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618 326

618 326. Physics of electronic materials and devices I Lecture 8. Thermionic emission process. It is the phenomenon that carriers having high energy thermionically emitted into the vacuum. In other words, electrons escapes from the hot or high temperature surface of the material.

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618 326

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  1. 618 326 Physics of electronic materials and devices I Lecture 8

  2. Thermionic emission process • It is the phenomenon that carriers having high energy thermionically emitted into the vacuum. • In other words, electrons escapes from the hot or high temperature surface of the material. • This is called “thermionic emission process”.

  3. Thermionic emission process • Electron affinity q is the energy difference between the conduction band edge and the vacuum. • Work function q is the energy between the Fermi level and the vacuum level in the semiconductor.

  4. Thermionic emission process • It is clearly seen that an electron can thermionically escape from the semiconductor surface into the vacuum if its energy is above q. • The electron density with energies above q can be found by where Vn is the difference between the bottom of the conduction band and the Fermi level.

  5. Thermionic emission process • If escaping electrons with velocity normal to the surface and having energy greater than EF+ q, the thermionic current density is equal to

  6. Thermionic emission process • Then we use p = mv and, and after integration, it yields

  7. Example 1 • Calculate the thermionically emitted electron density nth at room temperature for an n-type silicon sample with an electron affinity q = 4.05 eV and qVn = 0.2 eV. If we reduce the effectiveq  to 0.6 eV, what is nth?

  8. Example 1 • Soln • As we clearly see that at the room temperature, there is no thermionic emission of electrons into the vacuum. This thermionic emission process is important for metal-semiconductor contacts.

  9. Tunneling Process • The figure shows the energy band when two semiconductor samples are brought close to each other. • The distance between them (d) is sufficient small, so that the electrons in the left-side semiconductor may transport across the barrier and move to the right-side semiconductor even the electron energy is much less than the barrier height. • This process is called “quantum tunneling process”.

  10. Tunneling Process • The transmission coefficient can be expressed as • This process is used in tunnel diodes by having a small tunneling distance d, a low potential barrier qV0, and a small effective mass.

  11. p-n Junction • A p-n junction plays a major role in electronic devices. • It is used in rectification, switching, and etc. • It is the simplest semiconductor devices. • Also, it is a key building block for other electronic, microwave, or photonic devices.

  12. Basic fabrication steps The basic fabrication steps for p-n junction include • oxidation, • lithography, • diffusion or ion implanation, • and metallization.

  13. Oxidation • This process is to make a high-quality silicon dioxide (SiO2) as an insulator in various devices or a barrier to diffusion or implanation during fabrication process. • There are two methods to grow SiO2: dry and wet oxidation, using dry oxygen and water vapor, respectively. • Generally, dry oxidation is used to form thin oxides because of its good Si-SiO2 interface characteristics, while wet oxidation is used for forming thicker layers since its higher growth rate.

  14. Lithography • This process is called photolithography used to delineate the pattern of the p-n junction.

  15. Lithography • (a) The wafer after the development. • (b) The wafer after SiO2 removal. • (c) The final result after a complete lithography process.

  16. Diffusion and Ion Implantation • This is used to put the impurity into the semiconductor. • For diffusion method, the semiconductor surface not protected by the oxide is exposed to a high concentration of impurity. The impurity moves into the crystal by solid-state diffusion. • For the ion-implantation method, the impurity is introduced into the semiconductor by accelerating the impurity ions to a high-energy level and then implanting the ions in the semiconductor.

  17. Metallization • This process is used to form ohmic contacts and interconnections. • After this process is done, the p-n junction is ready to use.

  18. p-n junction rectification • The forward biased voltage is normally less than 1 V and the current increases rapidly as the biased voltage increases. • As the reverse bias increases, the current is still small until a breakdown voltage is reached, where the current suddenly increases.

  19. Thermal equilibrium condition • Assume that both p- and n-type semiconductors are uniformly doped. • The Fermi level EF is near the valence band edge in the p-type material and near the conduction band edge in the n-type material.

  20. Thermal equilibrium condition • Electrons diffuse from n-side toward p-side and holes diffuse from p-side toward n-side. • As electrons leave the n-side, they leave behind the positive donor ions (ND+) near the junction. • In the same way, some of negative acceptor ions (NA-) are left near the junction as holes move to the n-side.

  21. Thermal equilibrium condition Space-charge region • The space-charge region is also called “depletion region” due to the depletion of free carriers. neutral neutral

  22. Thermal equilibrium condition • Carrier diffusion induces an internal electric field in the opposite direction to free charge diffusion. • Therefore, the electron diffusion current flows from left to right, whereas the electron drift current flows from right to left.

  23. Thermal equilibrium condition • At thermal equilibrium, the individual electron and hole current flowing across the junction are identically zero. • In the other words, the drift current cancels out precisely the diffusion current. Therefore, the equilibrium is reached as EFn = EFp.

  24. Thermal equilibrium condition • The space-charge density distribution and the electrostatic potential  are given by Poisson’s equation as (1)

  25. Thermal equilibrium condition • Assume that all donor and acceptor atoms are ionized. • Assume NA = 0 and n >> p for n-type neutral region and ND = 0 and p >> n for p-type neutral region.

  26. Thermal equilibrium condition • The electrostatic potential  in of the n- and p-type with respect to the Fermi level can be found with the help of and as (2) (3)

  27. Thermal equilibrium condition • The total electrostatic potential difference between the p-side and the n-side neutral region is called the “built-in potential” Vbi. It is written as (4)

  28. p-n junction • a) A p-n junction with abrupt doping changes at the metallurgical junction. • (b) Energy band diagram of an abrupt junction at thermal equilibrium. • (c) Space charge distribution. • (d) Rectangular approximation of the space charge distribution.

  29. Example 2 • Calculate the built-in potential for a silicon p-n junction with NA = 1018cm-3 and ND = 1015 cm-3 at 300 K. • Soln

  30. Depletion Region The p-n junction may be classified into two classes depending on its impurity distribution: • the abrupt junction and • the linearly graded junction.

  31. Abrupt junction • An abrupt junction can be seen in a p-n junction that is formed by shallow diffusion or low-energy ion implantation. • The impurity distribution in this case can be approximated by an abrupt transition of doping concentration between the n- and the p-type regions.

  32. Linearly graded junction • In the linearly graded junction, the p-n junction may be formed by deep diffusions or high-energy ion implantations. • The impurity distribution varies linearly across the junction.

  33. Abrupt Junction • Consider an abrupt junction as in the figure above, equation (1) can be written as (5)

  34. Abrupt junction • The charge conservation is expressed by the condition Q = 0 or (6) To solve equation (5), we need to solve it separately for p-and n-type cases.

  35. Abrupt junction

  36. Abrupt junction (7)

  37. Abrupt junction n-side: • Similarly, we can have (8) Let consider at x = 0 (9)

  38. Abrupt junction • We may relate this electric field E to the potential over the depletion region as (10)

  39. Abrupt junction • From (6), we have (11)

  40. Abrupt junction • Substitute (11) into (10), this yields (12)

  41. Abrupt junction • Hence, the space-charge layer width or depletion layer width can be written as (13)

  42. Example 3 Si p-n diode of NA = 5 x 1016 cm-3 and ND = 1015 cm-3. Calculate (a) built-in voltage (b) depletion layer width (c) Em

  43. Example 3 • Soln(a)

  44. Example 3 • Soln(b)

  45. Example 3 • Soln(c)

  46. One-sided junction • If one side has much higher impurity doping concentration than another, i.e. NA >> ND or ND >> NA, then this is called “one-sided junction”. • Consider case of p+-n junction as in the figure (NA >> ND),

  47. One-sided junction • Similarly, for n+-p junction of ND >> NA • The electric-field distribution could be written as where NB = lightly doped bulk concentration (i.e., NB = ND for p+-n junction)

  48. Abrupt junction • The maximum electric field Em at x = 0 can be found as • Therefore, the electric-field distribution E(x) can be re-written as (16)

  49. Abrupt junction • The potential distribution can be found from integrating (16) as (17)

  50. Example 4 • For a silicon one-sided abrupt junction with NA = 1019cm-3 and ND = 1016 cm-3, calculate the depletion layer width and the maximum field at zero bias. • Soln

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