Calculate Effective Mobility Using Square Law Fitting | MOSFET Analyzer

Calculate Effective Mobility Using Square Law Fitting

Analyze MOSFET transfer characteristics and extract field-effect mobility.

Drain Current (I_D) in Saturation

Measured drain current in Amperes (A).

Value must be greater than zero.

Gate-Source Voltage (V_GS)

Applied gate voltage in Volts (V).

V_GS must be higher than V_th.

Threshold Voltage (V_th)

Extracted threshold voltage in Volts (V).

Channel Width (W)

Width of the transistor channel in micrometers (μm).

Channel Length (L)

Length of the transistor channel in micrometers (μm).

Oxide Thickness (t_ox)

Thickness of the gate dielectric in nanometers (nm).

Effective Mobility (μ_eff)
0.00
cm² / V·s

Oxide Capacitance (C_ox)
0.00 F/cm²

Aspect Ratio (W/L)
0.00

Overdrive Voltage (V_GS – V_th)
0.00 V

Sqrt Drain Current (√I_D)
0.00 A^1/2

Square Law Fitting Curve (√I_D vs V_GS)

The chart illustrates the linear fit of √I_D against V_GS as per the square law model.

What is Calculate Effective Mobility Using Square Law Fitting?

In semiconductor physics and device characterization, the ability to calculate effective mobility using square law fitting is fundamental for evaluating MOSFET performance. Carrier mobility (μ) represents how quickly an electron or hole can move through a metal or semiconductor when pulled by an electric field. The “square law” refers to the ideal saturation region current-voltage relationship of a MOSFET.

Researchers and engineers use this method to extract parameters from experimental data. By plotting the square root of the drain current (√I_D) against the gate-to-source voltage (V_GS), a linear relationship should emerge in the saturation region. The slope of this line is directly proportional to the carrier mobility, allowing for a standardized way to compare different fabrication processes or semiconductor materials.

Common misconceptions include assuming mobility is a constant value across all operating voltages. In reality, effective mobility decreases at high gate voltages due to surface roughness scattering and transverse electric fields, which is why “square law fitting” is typically performed in a specific linear range above the threshold voltage.

Calculate Effective Mobility Using Square Law Fitting: Formula and Math

The standard square law equation for a MOSFET in the saturation region (V_DS > V_GS – V_th) is:

I_D = (μ_eff · C_ox · W / 2L) · (V_GS – V_th)²

To calculate effective mobility using square law fitting, we rearrange the formula to solve for μ_eff:

μ_eff = (2 · L · I_D) / (W · C_ox · (V_GS – V_th)²)

Variable	Meaning	Unit	Typical Range
I_D	Drain Current	Amperes (A)	10^-9 to 10^-1
V_GS	Gate-Source Voltage	Volts (V)	0 to 20
V_th	Threshold Voltage	Volts (V)	0.1 to 2.0
W	Channel Width	μm	1 to 1000
L	Channel Length	μm	0.01 to 100
C_ox	Oxide Capacitance	F/cm²	10^-8 to 10^-6

Practical Examples of Effective Mobility Calculation

Example 1: Standard Si-MOSFET

Suppose you have a silicon MOSFET with W = 100 μm, L = 10 μm, and an oxide thickness (SiO2) of 50 nm. If the measured drain current is 5 mA at V_GS = 5V and V_th = 1.2V, we first calculate C_ox (≈ 6.9e-8 F/cm²). Applying the formula to calculate effective mobility using square law fitting, we find a mobility of approximately 415 cm²/V·s, which is typical for bulk silicon N-channel MOSFETs.

Example 2: Thin-Film Transistor (TFT)

A researcher develops a new organic TFT with W = 1000 μm, L = 50 μm, and t_ox = 300 nm. At V_GS = 20V and V_th = 5V, they measure I_D = 20 μA. Using the square law fitting tool, the effective mobility is calculated at 0.051 cm²/V·s. This helps the researcher conclude that their material is suitable for low-speed flexible displays but not high-speed logic.

How to Use This Calculator

Enter Drain Current: Input your measured saturation current (I_D) in Amperes.
Define Voltages: Enter your applied Gate Voltage (V_GS) and the device’s Threshold Voltage (V_th). Note: V_GS must be greater than V_th.
Geometry Parameters: Provide the Channel Width (W) and Length (L) in micrometers.
Oxide Details: Enter the Oxide Thickness (t_ox) in nanometers. The tool automatically assumes SiO2 permittivity (3.9) to find C_ox.
Analyze Results: The calculator updates in real-time, showing μ_eff and a fitting curve.

Key Factors That Affect Effective Mobility Results

When you calculate effective mobility using square law fitting, several physical phenomena can cause deviations from the ideal model:

Surface Roughness Scattering: As V_GS increases, carriers are pushed harder against the oxide-semiconductor interface, slowing them down and reducing mobility.
Phonon Scattering: High temperatures increase lattice vibrations, which collide with carriers and decrease effective mobility.
Short Channel Effects: In very small devices (L < 1 μm), velocity saturation prevents the current from following the square law, leading to inaccurate mobility extraction.
Contact Resistance: If source/drain contacts are poor, the measured V_GS is not the actual voltage at the channel, causing an underestimation of mobility.
Gate Dielectric Quality: Trapped charges at the interface or within the oxide create Coulomb scattering, significantly lowering μ_eff in low-quality films.
Doping Concentration: Higher substrate doping levels increase impurity scattering, which typically lowers the peak mobility compared to lightly doped samples.

Frequently Asked Questions (FAQ)

1. Why is square law fitting used in saturation instead of the linear region?

In saturation, the I_D-V_GS relationship is squared, which simplifies the extraction of μ through the √I_D vs V_GS plot slope. The linear region requires knowledge of V_DS and is more sensitive to contact resistance.

2. Can I use this for P-channel MOSFETs?

Yes. While the polarity of voltages and currents are reversed, the absolute magnitudes are used in the same square law formula to calculate hole mobility.

3. What is the difference between field-effect mobility and effective mobility?

Field-effect mobility (μ_FE) is derived from transconductance (g_m), while effective mobility (μ_eff) is derived from drain conductance. Square law fitting usually yields a value close to μ_FE.

4. How does oxide thickness affect the calculation?

Oxide thickness determines C_ox. A thinner oxide results in higher capacitance, meaning the same current can be achieved with a lower mobility or lower voltage.

5. What if my Vgs is lower than Vth?

The device is in the “subthreshold” or “cut-off” region. The square law does not apply here; current flows via diffusion rather than drift.

6. Does the calculator handle high-k dielectrics?

This specific calculator uses the permittivity of SiO2 (3.9). For high-k materials, the effective oxide thickness (EOT) should be used instead.

7. Why is my calculated mobility much lower than the textbook value?

Textbook values are for pure bulk crystals. Thin films, polycrystalline materials, or devices with high interface traps naturally have much lower mobility.

8. How accurate is the square law model?

It is a first-order approximation. It works well for “long-channel” devices but loses accuracy for modern nanometer-scale transistors.

Related Semiconductor Characterization Tools

Semiconductor Physics Basics – Learn the fundamentals of carrier transport.
MOSFET Characterization Techniques – Advanced methods for parameter extraction.
Thin-Film Transistor Analysis – Specific guides for TFT and organic electronics.
Carrier Transport Mechanisms – Understanding drift, diffusion, and scattering.
Oxide Capacitance Calculator – Calculate C_ox for various dielectric materials.
Threshold Voltage Derivation – Mathematical background for extracting V_th.

Square Law Fitting Curve (√ID vs VGS)