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ETU 07210 LECTURE ONE Lecture_1 Linear ICs applications Lab 1 Coverage Integrated circuits (ICs) • • • • • Introduction Advantages and disadvantages of ICs Scale of integration Classification of Ics ICs fabrication references • Electrical Technology Volume IV - Electronic Devices and Circuits - B.L.Theraja. (Pg. 2472-2500) • Electronic Devices and Circuit Theory, 6th Edition – Robert L. Boylestad. (Pg. 588-608) Lecture_1 Linear ICs applications Lab 2 Integrated Circuits Introduction • • • • Lecture_1 Electronic circuitry has undergone tremendous changes since the invention of a triode in 1907. With the invention of the transistor in 1948, the electronic circuits became considerably reduced in size. Development of printed circuit boards (PCBs) further reduced the size of electronic equipment by eliminating bulky wiring and tie points. In the early 1960s, a new field of microelectronics was born with the aim of reducing the size, weight, and power of military electronic systems because of the increase use of these systems. Linear ICs applications Lab 3 Integrated Circuits Continue… • • • Microelectronics is that area of technology associated with and applied to the realization of electronic systems made of extremely small electronic parts or elements The extreme reduction in the size of electronic circuits has led to the development of microelectronic circuits called integrated circuits (ICs) An IC is a complete electronic circuit in which both the active and passive components are fabricated on a tiny single chip of silicon. Advantages of ICs • Lecture_1 Extremely small physical size: Thousands of times smaller than a discrete circuit. Linear ICs applications Lab 4 Integrated Circuits Continue… • • • • • • Lecture_1 Very small weight: Many circuit functions can be packed into a small space. Reduced cost: Many identical circuit can be built simultaneously on a single wafer (Batch fabrication). Extremely high reliability: ICs works for longer periods without giving any trouble. Increased response time and speed: The time delay of signals is reduced. Low power consumption: ICs are more suitable for low power operation. Easy replacement: It is more economical to replace an IC than to repair it. Linear ICs applications Lab 5 Integrated Circuits Continue… ICs Drawbacks • • • • Coils or inductors cannot be fabricated. ICs function at fairly low voltages. They handle only limited amount of power. They are quite delicate and cannot withstand rough handling or excessive heat. Scale of integration • • • • • • Lecture_1 Small scale integration (SSI). < 12 Medium scale integration (MSI). 12 – 99 Large scale integration (LSI). 100 – 9,999 Very large scale integration (VLSI). 10,000 – 99,999 Ultra large scale integration (ULSI). 100,000 – 999,999 Giga scale integration (GSI). 1,000,000 Linear ICs applications Lab 6 Integrated Circuits Continue… Classification of ICs by structure • Monolithic ICs: Both active and passive components are fabricated inseparably within a semiconductor substrate. • Film ICs (Thin film and Thick film): Film components are made of either conductive or nonconductive material that is deposited in desired patterns on a ceramic or glass substrate. Film can only be used as passive circuit components, such as resistors and capacitors. Transistors and/or diodes are added externally as discrete components to the substrate to complete the circuit. Lecture_1 Linear ICs applications Lab 7 Integrated Circuits Continue… • Hybrid ICs: Combine two or more integrated circuit types or combine one or more integrated circuit types and discrete components. Comparison between different ICs • Each type of IC has its own advantages and disadvantages. Advantages of monolithic Ics - Lowest cost and highest reliability Disadvantages of monolithic ICs - Isolation between components is poorer, - Range of values of passive components used in the circuits is comparatively small, Lecture_1 Linear ICs applications Lab 8 Integrated Circuits Continue… - Inductors cannot be fabricated, and - They afford no flexibility in circuit design. Advantages of film ICs - The passive components with broader range of values ca be formed, - The isolation between their components is better, - Greater flexibility in circuit design due to the use of external discrete active components. Disadvantages of film ICs - Not being able to fabricate active components, - Comparatively higher cost, and - Larger physical size. Lecture_1 Linear ICs applications Lab 9 Integrated Circuits Continue… Classification of ICs by function • Linear integrated circuits (LICs) LICs are also referred to as analog ICs. Their inputs and outputs takes on a continuous range of values and the outputs are generally proportional to the inputs. As compared to digital ICs, LICs are used much less. They are frequently used in - Operational amplifiers, - Small-signal amplifiers, - Power amplifiers, - RF and IF amplifiers, Lecture_1 Linear ICs applications Lab 10 Integrated Circuits Continue… - Microwave amplifiers, - Multipliers, - Voltage comparators, - Voltage regulators etc. Manufacturer’s designation of LICs - LICs with the same specifications but different code and type number can be produced by different manufacturers. - For example, consider the op-amp 741 with the following codes: National Semiconductor — LM 741 Motorola — MC 1741 Lecture_1 Linear ICs applications Lab 11 Integrated Circuits Continue… RCA — CA 3741 Texas Instruments — SN 5274 LICs classes - Many LICs are available in different classes such as A, B, C, E, S, and SC. - For example, main classes of op-amp 741 are: 741— Military grade op-amp 741 C — Commercial grade op-amp 741 A — Improved version of 741 741 E — Improved version of 741 C 741 S — Military grade op-amp with higher slew rate Lecture_1 Linear ICs applications Lab 12 Integrated Circuits Continue… 741 SE — Commercial grade op-amp with higher slew rate • Digital integrated circuits (DICs) DICs dominate the IC market and they are mostly utilized by computer industry. DICs are of the monolithic integration type due to the fact that a computer uses a larger number of identical circuits. DICs contain circuits whose input and output voltages are limited to two possible levels— low or high. It is so because digital signals are usually binary. Sometimes, digital circuits are referred to as switching circuits. Lecture_1 Linear ICs applications Lab 13 Integrated Circuits Continue… DICs include circuits such as: - Logic gates - Flip-flops - Counters - Clock-chips - Calculator chips - Memory chips - Microprocessors (µP) etc. Reading assignment: Go through page 2478 (Electrical Technology Volume IV - Electronic Devices and Circuits - B.L.Theraja) and read what has been covered under “IC terminology” heading. Lecture_1 Linear ICs applications Lab 14 Integrated Circuits Continue… How ICs are made? • The ICs are manufactured in four distinct stages. These are: Material preparation, Crystal growing and wafer preparation, Wafer fabrication, and Testing, bonding and packaging. • Material preparation Silicon, as an element is not found in nature. It is found abundantly in nature in the form of silicon dioxide, which constitutes about 20% of earth’s crust. Silicon is commonly found as quartz or sand. Lecture_1 Linear ICs applications Lab 15 Integrated Circuits Continue… A number of processes are required to convert sand into pure silicon with a polycrystalline structure. Figure 1.1 shows the different processes involved in the preparation of polycrystalline silicon from sand. - As seen from this figure, the sand is allowed to react with a gas produced from the burning of carbon. - This produces silicon with 98% purity. - Next silicon is further purified in a reactor to produce electronic-grade polycrystalline silicon. Lecture_1 Linear ICs applications Lab 16 Integrated Circuits Continue… Fig. 1.1 Lecture_1 Linear ICs applications Lab 17 Integrated Circuits Continue… • Crystal growing and wafer preparation • Crystal growth There are two methods to carryout the crystal growth: - The Czochralski and - The flat zone process. The Czochralski process prepares virtually all the silicon used for IC fabrication. The flat zone process is used to prepare crystals for fabricating high-power, high voltage semiconductor devices. The Czochralski process - The equipment used for single crystal growth (called puller) is as shown in Figure 1.2. Lecture_1 Linear ICs applications Lab 18 Integrated Circuits Continue… - The puller has three main components: A furnace which includes quartz crucible, a rotation mechanism (clockwise as shown), and a radio frequency (RF) heating element, A crystal pulling mechanism which includes a seed holder and a rotation mechanism (counterclockwise), and An ambient control which includes an argon gas source, a flow control and an exhaust system. - In addition the puller has a computer system to control process parameters such as temperature, crystal diameter, pull rate and rotation speed. - To grow crystals, the polycrystalline silicon is placed in the crucible. Lecture_1 Linear ICs applications Lab 19 Integrated Circuits Continue… - The furnace is heated to a temperature of 1690 K which is slightly greater than the melting point (1685 K) of silicon. - A precisely controlled amount of dopant is added to the melt to make the silicon as P-type or N-type. - A suitable oriented seed crystal is suspended over the crucible in a seed holder. - The seed is inserted into the melt and a small portion of it is allowed to melt. - The seed is rotated and pulled up very slowly, while at the same time, the crucible is rotated in the opposite direction. Lecture_1 Linear ICs applications Lab 20 Lecture_1 Linear ICs applications Lab 21 Integrated Circuits Continue… - The molten silicon attaches itself to the seed and it becomes identical to the seed in structure and orientation. - As the seed is pulled up, the material that is attached to the seed solidifies - Its crystal structure becomes the same as that of the seed and a larger crystal is formed. - Thus using this method, cylindrical single crystal bars (called ingots) of silicon are produced. - The desired diameter of the silicon ingot is obtained by controlling both the temperature and the pulling speed. - The resulting ingot is cooled and is removed to be made into thin discs called wafers. Lecture_1 Linear ICs applications Lab 22 Integrated Circuits Continue… - The ingots have diameters as large as 200 mm with the latest ones approaching 300 mm. - The ingot length is of the order of 1000 mm. • Wafer preparation In this stage the ingot surface is grounded throughout to an exact diameter and the top and bottom portions are cut off. After that one or more flat regions are ground along the length of the ingot. These flat regions mark the specific crystal orientation of the ingot and conductivity type silicon material. Refer to Figure 1.3. Lecture_1 Linear ICs applications Lab 23 Integrated Circuits Continue… Notice that the ingot is marked with two flats regions : - the larger flat (called primary flat) and - the smaller flat or secondary flat regions. The primary flat allows a mechanical locator in automatic processing equipment to position the wafer and to orient the devices relative to the crystal in a specific manner. The secondary flat regions are used to identify the orientation and conductivity type of the crystal. The conductivity of the wafer could be either P-type or N-type and the crystal orientation, {100} or {111}. Lecture_1 Linear ICs applications Lab 24 Lecture_1 Linear ICs applications Lab 25 Integrated Circuits Continue… The semiconductor industry uses {111} wafers for fabricating ICs with bipolar transistor technology and {100} wafers for MOS circuits. Once the orientations are done, the ingot is sliced into wafers by a high-speed diamond saw. The wafer thickness varies from 0.4 to 1.0 mm. After slicing, the next step is to polish the wafer surface. Finally the wafers are cleaned and dried for use in fabrication of ICs. Lecture_1 Linear ICs applications Lab 26 Integrated Circuits Continue… • Wafer fabrication Category of the processes that are used in the fabrication of ICs: - Oxidation - Etching - Diffusion - Ion implantation - Photolithography - Epitaxy - Metallization and interconnections. Lecture_1 Linear ICs applications Lab 27 Integrated Circuits Continue… • Oxidation It consists of growing a thin film of silicon dioxide (SiO2) on the surface of a silicon wafer. Silicon dioxide has several uses: - To serve as a mask against implant or diffusion of dopant into silicon, - To provide surface passivation, - To isolate one device from another, and - To act as a component in MOS structures. Techniques for forming oxide layers on silicon wafer: - Thermal oxidation, Lecture_1 Linear ICs applications Lab 28 Integrated Circuits Continue… - Vapour phase technique [chemical vapour deposition (CVD)], and - Plasma oxidation. However, thermal oxidation is the more commonly used technique in IC processing. Figure 1.4 shows a thermal oxidation system. - The silicon wafers are placed vertically into a quartz boat in a quartz tube. - The quartz boat is slowly passed through a furnace, in the presence of oxygen, operating at 10000C. - The oxidizing agent may dry oxygen or a mixture of water vapour and oxygen. Lecture_1 Linear ICs applications Lab 29 Integrated Circuits Continue… - A computer controls the whole operation in the thermal oxidation system. - The operation include regulating the gas flow sequence, automatic insertion and removal of wafers and the furnace temperature. Lecture_1 Linear ICs applications Lab 30 Integrated Circuits Continue… • Etching Etching is the process of selective removal of regions of a semiconductor, metal or silicon dioxide. There are two types of etching : - Wet etching; the wafers are immersed in a chemical solution at a predetermined temperature. - Dry (or plasma) etching; the wafers are immersed in gaseous plasma created by a radio-frequency electric field applied to a gas such as argon. • Diffusion The process of introducing impurities into selected regions of a wafer to form junctions. Lecture_1 Linear ICs applications Lab 31 Integrated Circuits Continue… It occurs in two steps : the pre-deposition and the drive-in diffusion. Pre-deposition tends to produce, a shallow but heavily doped layer, near the silicon surface. Drive-in is used to drive the impurity atoms deeper into the surface, without adding any more impurities. Figure 1.5 shows the graph of doping profiles, during the pre-deposition and the drive-in steps of diffusion. The doping profiles indicate that the impurity concentration decreases monotonically from the surface of the substrate. The profiles of the dopant distribution is determined mainly by the temperature and diffusion time. Lecture_1 Linear ICs applications Lab 32 Integrated Circuits Continue… Common dopants are boron for P-type layers and phosphorus, antimony and arsenic for N-type layers. Diffusion is rarely performed using pure elements themselves, instead compounds of elements are used. Lecture_1 Linear ICs applications Lab 33 Integrated Circuits Continue… Lecture_1 Linear ICs applications Lab 34 Integrated Circuits Continue… Figure 1.6. shows the equipment used in diffusion. The wafers are placed in a quartz boat within a quartz furnace tube. The furnace is heated by resistance heaters surrounding it. To introduce an impurity, phosphorus for example, phosphorus oxychloride (POCl) is placed in a container at a temperature that maintains its liquid form. The proper vapour pressure is maintained by a control of the temperature. Nitrogen and oxygen gas are made to pass over the container. Lecture_1 Linear ICs applications Lab 35 Integrated Circuits Continue… These gases react with the silicon, forming a layer on the surface of the wafer that contains silicon, oxygen and phosphorus. At the high temperature of the furnace, phosphorus easily diffuses into the silicon. In order that the dopant may be diffused deeper into silicon, the drive-in step follows. This is done at a higher temperature of about 11000C inside a furnace similar to that used for pre-deposition, except that no dopant is introduced into the furnace. The higher temperature, causes the dopant atoms to move into silicon more quickly. Lecture_1 Linear ICs applications Lab 36 Integrated Circuits Continue… Diffusion depth is controlled by the time and temperature of the drive-in process. Figure 1.7 shows the diffusion of dopant into silicon. Lecture_1 Linear ICs applications Lab 37 Integrated Circuits Continue… • Ion implantation This is a process of introducing dopants into selected areas of the surface of the wafer by bombarding the surface with high-energy ions of the particular dopant. • Photolithography It is a process in which the geometrical pattern on the glass plate is transferred to the surface of the wafer. This is done to open identical windows so that the diffusion process may take place in all identical regions of the same IC and for all ICs on the wafer. As an illustration we assume that the first reticle is used over an oxidized surface as shown in Figure 1.8 (a). Lecture_1 Linear ICs applications Lab 38 Integrated Circuits Continue… Lecture_1 Linear ICs applications Lab 39 Integrated Circuits Continue… Lecture_1 Linear ICs applications Lab 40 Integrated Circuits Continue… Steps taken in photolithographic process: - To create a thin layer of silicon dioxide (SiO2)on the surface of a silicon wafer, fig. 1.8 (a). - To deposit a coating of photoresist (PR) material on top of the SiO2 layer, fig. 1.8 (b). - The PR coating is exposed to ultraviolet (UV) light through a glass mask, fig. 1.8 (c). - The exposed PR material is chemically removed, fig. 1.8 (d). - The exposed SiO2 is then etched away using hydrofluoric acid, fig. 1.8 (e). Lecture_1 Linear ICs applications Lab 41 Integrated Circuits Continue… - Unexposed PR material is removed and the structure is ready for the impurity diffusion step, fig. 1.8 (f). Two types of PR material: - Positive PR. Allows the windows to be opened wherever the UV light passes through the transparent parts of the mask. - Negative PR. Allows the windows to be open under the opaque parts of the mask while the exposed PR remains on the surface. Lecture_1 Linear ICs applications Lab 42 Integrated Circuits Continue… • Epitaxy Epitaxy or Epitaxial growth is the process involves depositing a very thin layer of silicon to form a uniformly doped crystalline region (epitaxial layer) on the substrate. Components are produced by diffusing appropriate materials into the epitaxial layer in the same way as the diffusion method. In the processes of diffusion and ion implantation, a dopant is driven into a substrate of doped silicon. In epitaxy, a layer of doped silicon is deposited on top of the surface of the substrate. Lecture_1 Linear ICs applications Lab 43 Integrated Circuits Continue… • Metallization and interconnections The provision of metallic interconnections for the IC and for external connections to the IC. The interconnections must - Have low resistance to minimize both the voltage drops on the lines as well as the capacitances between the lines so as to reduce delay times. - Make ohmic contacts to semiconductors in the devices such as P and N regions of a PN junction diode. - NB: An ohmic contact is one that exhibits a very low resistance, allowing currents to pass easily in both directions through the contact. Lecture_1 Linear ICs applications Lab 44 Integrated Circuits Continue… The most used metal for interconnections process is aluminium due to the following reasons: - High conductivity - Easy to evaporate - Can be easily etched - Not expensive - Adheres well to silicon dioxide. Three important processes for depositing aluminium on silicon substrate: - Resistance heating, - Electron beam heating, and - Sputtering. Lecture_1 Linear ICs applications Lab 45 Integrated Circuits Continue… • Testing, bonding and packaging Testing - Each chip on a wafer is tested before the individual chips are cut from the wafer. - Multiple test probes are touched to the metal pads and the chip is tested to verify circuit performance. - After all the circuits are tested, the wafer is removed from the testing machine, sawed between the circuits, and broken apart. - Then each die that passed the test is picked up and placed in the package. Lecture_1 Linear ICs applications Lab 46 Integrated Circuits Continue… Bonding - It means permanent attachment. - It consists of two steps. Die bonding. The metallurgical process by which the die (chip) is rigidly attached to its substrate or base. Wire bonding. The permanent attachment of wire leads between the pads on the chip and terminal posts as shown in figure 1.9. Lecture_1 Linear ICs applications Lab 47 Integrated Circuits Continue… Lecture_1 Linear ICs applications Lab 48 Integrated Circuits Continue… Packaging - Packaging is the process of protecting the surface of device (die) from environment of its intended application. - Packaging can be broadly classified into the following two categories: - Through-hole mount that involve inserting the package pins through holes on the printed circuit board (PCB) before soldering [Figure 1.10] - Surface mount type where the leads do not pass through holes in the PCB [Figure 1.11]. Lecture_1 Linear ICs applications Lab 49 Lecture_1 Linear ICs applications Lab 50 THE END OF LECTURE ONE Lecture_1 Linear ICs applications Lab 51