Unterschiede
Hier werden die Unterschiede zwischen zwei Versionen angezeigt.
| Beide Seiten der vorigen Revision Vorhergehende Überarbeitung Nächste Überarbeitung | Vorhergehende Überarbeitung | ||
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electrical_engineering_2:the_stationary_electric_flow [2023/03/16 15:38] mexleadmin |
electrical_engineering_2:the_stationary_electric_flow [2024/03/29 19:57] (aktuell) mexleadmin |
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| Zeile 1: | Zeile 1: | ||
| - | ====== 2. The stationary Current Density and Flux ====== | + | ====== 2 The stationary Current Density and Flux ====== |
| < | < | ||
| Zeile 9: | Zeile 9: | ||
| In the discussion of the electrostatic field in principle, no charges in motion were considered. Now the motion of charges shall be considered explicitly. | In the discussion of the electrostatic field in principle, no charges in motion were considered. Now the motion of charges shall be considered explicitly. | ||
| - | The current density here describes how charge carriers move together (collectively). The stationary current density describes the charge carrier movement if a **direct voltage** | + | The current density here describes how charge carriers move together (collectively). The stationary current density describes the charge carrier movement if a **direct voltage** |
| $\large{{{\rm d}I}\over{{\rm d}t}}=0$ | $\large{{{\rm d}I}\over{{\rm d}t}}=0$ | ||
| Zeile 35: | Zeile 35: | ||
| < | < | ||
| - | For this purpose, a packet of charges ${\rm d}Q$ is considered, which will pass the area $A$ during the period ${\rm d}t$ (see <imgref imageNo02> | + | For this purpose, a packet of charges ${\rm d}Q$ is considered, which will pass the area $A$ during the period ${\rm d}t$ (see <imgref imageNo02> |
| ~~PAGEBREAK~~ ~~CLEARFIX~~ | ~~PAGEBREAK~~ ~~CLEARFIX~~ | ||
| Zeile 43: | Zeile 43: | ||
| The flowing charges contained in the partial volume element $dV$ are then (with elementary charge $e_0$): | The flowing charges contained in the partial volume element $dV$ are then (with elementary charge $e_0$): | ||
| - | \begin{align*} | + | \begin{align*} |
| The current is then given by $I={{{\rm d}Q}\over{{\rm d}t}}$: | The current is then given by $I={{{\rm d}Q}\over{{\rm d}t}}$: | ||
| - | \begin{align*} I = n_e \cdot e_0 \cdot A \cdot {{{\rm d}x}\over{{\rm d}t}} = n_e \cdot e_0 \cdot A \cdot v_e \end{align*} | + | \begin{align*} I = n_{\rm e} \cdot e_0 \cdot A \cdot {{{\rm d}x}\over{{\rm d}t}} = n_e \cdot e_0 \cdot A \cdot v_{\rm e} \end{align*} |
| This leads to an electron velocity $v_e$ of: | This leads to an electron velocity $v_e$ of: | ||
| - | \begin{align*} v_\rm{e} = {{{\rm d}x}\over{{\rm d}t}} = {{I}\over{n_e \cdot e_0 \cdot A }} \end{align*} | + | \begin{align*} v_{\rm e} = {{{\rm d}x}\over{{\rm d}t}} = {{I}\over{n_{\rm e} \cdot e_0 \cdot A }} \end{align*} |
| In contrast to the considerations in electrostatics, | In contrast to the considerations in electrostatics, | ||
| - | With regard to the electron velocity $v_\rm{e} \sim {{I}\over{A}}$ it is obvious to determine a current density $S$ (related to the area): | + | With regard to the electron velocity $v_{\rm e} \sim {{I}\over{A}}$ it is obvious to determine a current density $S$ (related to the area): |
| \begin{align*} | \begin{align*} | ||
| Zeile 149: | Zeile 149: | ||
| <panel type=" | <panel type=" | ||
| - | A current of $I = 2\{\rm A}$ flows in a conductor made of copper with cross-sectional area $A$. \\ The electron density in copper is $n_{\rm e}({\rm Cu})=8.47 \cdot 10^{19} ~\rm{{1}\over{mm^3}}$ and the magnitude of the elementary charge $e_0 = 1.602 \cdot 10^{-19} ~\rm{As}$ | + | A current of $I = 2~{\rm A}$ flows in a conductor made of copper with cross-sectional area $A$. \\ The electron density in copper is $n_{\rm e}({\rm Cu})=8.47 \cdot 10^{19} ~{\rm {1}\over{mm^3}}$ and the magnitude of the elementary charge $e_0 = 1.602 \cdot 10^{-19} ~{\rm As}$ |
| - | - What is the average electron velocity $v_\rm{e,1}$ of electrons when the cross-sectional area of the conductor is $A = 1.5~\rm{mm}^2$? | + | - What is the average electron velocity $v_{\rm e,1}$ of electrons when the cross-sectional area of the conductor is $A = 1.5~{\rm mm}^2$? |
| - | - What is the average electron velocity $v_\rm{e,1}$ of electrons when the cross-sectional area of the conductor is $A = 1.0~\rm{mm}^2$? | + | - What is the average electron velocity $v_{\rm e,1}$ of electrons when the cross-sectional area of the conductor is $A = 1.0~{\rm mm}^2$? |
| </ | </ | ||
| Zeile 158: | Zeile 158: | ||
| <panel type=" | <panel type=" | ||
| - | Similar to task 2.1.2 a current of $I = 2~\rm{A}$ shall flow through a cross-sectional area $A = 1.5~\rm{mm}^2$ of semiconductors. \\ | + | Similar to task 2.1.2 a current of $I = 2~{\rm A}$ shall flow through a cross-sectional area $A = 1.5~{\rm mm}^2$ of semiconductors. \\ |
| - | (magnitude of the elementary charge $e_0 = 1.602 \cdot 10^{-19} ~\rm{As}$) | + | (magnitude of the elementary charge $e_0 = 1.602 \cdot 10^{-19} ~{\rm As}$) |
| - | - What is the average electron velocity $v_\rm{e,1}$ of electrons for undoped silicon (electron density $n_{\rm e}({\rm Si})=9.65 \cdot 10^{9} ~\rm{{1}\over{cm^3}}$ at room temperature)? | + | - What is the average electron velocity $v_{\rm e,1}$ of electrons for undoped silicon (electron density $n_{\rm e}({\rm Si})=9.65 \cdot 10^{9} ~{\rm {1}\over{cm^3}}$ at room temperature)? |
| - | - The electron density of doped silicon $n_\rm{e}(Si\; doped)$ is (mainly) given by the number of dopant atoms per volume. The doping shall provide 1 donator atom per $10^7$ silicon atoms (here: one donator atom shall release one electron). The molar volume of silicon is $12 \cdot 10^{-6}~\rm{{m^3}\over{mol}}$ with $6.022 \cdot 10^{23}$ silicon atoms per $\rm{mol}$. What is the average electron velocity $v_\rm{e,1}$ of electrons for doped silicon? | + | - The electron density of doped silicon $n_{\rm e}(Si\; doped)$ is (mainly) given by the number of dopant atoms per volume. The doping shall provide 1 donator atom per $10^7$ silicon atoms (here: one donator atom shall release one electron). The molar volume of silicon is $12 \cdot 10^{-6}~{\rm {m^3}\over{mol}}$ with $6.022 \cdot 10^{23}$ silicon atoms per ${\rm mol}$. What is the average electron velocity $v_{\rm e,1}$ of electrons for doped silicon? |
| Zeile 171: | Zeile 171: | ||
| < | < | ||
| - | ==== Targets | + | ==== Goals ==== |
| After this lesson, you should: | After this lesson, you should: | ||
| Zeile 240: | Zeile 240: | ||
| In transformer stations sometimes water resistors are used as {{wp> | In transformer stations sometimes water resistors are used as {{wp> | ||
| - | The water resistor consists of a water basin. In the given basin two quadratic plates with the edge length of $l = 80 ~\rm{cm}$ are inserted with the distance $d$ between them. | + | The water resistor consists of a water basin. In the given basin two quadratic plates with the edge length of $l = 80 ~{\rm cm}$ are inserted with the distance $d$ between them. |
| - | The resistivity of the water is $\rho = 0.25 ~\Omega \rm{m}$. The resistor shall dissipate the energy of $P = 4 ~\rm{kW}$ and shall exhibit a homogeneous current field. | + | The resistivity of the water is $\rho = 0.25 ~\Omega |
| - | - Calculate the required distance of the plates to get a current density of $S = 25 ~\rm{mA/cm^2}$ | + | - Calculate the required distance of the plates to get a current density of $S = 25 ~{\rm mA/cm^2}$ |
| - What are the values of the current $I$ and the voltage $U$ at the resistor, such as the internal electric field strength $E$ in the setup? | - What are the values of the current $I$ and the voltage $U$ at the resistor, such as the internal electric field strength $E$ in the setup? | ||
| </ | </ | ||