Direct and indirect band gaps

Quantum capacitance (density) is a physical value first introduced by Serge Luryi (1988)^[1] to describe the 2D-electronic systems in silicon surfaces and GaAs junctions. This capacitance was defined through standard density of states in the solids. Quantum capacitance could be used in the quantum Hall effect (integer and fractional) investigations as a new approach which uses quantum LC circuit.

Theory

In the general case 2D-density of states in a solid could be defined by the following:

${\displaystyle D_{2D}={\frac {m^{*}}{\pi \hbar ^{2}}}}$,

where ${\displaystyle m^{*}=\xi m_{0}}$ is a current carrier's effective mass in a solid, ${\displaystyle m_{0}}$ is the electron mass, and ${\displaystyle \xi }$ is a dimensionless parameter which considers the zone structure of a solid. So, the quantum capacitance can be defined as follows:

${\displaystyle C_{QL}=e^{2}\cdot D_{2D}=\xi \cdot C_{Q0}}$,

where ${\displaystyle C_{Q0}=8\pi \alpha \cdot C_{QY}\ }$ - the ‘‘ideal value’’ of quantum capacitance at ${\displaystyle \xi =1\ }$ and another ideal quantum capacitance:

${\displaystyle C_{QY}={\frac {\epsilon _{0}}{\lambda _{0}}}=3.649\;2417\;\mathrm {F/m^{2}} }$,

where ${\displaystyle \epsilon _{0}-\ }$ dielectric constant, ${\displaystyle \alpha -\ }$ fine structure constant and ${\displaystyle \lambda _{0}-\ }$ Compton wave length of electron, first defined by Yakymakha (1994) )^[2] in the spectroscopic investigations of the silicon MOSFETs.

Experiments

Heterostructure tunnel junctions

The first attempt of quantum capacitance experimental confirmation in the 21st century were made by Qingmin Liu and Alan Seabaugh from the Notre Dame University (2001).^[3] They investigated GaAs heterostructure tunnel junctions. It is evident that tunnel junction capacity is defined by the metallurgic tunnel junction surface:

${\displaystyle C_{TD}={\frac {\epsilon _{0}S_{TD}}{a_{TD}}}\approx 6\times 10^{-14}\;\mathrm {F} =60\;\mathrm {fF} }$

where ${\displaystyle S_{TD}=(1.6\times 10^{-6}\;\mathrm {m} )^{2}-\ }$ AlAs/InGaAs/AlAs- metallurgic tunnel junction surface, ${\displaystyle a_{TD}=3.84\times 10^{-10}\;\mathrm {m} -\ }$ junction thickness (its value could be estimated by heterostructure lattice constant). For the aim of comparison, the quantum capacitance (Yakymakha) in this case should be:

${\displaystyle C_{TDQ}={\frac {\epsilon _{0}S_{TD}}{\lambda _{0}}}\approx 9.34\times 10^{-12}\;\mathrm {F} =9.32\;\mathrm {pF} \ }$.

Therefore this value is significantly greater than the experimental value obtained by Seabaugh. Thus, in the general case of tunnel junction, neither Yakymakha, nor Luryi (there are no 2D- density of states in the 1D- dimension) approaches could be used.

Graphene MOSFETs

One publication on the theme was made by Zhihong Chen and Joerg Appenzeller^[4] on the high quality Graphene field-effect transistor devices. In this paper the Luryi definition of quantum capacitance was used:

${\displaystyle D_{Gr}={\frac {aE}{\pi \hbar ^{2}v_{F}^{2}}},a=1\ }$

${\displaystyle C_{QL}=e^{2}D_{Gr}={\frac {e^{2}m^{*}}{\pi \hbar ^{2}}}}$,

where ${\displaystyle m^{*}={\frac {E}{v_{F}^{2}}}={\frac {\hbar }{v_{F}}}\cdot {\sqrt {\pi n_{2D}}}-\ }$ current carriers cyclotron mass. The authors obtained the linear mirrors dependence of the quantum capacitance on the gate voltage, with the minimal value at the ‘‘Dirac point’’ about (Fig.7):

${\displaystyle C_{exp}\approx 4\times 10^{-3}\;\mathrm {F/m^{2}} \ }$.

In the case of the multi-layer graphene there is the constant value (independent of the gate voltage) of the quantum capacitance, equal to the minimal value of the mono-layer graphene. Further the authors supposed, that in the "ideal case" the quantum capacitance of graphene should have zero value at the Dirac point. This isn’t true. According to Yakymakha (1989),^[5] the 2D-system with the particles of two sorts have zone structure with the minimal particles concentration about the intrinsic value:

${\displaystyle n_{2D}(T_{c})=3.03\times 10^{14}\;\mathrm {m^{-2}} \ }$.

Using this value for the cyclotron mass, we obtain its minimum value:

${\displaystyle m^{*}(n_{2D}(T_{c}))={\frac {2\hbar }{\alpha c}}{\sqrt {\pi n_{2D}(T_{c})}}\approx 2.9767\times 10^{-33}\;\mathrm {kg} \ }$.

Then, dimensionless parameter will be approximated as:

${\displaystyle \xi ={\frac {m^{*}(n_{2D}(T_{c}))}{m_{0}}}\approx 3.2677\times 10^{-3}\ }$.

From above, we can find out the minimal value of the quantum capacitance in graphene:

${\displaystyle C_{QL}=\xi C_{Q0}\approx 2.187\times 10^{-3}\;\mathrm {F/m^{2}} \ }$.

This value is two times lesser than the experimental value. Nothing strange is there. Actually, we used above only one type of current carriers during estimation procedure. However, at the Dirac point in graphene, we have the two type conductivity, due to the quasi-electron and quasi-holes. Therefore, on practice, we have two quantum capacitances due to the quasielectron and quasiholes, connected in the parallel circuit. These two quantum capacitances confirms indirectly the existence of the “band structure” in graphene near the Dirac point with nonzero value of the “forbidden band”.

References

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External links

• D.L. John, L.C. Castro, and D.L. Pulfrey "Quantum Capacitance in Nanoscale Device Modeling" Nano Electronics Group Publications.
• ECE 453 Lecture 30: Quantum Capacitance
• "Measurement of the quantum capacitance of interacting electrons in carbon nanotubes" Nature