expect a broad vibronic band extending downwards from the 0-0 transition at 3.13 eV. The width of the band will be about 1 eV. A series of vibronic peaks will occur with energies given by hν ≈ (3.13 − n~Ω), with ~Ω ≈ 0.18 eV. We would thus expect peaks at 3.13, 2.95, 2.77, 2.59 eV · · · .

(8.13) The S1 absorption band has a 0–0 transition at 1.9 eV and extends to

∼ 2.8 eV. The emission band would thus have a 0–0 transition at 1.9 eV and extend down to about 1.0 eV. The 0–1 vibronic peaks occurs at 2.1 eV in the absorption spectrum, which implies a vibrational energy of ∼ 0.2 eV, and hence a 0–1 transition in emission at around 1.7 eV.

(8.14) As discussed for the PDA data in Fig. 8.16, the difference between the absorption and photoconductivity edges is caused by excitonic effects. The absorption edge corresponds to the creation of tightly-bound (Frenkel) excitons. Since excitons are neutral particles, they do not contribute to the photoconductivity. The photoconductivity edge therefore corresponds to the band edge where free electrons and holes are first created. The difference in the two edges gives the exciton binding energy, which works out to be 1.1 eV.

It is important to realize that this is a different situation to that encoun-tered for weakly-bound (Wannier) excitons. Weakly-bound excitons can

be easily ionized to produce free electrons and holes, and hence produce a photocurrent. (See, for example, Figs 4.5 and 6.15.)

(8.15) The dominant vibrational frequency can be deduced by analysing the vi-bronic progression of either the absorption or emission spectra in Fig. 8.17 according to eqns 8.3 or 8.5 as appropriate. This gives ~Ω ∼ 0.17 eV, im-plying Ω ∼ 2.6 × 10¹⁴rad/s. With ω = 2.98 × 10¹⁵rad/s, we then find ω_Raman= (ω − Ω) = 2.72 × 10¹⁵rad/s, which is equivalent to a wavelength of 693 nm.

Two points could be made here:

• The molecule will have other vibrational modes, and these will give additional Raman lines.

• Not all vibrational modes are Raman-active, (see Section 10.5.2) and it is not immediately obvious that the 0.17 eV mode responsible for the vibronic spectra will show up in the Raman spectrum. In fact, these modes are observed in the experimental Raman spectra, but it requires a careful analysis by group theory to prove that this is so.

(8.16) Optical excitation creates only singlets because the ground state is a singlet and optical transitions do not change the spin. With only singlet states excited, the recombination of the electrons and holes is optically allowed for all the carriers.

Wave function Sz S State

↑e↑h +1 1 triplet (↑e↓h+ ↓e↑h)/√

2 0 1 triplet (↑e↓h− ↓e↑h)/√

2 0 0 singlet

↓e↓h −1 1 triplet

Table 6: Possible arrangements of relative electron-hole spins as discussed in Exercise 8.16.

On the other hand, with electrical injection there is no control of the relative spin of the electrons and holes. The spins can be either parallel or anti-parallel, and this gives rise to four possible total spin wave functions, as indicated in Table 6. Three of these are triplets and only one is a singlet state. The relative number of triplet and singlet excitons created by electrical injection is therefore in the ratio 3:1, which implies that only 25% of the excitons are in singlet states. The remaining 75% are in triplet states with very low emission probabilities. Hence the emission is expected to be weaker than that for optical excitation by a factor of four.

The creation of triplets in electrically-driven organic LEDs is a serious issue that limits their efficiency. One way to enhance the efficiency is to increase the spin–orbit interaction to encourage inter-system crossing.

This is typically done by including a heavy metal atom in the molecule.

(See Exercise 8.9.)

(8.17) (a) As we have seen in Exercise 8.16, we expect that 75% of the excitons created will be in triplet states with very low emission probabilities. Hence

the maximum quantum efficiency that we can expect corresponds to the number of singlet excitons that we create, namely 25%.

(b) The number of electrons and holes flowing into a device carrying a current i is equal to i/e. The quantum efficiency is defined as the ratio of photons out to electrons in, and so the number of photons emitted will be equal to ηi/e. The power emitted is then equal to hν × ηi/e, and we have:

P = 2.25 eV × 25% × 10 mA/e = 5.6 mW .

(c) The electrical power consumed by the device is equal to iV = 50 mW.

The power conversion efficiency is thus equal to 5.6/50 = 11 %. The efficiency of a real device would be much lower, mainly due to the difficulty of collecting the photons, which are emitted in all directions (ie over 4π solid angle). Only a small fraction of these would be collected by the optics. This latter point is exacerbated by the high refractive index of the molecular material, which tends to limit the effective collection efficiency even further. (See Exercise 5.13.)

a

Figure 33: (a) Analysis of the lattice vectors of graphene, as considered in in Exercise 8.18(a). (b) Evaluation of the chiral angle θ, as required in Exer-cise 8.18(c).

(8.18) (a) The unit cell of graphene and its lattice vectors are shown in Fig. 33(a).

From inspection of this figure, we see that:

|a1| = 2 × a cos 30^◦= 2a√

3/2 =√ 3a ,

where a is the length of the hexagon edge. The result for |a2| is identical by symmetry.

(b) We first find the length of the chiral vector c defined in eqn 8.14 by evaluating its scalar product:

c²≡ c · c = (n1a1+ n2a2) · (n1a1+ n2a2) ,

= n²₁a1· a1+ 2n1n2a1· a2+ n²₂a2· a2.

Now a1· a1= a2· a2= a²₀and a1· a2= |a1| |a2| cos 60^◦ = a²₀/2. Hence c²= a²₀(n²₁+ n1n2+ n²₂) .

Since c is the circumference, the tube diameter d is then given by:

d = c π =a0

π q

n²₁+ n1n2+ n²₂, as required.

(c) The chiral angle for a nanotube with the chiral vector defined in eqn 8.14 can be evaluated by reference to Fig. 33(b). It is apparent that:

tan θ = n2|a2| sin 60^◦ n1|a1| + n2|a2| cos 60^◦. On noting that |a1| = |a2|, this simplifies to:

tan θ = n2sin 60^◦ n₁+ n₂cos 60^◦ =

√3n2/2 n₁+ n₂/2 =

√3n2

2n₁+ n₂. Equation 8.16 follows immediately.

(8.19) (a) Symmetry requires that the electron wave function should be single-valued on rotating the tube by 2π. The phase change of the electron wave function for a rotation through 2π is given by:

∆φ = k⊥|c| ≡ k · c

where k⊥ is the component of the wave vector in the direction perpen-dicular to the tube axis and c is the chiral vector. This must be equal to an integer multiple of 2π in order that the electron wave function is single-valued. Hence we require:

k · c = 2πm , where m is an integer.

(b) The tube will be metallic if the k vector corresponding to the K point of the Brillouin zone is one of the allowed wave vectors of the nanotube.

This will be the case if the condition derived in part (a) is satisfied when k corresponds to the K point, that is if:

K · c = 2πm ,

where K = (k1− k2)/3. Now the reciprocal lattice vectors are defined by:

a₁· k₁= a₂· k₂ = 2π , a2· k1= a1· k2 = 0 . Hence

K · c = (k1− k2) · (n1a1+ n2a2)/3 = (2πn1− 2πn2)/3 , and therefore

2π(n1− n2)/3 = 2πm , which implies n1− n2= 3m.

(8.20) We treat the nanotube as a 1–D quantum wire of length L with its axis along the z direction, and apply periodic boundary conditions so that

Ψ(x, y, z) = Ψ(x, y, z + L) .

The electrons are assumed to have free motion along the z axis and so their wave function is of the form:

Ψ(x, y, z) = ψ(x, y) exp ikz . The periodic boundary condition requires that:

exp ik(z + L) = exp ikz .

This means that exp ikL = 1, and hence that k = 2πm/L, where m is an integer. The density of states in k space is therefore L/2π. We can thus write the density of states per unit length in k space as

g(k) = 1/2π .

The density of states per unit length in energy space is worked out from:

g(E) = 2 × 2g(k) dE/dk.

The additional factor of two here compared to eqn 3.14 comes from the fact that the +k and −k velocity states are degenerate. We assume that we have a free electron moving in a band with energy En associated with the quantized motion in the (x, y) directions. The total energy is then given by:

E(k) = En+~²k² 2m^∗ , so that

dE dk =~²k

m^∗ = µ2~²

m^∗

¶_1/2

(E − En)^1/2. The density of states is thus given by:

g(E) = 4 1 2π

µm^∗ 2~²

¶_1/2

(E − En)^−1/2=

√2m^∗

π~ (E − En)^−1/2, as required for eqn 8.20.

(8.21) The radiative quantum efficiency is given by eqn 5.5. The decay route via intersystem crossing to the T1 level is non-radiative, and so we can take τNR = 1.2 ns. The radiative lifetime τR is given as 1.8 µs. Hence:

ηR= 1

1 + τR/τNR = 1

1 + (1.8 × 10⁻⁶/1.2 × 10⁻⁹) = 6.7 × 10⁻⁴. The radiative quantum efficiency is therefore only 0.07%.

Chapter 9