PHT.301 Physics of Semiconductor Devices
04.03.2022

Problem 1
Consider a pn-junction.

(a) If there is no voltage applied, there is no current. Nevertheless there is an electric field. Provide the formulas for the drift current and the diffusion current and using these formulas write down the equation that states there is not current.

(b) If the junction is reverse biased, what is the expression for the capacitance?

(c) State the relationship between the hole concentration on the p-side, the hole concentration on the n-side, and the built-in voltage $V_{bi}$.

Solution

<hr />

<p><b>(a)</b></br></br>
If there is no external voltage applied to the pn-junction, drift and diffusion current are in equilibrium and cancel each other out.</br> The current density equations for diffusion and drift are given by:</p>
\begin{equation*}
	\left.\begin{aligned}
	\vec{j}_{n,diff}  &= e * D_n * \nabla n \\
	\vec{j}_{p,diff}  &= -e * D_p * \nabla p \\
	\vec{j}_{n,drift} &= -n * e * \mu_n * \vec{E} \\
	\vec{j}_{p,drift} &= p * e * \mu_p * \vec{E}
	\end{aligned}
	\right\}
    \begin{aligned}
	\vec{j}_{n,total} &= \vec{j}_{n,diff} + \vec{j}_{n,drift} = \vec{0}  \\
	\vec{j}_{p,total} &= \vec{j}_{p,diff} + \vec{p}_{n,drift} = \vec{0}
	\end{aligned}
\end{equation*}

<p>The Einstein relation provides us the basics to derive the diffusion constant and show that the current denisties cancel each other out.</br> Derived for electrons, similar for holes:</p>
\begin{equation*}
	\vec{E} = - \nabla V\;, \;\; n = A * exp \bigg( \frac{-e*V}{k_B * T} \bigg) \\
	\nabla n=-\frac{e}{k_B * T} * A * exp \bigg(\frac{-e * V}{k_B * T} \bigg) * \nabla V=-\frac{n * e}{k_B * T} * \nabla V=\frac{n * e * \vec{E}}{k_B * T}\\
	\vec{j}_{n,drift} + \vec{j}_{n,diff} = -n * e * \mu_n * \vec{E} + e * D_n * \nabla n = \vec{0}\\
	-e * n * \mu_n * \vec{E} + e * D_n * \frac{n * e * \vec{E}}{k_B * T}=\vec{0}\\
	D_n=\frac{\mu_n * k_B * T}{e}
\end{equation*}
</br>

<hr>
<p><b>(b)</b></br></br> 
The depletion width of an abrupt pn-junction is given by:</p>
\begin{equation*}
	W=\frac{\varepsilon}{C_j}=\sqrt{\frac{2 * \varepsilon * \left(N_D + N_A\right) * (V_{bi}-V)}{e * N_D * N_A}}
\end{equation*}

<p>The built-in voltage is given by:</p>
\begin{equation*}
	V_{bi}=\frac{k_B * T}{e} * \ln \left(\frac{N_D * N_A}{n_i^2}\right)
\end{equation*}

<p>The expression for the specific capacitance:</p>
\begin{equation*}
	C_j=\frac{\varepsilon}{W}
\end{equation*}
</br>

<hr>
<p><b>(c)</b></p>
<div style="display:block; width:100%;">
	<div style="width:40%; float: left; display: inline-block;">
		<center>
			\begin{equation*}
			\begin{aligned}
				& n_i^2 = n_{p0} * p_{p0} = n_{n0} * p_{n0}\\			
				& n_p\left(x_p\right) = N_D * \exp \left(\frac{-e * \left(V_{bi}-V\right)}{k_B * T}\right)\\
				& p_n\left(x_n\right) = N_A * \exp \left(\frac{-e * \left(V_{bi}-V\right)}{k_B * T}\right)\\
				& e*V_{bi} = k_B * T * \ln \left(\frac{N_D * N_A}{n_i^2}\right)\\
				& e*V_{bi} = k_B * T * \ln \left(\frac{N_D}{n_{p0}}\right)\\
				& e*V_{bi} = k_B * T* \ln \left(\frac{N_A}{p_{n0}}\right)
			\end{aligned}
			\end{equation*}
		</center>
	</div>
	
	<div style="width:60%; float: left; display: inline-block;">
		<img src="1_c_pn_junction_carrier_densities.png" width="458" height="333" alt="picture carrier densities pn junction">
	</div>
</div>

Problem 2

Consider an n-channel JFET biased in saturation.

(a) How are the gate-source and gate-drain pn-junctions biased (forward or reverse)?

(b) If a large enough voltage is applied to the drain, breakdown will occur. How can a JFET be modified to increase the breakdown voltage?

(d) What determines the resistivity of the channel? Provide a formula if you can.

Solution

<hr />
<p><b>(a)</b></p>
<div style="display:block; width:100%;">
	<div style="width:40%; float: left; display: inline-block;">
	<p>The depletion mode n-channel JFET is normally conducting. A drain current $I_{D}$ will flow when a positive voltage is applied between drain and source. This leads to a voltage drop along the channel. By decreasing the gate-source voltage, the pn-junction is getting more reversed biased. Due to the voltage drop along the channel, the depletion width is linearly distributed from drain to source. At pinch-off, channel gets cut off and the saturation current $I_{D,SAT}$ is reached. Increasing the drain-source voltage in saturation, does not change the drain current. That means that the gate-source and the gate-drain pn-junction are reversed biased in saturation.</p>
	</div>
	<div style="width:60%; float: left; display: inline-block;">
		<img src="2_a_n_channel_jfet_saturation_diodes.png" height="250" alt="picture n channel jfet saturation diodes">
	</div>
</div>

<hr>
<p><b>(b)</b></br></br>
The possibility for the breakdown at the pn-junction between drain and gate is higher than anywhere else, </br> because this is the point of the highest electric field. The distance between gate and drain can be increased, </br> the doping concentration between gate and drain can be decreased (lightly doped drain extension) or </br> shallow tranch isolation (STI) can be implemented.</p>

<hr>
<p><b>(c)</b></p>
<div style="display:block; width:100%;">
	<div style="width:40%; float: left; display: inline-block;">
	<p>The n-channel JFET in saturation has a huge depletion region at the channel. Light creates an electron-hole pair in the depletion region, if the energy of the light is big enough. Ignoring recombination, there is an electric field in the depletion region pointing from channel to gate. In addition, an electric field between drain and source is present. Because of this electric fields, the electrons get accelerated to the drain and the holes get accelerated to the source. This increases the drain current.</p>
	</div>
	<div style="width:60%; float: left; display: inline-block;">
		<img src="2_c_n_channel_jfet_saturation_light.png" height="200" alt="picture n channel jfet saturation light">
	</div>
</div></p>

<hr>
<p><b>(d)</b></p>
<p> At saturation, the JFET works as a voltage controlled current source. Ideally, the saturation current $I_{D,SAT}$ </br>is dependent on the gate-source voltage, but not on the drain-source voltage. An increase of the drain-source voltage </br> does not implement a higher current. Out of the gradual channel approximation we get: </p>

\begin{equation*}
	I_{D,SAT}=I_p * \left[\frac{1}{3}-\frac{V_{bi}-V_G}{V_p}+\frac{2}{3} * \left(\frac{V_{bi}-V_G}{V_p}\right)^\frac{3}{2}\right] \;\; with \;\; I_p = \frac{\mu_n N_D^2 Z e^2 h^3}{2 L \varepsilon} \;\; and \;\; V_p = \frac{e N_D h^2}{2 \varepsilon}
\end{equation*}

<p>One is not able to built a ratio between drain-source voltage vs. drain current out of this equation. </br> For simplification, the drain current is assumed constant in saturation. This leads to a linear relationship:</p>
\begin{equation*}
	R_{DS} = \frac{V_{DS}}{I_{D,SAT}}
\end{equation*}

Problem 3
(a) Draw a cross section of an $n$-channel MESFET showing the source, drain, and gate contacts.

(b) Draw the band diagram (conduction band, valence band, Fermi energy) from the gate to body when no voltage is applied.

(c) What polarity do the voltages have (positive or negative) at the gate and drain when an n-channel MESFET is biased in saturation?

(d) What is thermionic emmission and when does a thermionic emmission current flow in a MESFET?

Solution

<hr>
<p><b>(c)</b></p>
<div style="display:block; width:100%;">
	<div style="width:40%; float: left; display: inline-block;">
	<p>The n-channel MESFET works with the same principle as the n-channel JFET but the pn-junction is replaced by a schottky-contact. Voltage between gate and source has to be negative and the voltage between drain and source has to be positive to pinch-off the channel and bias the MESFET in saturation. </p>
	</div>
	<div style="width:60%; float: left; display: inline-block;">
		<img src="3_c_n_channel_mesfet_polarities.png" height="200" alt="picture n channel mesfet polarities">
	</div>
</div>

<hr>
<p><b>(d)</b></p>
<div style="display:block; width:100%;">
	<div style="width:40%; float: left; display: inline-block;">
	<p>Between the gate and the channel is a schottky-contact. Thermionic emission entails, some off the electrons have thermal energy that exceed the work function and can swop over the energy barrier caused by the schottky-contact.</br></br>
	
	For schottky diodes there is no recombination of electron-hole pairs required. Thus, the nonideality factor is equal to 1. Majority carriers swop over. Thermionic emission dominates over diffusion current in a schottky diode.</br></br>
	
	</div>
	<div style="width:60%; float: left; display: inline-block;">
		<img src="3_d_thermionic_emission_mesfet_fermi_function.png" height="250" alt="picture thermionic emission mesfet fermi function"></img>
	</div>
</div>
<br></br>
<div style="display:block; width:100%;">
	<div style="width:40%; float: left; display: inline-block;">
	<p>	Schottky diode current equations:</br></p>
	\begin{equation*}
		I=I_{sm}+I_{ms}=I_s * \left(e^\frac{e * V}{k_B * T}-1\right) \;\;\;\;\;\; I_{sm} = I_{ms} \;\; (V=0)
	\end{equation*}
	
	\begin{equation*}	
		I_s=A * {A_R} * T^2 * \exp \left(\frac{-e * \phi_b}{k_B * T}\right)
	\end{equation*}
	</div>
	
	<div style="width:60%; float: left; display: inline-block;">
		<img src="3_d_schottky_barrier_foward_reverse_biased.png" height="400" alt="picture schottky barrier foward / reverse biased">
	</div>
</div>

Problem 4

(a) Plot the minority carrier concentration in an npn bipolar transistor in forward active mode.

(b) Why is a heterojunction bipolar transistor faster than a normal bipolar transistor?

(d) In an npn transistor, where do the holes in the base current recombine?

Solution

<hr>
<p><b>(b)</b></br></br>
	A HBT makes use of two materials with different bandgaps. The emitter bandgap is higher than the base bandgap. </br> This leads, compared to a BJT to a significant higher gain. Injection efficiency is much more improved leading to a higher gain. </br> But as that much gain is in most cases not needed it can be relaxed to improve so that base doping is higher than emitter doping.</br></br>
	Trade off with gain for higher speed!</br></br>
	Higher base doping leads to:</br>
	<p><ul>
		<li> lower base resistance</li>
		<li> reduced early effect</li>
		<li> less trouble with punch through</li>
		<li> base can be made thinner $\rightarrow$ faster transistors</li>
		<li> because of higher base doping, a higher collector doping is possible without punch through</li>
		<li> lower collector resistance</li>
	</ul></p>
</p>

<hr>
<p><b>(c)</b></p>
<div style="display:block; width:100%;">
	<div style="width:40%; float: left; display: inline-block;">
	<p>Because of the highly doped emitter, the depletion region of the base-emitter junction reaches much more into the base than into the emitter. On the other hand, the depletion region from the base-collector junction reaches into the base. 
	</br></br>
	Early effect: As VCE increases the neutral base region width decreases thus base gets thinner and β0 increases (better base transport factor) thus the current ICE increases. </br></br>
	Punch through: The neutral base width goes to zero and all the gain is lost. Without any control of the base a current flow. Electrons are injected to the base and are pushed to the collector.</p>
	</div>
	<div style="width:60%; float: left; display: inline-block;">
		<img src="4_c_npn_bipolar_transistor_cross_section.png" height="300" alt="picture npn bipolar transistor cross section">
	</div>
</div>

<hr>
<p><b>(d)</b></br></br>
The hole diffusion current originated from the base, does not affect the collector. </br> The holes move towards the emitter and recombine with injected electrons from the emitter. </br> The main part of the electron current flows from the emitter to the collector but a small part </br> is needed in the base for the recombination with the holes from the base connection. </br> This part is necessary for the function of the transistor. The more electrons are available, </br> the greater is the probability that a hole meets an electron and recombined. </br> The (bigger) electron current in the emitter is directly proportional to the (small) hole current of the base.</p>

Quantity	Symbol	Value	Units
electron charge	e	1.60217733 × 10^-19	C
speed of light	c	2.99792458 × 10⁸	m/s
Planck's constant	h	6.6260755 × 10^-34	J s
reduced Planck's constant	$\hbar$	1.05457266 × 10^-34	J s
Boltzmann's constant	k_B	1.380658 × 10^-23	J/K
electron mass	m_e	9.1093897 × 10^-31	kg
Stefan-Boltzmann constant	σ	5.67051 × 10^-8	W m^-2K^-4
Bohr radius	a₀	0.529177249 × 10^-10	m
atomic mass constant	m_u	1.6605402 × 10^-27	kg
permeability of vacuum	μ₀	4π × 10^-7	N A^-2
permittivity of vacuum	ε₀	8.854187817 × 10^-12	F m^-1
Avogado's constant	N_A	6.0221367 × 10²³	mol^-1

PHT.301 Physics of Semiconductor Devices04.03.2022

PHT.301 Physics of Semiconductor Devices
04.03.2022