Physics/Essays/Fedosin/Quantum Inductance: Difference between revisions

Quantum Inductance is the physical value that can be obtained from the density of states (DOS) approach, first introduced by Serge Luryi (1988) ^[1] to describe the 2D-electronic systems in silicon surfaces and AsGa junctions. This inductance is defined through standard density of states in solids. Quantum inductance can be used in Quantum Hall effect (integer and fractional) investigations as an approach which uses Quantum LC circuit.

For the standard classical series ${\displaystyle R_d{L}_d{C}_d}$ circuit the planar inductance can be defined as:

${\displaystyle L_d=\frac{{\mu }_0{\mu }_r{S}_{xz}{N}^2}{l_y},}$

where ${\displaystyle {\mu }_0}$ is the vacuum permeability, ${\displaystyle {\mu }_r}$ is the relative permeability, ${\displaystyle S_{yz}=l_y{l}_z}$ is the MOSFET channel surface, ${\displaystyle S_{xz}=l_x{l}_z}$ is the channel cross section, ${\displaystyle l_x}$ is the channel depth, ${\displaystyle l_y}$ is the channel length, ${\displaystyle l_z}$ is the channel width, ${\displaystyle N=\frac{l_y}{{\lambda }_y}}$ is the turn number of the planar induction coil, ${\displaystyle {\lambda }_y}$ is the helix step of induction coil.

In the quantum limits, unknown parameter could be estimated by the following:

${\displaystyle {\lambda }_y=\sqrt{\frac{{\mu }_0{\mu }_r{S}_{yz}{l}_x}{L_d}}}$,

where ${\displaystyle \mu \to 1}$, ${\displaystyle l_x\to {\lambda }_0}$, ${\displaystyle L_d\to L\approx 7.407\cdot 10^{-2}}$ H and ${\displaystyle S_{yz}\to S\approx 1.43\cdot 10^{-7}}$ m². Therefore we shall have the quantum value about Compton wavelength of electron ${\displaystyle {\lambda }_0}$:

${\displaystyle {\lambda }_{y0}=\sqrt{\frac{{\mu }_{0}S{\lambda }_0}{L}}\approx 2.426\cdot 10^{-12}}$ m.

Electromagnetic induction (Faraday) law is:

${\displaystyle V_{ind}=\frac{\partial \mathrm{\Phi }}{\partial t}=-L\frac{\partial I}{\partial t},}$

where ${\displaystyle \mathrm{\Phi }}$ is magnetic flux, ${\displaystyle L}$ is the Josephson junction quantum inductance and ${\displaystyle I}$ is the Josephson junction current.

DC Josephson equation for current is:

${\displaystyle I=I_J\cdot \sin \varphi ,}$

where ${\displaystyle I_J}$ is the Josephson scale for current, ${\displaystyle \varphi }$ is the phase difference between superconductors.

Current derivative on time variable will be:

${\displaystyle \frac{\partial I}{\partial t}=I_J\cos \varphi \cdot \frac{\partial \varphi }{\partial t}.}$

AC Josephson equation is:

${\displaystyle \frac{\partial \varphi }{\partial t}=\frac{q}{\hslash }V=\frac{2\pi }{{\mathrm{\Phi }}_0}V,}$

where ${\displaystyle \hslash }$ is the reduced Planck constant, ${\displaystyle {\mathrm{\Phi }}_0=h/2e}$ is the Josephson magnetic flux quantum, ${\displaystyle q=2e}$ and ${\displaystyle e}$ is the elementary charge.

Combining equations for derivatives yields junction voltage:

${\displaystyle V=\frac{{\mathrm{\Phi }}_0}{2\pi I_J}\cdot \frac{1}{\cos \varphi }\cdot \frac{\partial I}{\partial t}=L_J\cdot \frac{\partial I}{\partial t},}$

where

${\displaystyle L_J=\frac{{\mathrm{\Phi }}_0}{2\pi I_J}\cdot \frac{1}{\cos \varphi }}$

is the Deboret (1997) ^[2] quantum inductance.

In the general case 2D-density of states (DOS) in a solid can be defined by the following:

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

where ${\displaystyle m^{*}=\xi m_e}$ is current carriers effective mass in a solid, ${\displaystyle m_e}$ is the electron mass, and ${\displaystyle \xi }$ is a dimensionless parameter, which considers band structure of the solid. So, the quantum inductance can be defined as follows:

${\displaystyle L_Q={\varphi }_0^2\cdot D_{2D}\cdot S=\frac{h^2}{e^2}\cdot D_{2D}\cdot S=k\xi \cdot L_{Q0},}$

where ${\displaystyle {\varphi }_0=h/e}$ is the magnetic flux quantum, ${\displaystyle S=k{S}_0}$ is the resonator surface area, ${\displaystyle S_0=\frac{{\lambda }_0^2}{2\pi }}$ is the elementary surface area, ${\displaystyle k}$ is the coefficient of area, ${\displaystyle L_{Q0}=2\beta \cdot L_{QY}}$ is the elementary quantum inductance, and another ideal quantum inductance is:

${\displaystyle L_{QY}={\mu }_0{\lambda }_0=3.04899\cdot 10^{-18}}$ H,

where ${\displaystyle {\mu }_0}$ is the vacuum permeability, ${\displaystyle \beta =\frac{1}{4\alpha }}$ is the magnetic coupling constant, ${\displaystyle \alpha }$ is the fine structure constant and ${\displaystyle {\lambda }_0=\frac{h}{m_{e}c}}$ is the Compton wavelength of electron.

The quantum inductance in the QHE mode will be:

${\displaystyle L_{QA}=\frac{{\varphi }_0^2\cdot D_{2D}}{n_B}}$,

where the carrier concentration per unit area in magnetic field ${\displaystyle B}$ is:

${\displaystyle n_B=\frac{eB}{h}.}$

By analogy, the quantum capacitance in the QHE mode will be:

${\displaystyle C_{QA}=\frac{C_{QL}}{n_B}}$,

where

${\displaystyle C_{QL}=e^2\cdot D_{2D}=\xi \cdot C_{q0},}$

is DOS definition of the quantum capacitance per unit area according to Luryi, ^[1] and ${\displaystyle C_{q0}=4\pi \alpha \cdot C_{qY}}$ is the elementary quantum capacitance per unit area at ${\displaystyle \xi =1}$, and another ideal quantum capacitance per unit area is: ^[3]

${\displaystyle C_{qY}=\frac{{\epsilon }_0}{{\lambda }_0}=3.6492417}$ F/m²,

where ${\displaystyle {\epsilon }_0}$ is the electric constant.

The standard wave impedance definition for the QHE LC circuit can be presented as:

${\displaystyle {\rho }_Q=\sqrt{\frac{L_{QA}}{C_{QA}}}=\sqrt{\frac{{\varphi }_0^2}{e^2}}=R_K}$,

where ${\displaystyle R_K=\frac{h}{e^2}=25.812813k\mathrm{\Omega }}$ is the von Klitzing constant for resistance.

The standard resonant frequency definition for the QHE LC circuit can be presented as:

${\displaystyle {\omega }_Q=\frac{1}{\sqrt{L_{QA}{C}_{QA}}}=\frac{\hslash {\omega }_c}{{\varphi }_{0}e}=\frac{{\omega }_c}{2\pi }}$,

where ${\displaystyle {\omega }_c=\frac{eB}{m^{*}}}$ is the standard cyclotron frequency in the magnetic field ${\displaystyle B}$.

The first quantum inductance, based on the density of states approach was introduced by Wang et al. (2007) ^[4]. These authors modernized Buttiker approach (1993) ^[5] considering quantum dot (QD, labeled by “I”), placed over the metallic electrode (ME, labeled by “II”), and quantum capacitance. The quantum dot has the injected charge and induced charge per unit of area:

${\displaystyle Q_I=Q_I^{inj}+Q_I^{ind}}$,

where injection charge is:

${\displaystyle Q_I^{inj}=e^2{D}_I{v}_I}$,

and induced charge is:

${\displaystyle Q_I^{ind}=-e^2{D}_I{V}_I}$.

Therefore the resulting charge will be

${\displaystyle Q_I=e^2{D}_I(v_I-V_I)=C_0(V_I-V_{II})=C_{\mu }(v_I-v_{II})}$,

${\displaystyle Q_{II}=-Q_I=e^2{D}_{II}(V_{II}-v_{II})}$,

where ${\displaystyle D_I}$ and ${\displaystyle D_{II}}$ are frequency dependent density of states for QD and ME, ${\displaystyle v_I}$ and ${\displaystyle v_{II}}$ are the external AC potentials applied to the QD and ME and ${\displaystyle C_{\mu }}$ is a frequency dependent capacitance per unit of area connected with the potentials; ${\displaystyle V_I}$ and ${\displaystyle V_{II}}$ are the proper frequency dependent electric potentials due to QD and ME, and ${\displaystyle C_0}$ is a capacitance per unit of area connected with the potentials.

From the above we can obtain the following equation for the quantum capacitance per unit of area of the considered quantum system:

${\displaystyle \frac{e^2}{C_{\mu }}=\frac{e^2}{C_0}+\frac{1}{D_I}+\frac{1}{D_{II}}}$.

The quantum density of states for QD as a function of frequency ${\displaystyle \omega }$ can be expressed as:

${\displaystyle D_I(\omega )=\frac{{\mathrm{\Gamma }}_L}{2\pi \hslash \omega (\hslash \omega +i{\mathrm{\Gamma }}_L)}[\frac{1}{2}\ln \frac{{\mathrm{\Delta }}^2}{{\mathrm{\Delta }}_{+}{\mathrm{\Delta }}_{-}}-i(\arctan \frac{\mathrm{\Delta }E-\hslash \omega }{{\mathrm{\Gamma }}_L/2}-\arctan \frac{\mathrm{\Delta }E+\hslash \omega }{{\mathrm{\Gamma }}_L/2})],}$

where ${\displaystyle \mathrm{\Delta }=\mathrm{\Delta }{E}^2+{\mathrm{\Gamma }}_L^2/4,}$ and ${\displaystyle {\mathrm{\Delta }}_{\pm }=(\mathrm{\Delta }E\pm \hslash \omega {)}^2+{\mathrm{\Gamma }}_L/4,}$ and ${\displaystyle \mathrm{\Delta }E=E_F-E_0.}$

For the quantum capacitor at low frequencies, there exists a charge relaxation resistance: ${\displaystyle R_q=\frac{h}{2e^2}}$, for a single channel plate. Therefore, the considered system has the charge build-up time per unit of area due to the RC-time:

${\displaystyle {\tau }_{RC}=R_q{C}_{\mu }}$.

However, the complexity of the density of states quantum capacitance produces another dwell time parameter ${\displaystyle {\tau }_d}$ per unit of area, due to the quantum inductance. Actually, the general expression for quantum capacitance per unit of area can be expanded into a Taylor series to second order in frequency:

${\displaystyle C_{\mu }(\omega )=C_{\mu 0}+i\omega C_{\mu 0}^2\frac{h}{2e^2}-{\omega }^2{C}_{\mu 0}^3\frac{h^2}{4e^4}+{\omega }^2{C}_{\mu 0}^2\frac{h^2}{12\pi {\mathrm{\Gamma }}_L{e}^2}}$,

where ${\displaystyle C_{\mu }(\omega =0)=C_{\mu }(0)=C_{\mu 0}}$ on the right hand side is the static electrochemical capacitance.

For a classical RLC circuit with capacitance ${\displaystyle C_{\mu 0}}$, resistance ${\displaystyle R_q}$ and inductance ${\displaystyle L_q}$, the dynamic conductance is

${\displaystyle G(\omega )=\frac{-i\omega C_{\mu 0}}{1-{\omega }^2{L}_q{C}_{\mu 0}-i\omega C_{\mu 0}{R}_q}}$,

Expanding this expression in power series of ${\displaystyle \omega }$, we obtain

${\displaystyle G(\omega )=-i\omega C_{\mu 0}+{\omega }^2{C}_{\mu 0}^2{R}_q+i{\omega }^3{C}_{\mu 0}^3{R}_q^2-i{\omega }^3{C}_{\mu 0}^2{L}_q}$.

Since a capacitor conductance ${\displaystyle G(\omega )=-i\omega C_{\mu }(\omega )}$, we obtain the following values for quantum resistance and inductance per unit of area:

${\displaystyle R_q=h/2e^2=R_K/2}$,

${\displaystyle L_q=\frac{h^2}{12\pi e^2{\mathrm{\Gamma }}_L}=\frac{h{R}_K}{12\pi {\mathrm{\Gamma }}_L}}$,

where ${\displaystyle R_K=\frac{h}{e^2}}$ is the von Klitzing constant.

Let us consider in more detail obtained values of reactive parameters of the system per unit of area:

${\displaystyle C_{\mu }=\frac{e^2}{12\pi {\mathrm{\Gamma }}_L},}$

${\displaystyle L_q=\frac{h{R}_K}{12\pi {\mathrm{\Gamma }}_L}=2\pi R_K\frac{m_e}{h}=2\beta \frac{L_{QY}}{S_0},}$

${\displaystyle {\tau }_d=\frac{4\hslash }{{\mathrm{\Gamma }}_L},}$

${\displaystyle {\omega }_q=\frac{1}{\sqrt{C_{\mu }{L}_q}}=\frac{12\pi {\mathrm{\Gamma }}_L}{h},}$

${\displaystyle {\rho }_q=\sqrt{\frac{L_q}{C_{\mu }}}=R_K,}$

where line width function:

${\displaystyle {\mathrm{\Gamma }}_L=\frac{h^2}{24{\pi }^2{m}_e}=\frac{1}{12\pi }\frac{1}{D_{2D}}.}$

So, we have the first definition of quantum inductance for the DOS.

In the general case the characteristic impedance of RLC circuit can be defined as:

${\displaystyle Z_d=\sqrt{R_d+(\frac{1}{\omega C_d}-\omega L_d{)}^2}}$.

The resonant parameters of the RLC circuit (without dissipation, when ${\displaystyle R_d=0}$ and ${\displaystyle Z_d=0}$ ) will be:

${\displaystyle {\omega }_d=\frac{1}{\sqrt{L_d{C}_d}}}$,

${\displaystyle {\rho }_d=\sqrt{\frac{L_d}{C_d}}}$.

Semi-classical inductance and capacitance could be defined through the quantum values by the following: ${\displaystyle L_d=L_0+\mathrm{\Delta }L}$ and ${\displaystyle C_d=C_0+\mathrm{\Delta }C}$.

So, the resulting value of quantum resonant impedance will be: ${\displaystyle {\rho }_0=\sqrt{\frac{L_0}{C_0}}=\sqrt{\frac{{\mu }_0}{{\epsilon }_0}}}$ (impedance of free space).

Let us consider in more detail the semi-classical wave impedance in the form:

${\displaystyle {\rho }_d=\sqrt{\frac{L_d}{C_d}}=\sqrt{\frac{L_0+{\mathrm{\Delta }}_L}{C_0+{\mathrm{\Delta }}_C}}}$.

Expanding this expression in power series of ${\displaystyle {\mathrm{\Delta }}_C}$ and ${\displaystyle {\mathrm{\Delta }}_L}$, we shall obtain for the first order:

${\displaystyle {\rho }_d={\rho }_0[1+\frac{1}{2}(\frac{{\mathrm{\Delta }}_L}{L_0}-\frac{{\mathrm{\Delta }}_C}{C_0})]}$.

Considering that ${\displaystyle {\mathrm{\Delta }}_L=L_d-L_0}$ and ${\displaystyle {\mathrm{\Delta }}_C=C_d-C_0}$, the semi-classical wave impedance can be rewritten as:

${\displaystyle {\rho }_d={\rho }_0[1+\frac{1}{2}(\frac{L_d}{L_0}-\frac{C_d}{C_0})]}$.

The first semi-classical resonant LC circuit was discovered by Yakymakha (1994) ^[3] during MOSFET spectroscopic investigation in the frequency band 100H – 20kH. Obtained value for the cycle resonance frequency (5088 rad/s), permits to make estimations for the quantum reactive MOSFETs parameters. Quantum capacitance was defined as:

${\displaystyle C_{0X}=\frac{{\epsilon }_0{S}_{MOS}}{{\lambda }_0}\cdot \frac{{\lambda }_{CX}}{{\lambda }_0}}$

where ${\displaystyle S_{MOS}}$ is the MOSFET surface area and ${\displaystyle {\lambda }_{CX}}$ is the flat quantum capacitance thickness.

Quantum inductance was defined as:

${\displaystyle L_{0X}=\frac{{\mu }_0{S}_{MOS}}{{\lambda }_0}\cdot \frac{{\lambda }_{LX}}{{\lambda }_0}}$,

where ${\displaystyle {\lambda }_{LX}}$ is the flat quantum inductance thickness.

Experimental results prove that flat quantum inductance and capacitance thicknesses were about the Compton wavelength of electron:

${\displaystyle {\lambda }_{CX}={\lambda }_{LX}={\lambda }_0}$.

The first attempts were made by Cage and Jeffery (1996) ^[6] to consider QHE devices as resonant LC circuit. These investigations were made due to the program of the AC-measuring resistor standards. However, the considered model used only classical approach to the reactive parameters of the Landau levels.

• Quantum capacitance
• Quantum Electromagnetic Resonator

Template:Reflist

• Jian Wang, Baigeng Wang, and Hong Guo (2007). "Quantum inductance and negative electrochemical capacitance at finite frequency in a two-plate quantum capacitor". Phys. Rev. B 75, 155336