Biexciton Explained

In condensed matter physics, biexcitons are created from two free excitons.

Formation of biexcitons

In quantum information and computation, it is essential to construct coherent combinations of quantum states.The basic quantum operations can be performed on a sequence of pairs of physically distinguishable quantum bits and, therefore, can be illustrated by a simple four-level system.

In an optically driven system where the

|01\rangle

and

|10\rangle

states can be directly excited, direct excitation of the upper

|11\rangle

level from the ground state

|00\rangle

is usually forbidden and the most efficient alternative is coherent nondegenerate two-photon excitation, using

|01\rangle

|10\rangle

as an intermediate state.^[1] ^[2]

Observation of biexcitons

Three possibilities of observing biexcitons exist:^[3]

(a) excitation from the one-exciton band to the biexciton band (pump-probe experiments);

(b) two-photon absorption of light from the ground state to the biexciton state;

Binding energy of biexcitons

The biexciton is a quasi-particle formed from two excitons, and its energy is expressed as

E_XX=2E_X-E_b

where

E_XX

is the biexciton energy,

E_X

is the exciton energy, and

E_b

is the biexciton binding energy.

When a biexciton is annihilated, it disintegrates into a free exciton and a photon. The energy of the photon is smaller than that of the exciton by the biexciton binding energy,so the biexciton luminescence peak appears on the low-energy side of the exciton peak.

The biexciton binding energy in semiconductor quantum dots has been the subject of extensive theoretical study. Because a biexciton is a composite of two electrons and two holes, we must solve a four-body problem under spatially restricted conditions. The biexciton binding energies for CuCl quantum dots, as measured by the site selective luminescence method, increased with decreasing quantum dot size. The data were well fitted by the function

B_XX=

	c₁
	a²

	c₂
	a

+B_bulk

where

B_XX

is biexciton binding energy,

is the radius of the quantum dots,

B_bulk

is the binding energy of bulk crystal, and

c₁

and

c₂

are fitting parameters.^[4]

A simple model for describing binding energy of biexcitons

In the effective-mass approximation, the Hamiltonian of the system consisting of two electrons (1, 2) and two holes (a, b) is given by

H_XX=-

\hbar²

	*
m
	e

	2
({\nabla
	1}

	2)
{\nabla
	2}

\hbar²

	*
m
	h

	2
({\nabla
	a}

	2)
{\nabla
	b}

where

	*
m
	e

and

	*
m
	h

are the effective masses of electrons and holes, respectively, and

V=V₁₂-V_1a-V_1b-V_2a-V_2b+V_ab

where

V_ij

denotes the Coulomb interaction between the charged particles

and

(

i,j=1,2,a,b

denote the two electrons and two holes in the biexciton) given by

V_ij=

	e²
	\epsilon\|r_i-r_j\|

where

\epsilon

is the dielectric constant of the material.

Denoting

and

are the c.m. coordinate and the relative coordinate of the biexciton, respectively, and

	*
m
	e

	*
m
	h

is the effective mass of the exciton, the Hamiltonian becomes

H_XX=-

	\hbar²
	4M

	2
{\nabla
	R}

	\hbar²
	M

	2
{\nabla
	r}

	\hbar²
	2\mu

({\nabla_1a

}^2 + ^2) + V

where

1/\mu=

	*}
1/{m
	e

	*}
1/{m
	h

;

{\nabla_1a

}^2 and

{\nabla_2b

}^2 are the Laplacians with respect to relative coordinates between electron and hole, respectively.And

	2
{\nabla
	r}

is that with respect to relative coordinate between the c. m. of excitons, and

	2
{\nabla
	R}

is that with respect to the c. m. coordinate

of the system.

In the units of the exciton Rydberg and Bohr radius, the Hamiltonian can be written in dimensionless form

H_XX=-({\nabla_1a

}^2 + ^2) - ^2 + V

where

\sigma=

	*}
{m
	h

with neglecting kinetic energy operator of c. m. motion. And

can be written as

V=2\left(

	1
	r₁₂

	1
	r_1a

	1
	r_1b

	1
	r_2a

	1
	r_2b

	1
	r_ab

\right)

To solve the problem of the bound states of the biexciton complex, it is required to find the wave functions

\psi

satisfying the wave equation

H_XX\psi=E_XX\psi

If the eigenvalue

E_XX

can be obtained, the binding energy of the biexciton can be also acquired

E_b=2E_X-E_XX

where

{E_b

} is the binding energy of the biexciton and

{E_X

} is the energy of exciton.^[5]

Numerical calculations of the binding energies of biexcitons

The diffusion Monte Carlo (DMC) method provides a straightforward means of calculating the binding energies of biexcitons within the effective mass approximation. For a biexciton composed of four distinguishable particles (e.g., a spin-up electron, a spin-down electron, a spin-up hole and a spin-down hole), the ground-state wave function is nodeless and hence the DMC method is exact. DMC calculations have been used to calculate the binding energies of biexcitons in which the charge carriers interact via the Coulomb interaction in two and three dimensions,^[6] indirect biexcitons in coupled quantum wells,^[7] ^[8] and biexcitons in monolayer transition metal dichalcogenide semiconductors.^[9] ^[10] ^[11]

Binding energy in nanotubes

Biexcitons with bound complexes formed by two excitons are predicted to be surprisingly stable for carbon nanotube in a wide diameter range.Thus, a biexciton binding energy exceeding the inhomogeneous exciton line width is predicted for a wide range of nanotubes.

The biexciton binding energy in carbon nanotube is quite accurately approximated by an inverse dependence on

, except perhaps for the smallest values of

E_XX ≈

	0.195eV
	r

The actual biexciton binding energy is inversely proportional to the physical nanotube radius.^[12] Experimental evidence of biexcitons in carbon nanotubes was found in 2012. ^[13]

Binding energy in CuCl QDs

The binding energy of biexcitons increase with the decrease in their size and its size dependence and bulk value are well represented by the expression

	78
	{a^*

^2}+

	52
	{a^*

} + 33 (meV)

where

a^*

is the effective radius of microcrystallites in a unit of nm. The enhanced Coulomb interaction in microcrystallites still increase the biexciton binding energy in the large-size regime, where the quantum confinement energy of excitons is not considerable.^[14]

Notes and References

Chen. Gang. Stievater. T. H.. Batteh. E. T.. Li. Xiaoqin. Steel. D. G.. Gammon. D.. Katzer. D. S.. Park. D.. Sham. L. J.. Biexciton Quantum Coherence in a Single Quantum Dot. Physical Review Letters. 88. 11. 117901. 2002. 0031-9007. 10.1103/PhysRevLett.88.117901. 11909428. 2002PhRvL..88k7901C.
Li. X.. An All-Optical Quantum Gate in a Semiconductor Quantum Dot. Science. 301. 5634. 2003. 809–811. 0036-8075. 10.1126/science.1083800. 12907794. 2003Sci...301..809L. 22671977.
Vektaris. G.. A new approach to the molecular biexciton theory. The Journal of Chemical Physics. 101. 4. 1994. 3031–3040. 0021-9606. 10.1063/1.467616. 1994JChPh.101.3031V.
S.. Park. etal. Fabrication of CuCl Quantum Dots and the Size Dependence of the Biexciton Binding Energy. Journal of the Korean Physical Society. 37. 3. 309–312. 2000.
Liu. Jian-jun. Kong. Xiao-jun. Wei. Cheng-wen. Li. Shu-shen. Binding Energy of Biexcitons in Two-Dimensional Semiconductors. Chinese Physics Letters. 15. 8. 1998. 588–590. 0256-307X. 10.1088/0256-307X/15/8/016. 1998ChPhL..15..588L. 250889566 .
D. Bressanini . M. Mella . G. Morosi . amp . Stability of four-body systems in three and two dimensions: A theoretical and quantum Monte Carlo study of biexciton molecules. Physical Review A . 57. 6 . 4956–4959 . 1998. 10.1103/PhysRevA.57.4956. 1998PhRvA..57.4956B .
M.Y.J. Tan . N.D. Drummond . R.J. Needs . amp . Exciton and biexciton energies in bilayer systems. Physical Review B . 71. 3 . 033303. 2005. 10.1103/PhysRevB.71.033303. 0801.0375 . 2005PhRvB..71c3303T . 119225682 .
R.M. Lee . N.D. Drummond . R.J. Needs . amp . Exciton-exciton interaction and biexciton formation in bilayer systems. Physical Review B . 79. 12 . 125308. 2009. 10.1103/PhysRevB.79.125308 . 0811.3318 . 2009PhRvB..79l5308L . 19161923 .
M.Z. Mayers. T.C. Berkelbach. M.S. Hybertson. D.R. Reichman. amp. Binding energies and spatial structures of small carrier complexes in monolayer transition-metal dichalcogenides via diffusion Monte Carlo. Physical Review B . 92 . 16. 161404. 2015. 10.1103/PhysRevB.92.161404. 1508.01224 . 2015PhRvB..92p1404M . 118607038.
Szyniszewski, M.. Binding energies of trions and biexcitons in two-dimensional semiconductors from diffusion quantum Monte Carlo calculations. Physical Review B. 95. 8. 081301(R). 2017. 10.1103/PhysRevB.95.081301. 1701.07407. etal. 2017PhRvB..95h1301S . 17859387.
Mostaani, E.. Diffusion quantum Monte Carlo study of excitonic complexes in two-dimensional transition-metal dichalcogenides. Physical Review B. 96. 7. 075431. 2017. 10.1103/PhysRevB.96.075431. 1706.04688. etal. 2017PhRvB..96g5431M. 46144082.
Pedersen. Thomas G.. Pedersen. Kjeld. Cornean. Horia D.. Duclos. Pierre. Stability and Signatures of Biexcitons in Carbon Nanotubes. Nano Letters. 5. 2. 2005. 291–294. 1530-6984. 10.1021/nl048108q. 15794613. 2005NanoL...5..291P.
Colombier. L.. Selles. J.. Rousseau. E.. Lauret. J. S.. Vialla. F.. Voisin. C.. Cassabois. G.. Detection of a Biexciton in Semiconducting Carbon Nanotubes Using Nonlinear Optical Spectroscopy. Physical Review Letters. 109. 19. 2012. 197402. 0031-9007. 10.1103/PhysRevLett.109.197402. 23215424. 2012PhRvL.109s7402C. 25249444 .
Masumoto. Yasuaki. Okamoto. Shinji. Katayanagi. Satoshi. Biexciton binding energy in CuCl quantum dots. Physical Review B. 50. 24. 1994. 18658–18661. 0163-1829. 10.1103/PhysRevB.50.18658. 9976308. 1994PhRvB..5018658M. 2241/98241. free.