1 / 27

Si Oxidation and Dielectrics

Si Oxidation and Dielectrics. Topics: Capacitors & Dielectrics Piezoelectrics Oxide films on Silicon. Capacitance. A parallel plate capacitor when in a vacuum (above) and when a dielectric material is present (below. D o ≡ charge density (C/m 2 )

caleb-donaldson
Download Presentation

Si Oxidation and Dielectrics

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. Si Oxidation and Dielectrics Topics: Capacitors & Dielectrics Piezoelectrics Oxide films on Silicon

  2. Capacitance A parallel plate capacitor when in a vacuum (above) and when a dielectric material is present (below Do≡ charge density (C/m2) eo = permittivity of free space = 8.85 x 10-12 F/m ξ≡ electric field strength = V/l P ≡ polarization, or increase in charge density due to presence of a dielectric

  3. The capacitance, C is related to the quantity of charge stored on either plate Q by : C = Q/V Where V = applied voltage. Units for C are coulombs per volt, or farads Capacitance can also b e expressed as C = eoA/l Where eo is permittivity of free space, A is the area of the plate and l is the plate separation distance

  4. If a dielectric is placed between the plates, the capacitance is: C = e A/l eis the permittivity of the dielectric. The relative permittivity, er, called the material dielectric constant, is typically used: er = e/eo Thus C = ereo A/l

  5. The applied electric field aligns the poles of the molecules in the dielectric. This is the source of polarization. The charge density, D, is D = eoξ + P And P may be written as P = eo(er-1)ξ Thus D =eoerξ

  6. Relative permittivity of nitrobenzene as a function of temperature Effect of frequency and temperature on the permittivity of soda-lime-silica glass

  7. Electronic polarization: fluctuations in the electron cloud Ionic polarization: displacement of ions in an ionic compound Orientation polarization: rotation of permanent dipole moments in presence of an applied field Variation of dielectric constant with frequency of an alternating electric field. Electronic, ionic and orientation polarization contributions to the dielectric constant are indicated

  8. Dielectric Breakdown Dielectric strength of various solids, gases and vacuum in uniform fields. Breakdown voltage versus dielectric thickness is plotted

  9. In a series circuit, capacitance is : C2 C1 • In a parallel circuit, circuit, capacitance is Ctotal = C1 + C2 +…Cn : C2 C1

  10. Piezoelectrics Figure (a) shows the electric dipoles in a piezoelectric material In a piezoelectric material, e.g. barium titanate, the Ti4+ and O2- ions are offset as shown When the material is compressed (b) the central Ti4+ is displaced, creating a voltage Applying a voltage (c) reverses this affect, causing the ions to move farther apart

  11. MSE-512 Piezoelectrics Field produced by stress: x = electric field s= applied stress E=Elastic modulus d = piezoelectric constant g = constant Strain produced by field: Elastic modulus:

  12. Thermal Oxidation and the Si/SiO2 Interface • Oxides play an important part in semiconductor fabrication. They are: • Easily grown or deposited on many substrates • Adhere well • Block diffusion of dopants and other unwanted impurities • Resistant to most processing chemicals • Easily patterned and etched with plasmas or specific chemicals • Excellent insulators • Have stable and reproducible properties Virtually all other semiconductor/insulator combinations suffer from one or more problems that significantly limit their applicability

  13. The most critical application of insulators in CMOS devices is as gate insulators. As seen above, these need to be <1 nm thick within the next 4 years

  14. SiO2 layers in CMOS are used as: • Gate dielectric layers • A mask against implantation • An isolation region laterally between devices • An insulator between metal layers

  15. Oxide Growth In ambient conditions, an oxide ~1 nm thick forms After several hours, its final thickness is 1-2 nm Oxides are thermally grown on wafers by heating in the presence of O2 or H2O

  16. Basic Concepts Because SiO2 is less dense than Si, it expands. This places the Si substrate in tension, and compresses the SiO2, forcing it upward New interface moves downward into Si

  17. SiO2 layers are amorphous. The bridging oxygen bonds can rotate, randomly accommodating SiO2 tetrahedra

  18. There are four basic types of defects or charges at the interface: 1. Qf, the fixed oxide charge. It has magnitude of 109 – 1011 cm-2 very close to the interface. Results from incompletely oxidized Si atoms with a net positive charge. Qf is stable. 2. Qit, the interface trapped charge. Similar to Qf, with dangling bonds located in oxide, very close to interface. Charge on Qit may be positive, negative or neutral and can change during operation. Density is about the same as Qf. Charges associated with the SiO2/Si system

  19. There are four basic types of defects or charges at the interface: 3. Qm, mobile charges. These are often processing artifacts causing erratic gate threshold voltages. These problems have been largely eradicated with proper cleanroom techniques. 4. Qot, the oxide trapped charge. Occurring anywhere in the oxide, these result from broken Si-O bonds, away from the interface. Usually caused by processing damage, they can often be removed by high-temperature annealing. Charges associated with the SiO2/Si system All types of charged defects have a negative effect on device performance

  20. Oxide Measurement Methods Optical Light reflection from a sample with a transparent thin film on its surface. no is the index of refraction in air (1.0), ni is that of the film and n2 is that of the substrate. f is the angle of incident light, b is the angle of reflecting light at the bottom of the interface m = 1,2,3… for maxima and ½, 3/2, 5/2… for minima

  21. Measurement Methods: the MOS Capacitor If a DC voltage +VG is applied to the gate, negative charges will be attracted across the oxide layer, producing a capacitance Cox If a negative voltage -VG is applied to the gate, negative charges will be repelled across the oxide layer, producing depletion region with its own capacitance, CD, in series with the oxide capacitance Cox accumulation |QG| = |QD| = ND/xD Where QG, QD are units of number of charges per cm2, ND is the doping in the substrate (assumed uniform). xD is the depth of the depletion region. depletion CD = es/xD es = permittivity of Si

  22. Measurement Methods: the MOS Capacitor If a large enough –VG is applied, it will attract minority carrier holes in the substrate to the surface and form an inversion layer (in this case, of P-type carriers. The gate voltage at which this occurs is called the threshold voltage, Vth. At this point, xD stops expanding at xDMax inversion For all regions of the capacitor, the gate charge must be balanced by the charge on the substrate, or: QG = NDxD + QI, Where QI is the charge density on the inversion layer. Since xD is maximum, the CV curve reaches a minimum as shown above.

  23. The End

More Related