The Kynix Blog - Diodes

2026 Executive SummaryA Rectifier Diode is a critical semiconductor component that acts as a one-way valve for electricity, converting Alternating Current (AC) into Direct Current (DC). In 2026, while silicon-based diodes remain standard for low-voltage electronics, the industry is rapidly shifting toward Silicon Carbide (SiC) and Gallium Nitride (GaN) diodes for high-efficiency power supplies, EV charging, and renewable energy systems due to their superior thermal performance and speed.Ⅰ Introduction: The Role of Rectifier Diodes in 2026Diodes are fundamental semiconductor devices essential for modern electronics. A rectifier diode is a specialized two-lead semiconductor that allows current to flow in only one direction, effectively blocking reverse current. Mechanically, the P-N junction diode is created by fusing n-type and p-type semiconductor materials. The anode represents the positive (P-type) side, while the cathode represents the negative (n-type) side. While generic diodes serve many purposes, rectifier diodes are specifically engineered for power conversion—transforming AC voltage into stable DC voltage for power supplies, battery chargers, and automotive systems. Zener diodes differ as they are primarily used to regulate voltage and prevent unwanted variations in DC supplies within a circuit.Ⅱ What is a Rectifier and How Does It Function?A rectifier is an electrical circuit or device that converts alternating current (AC), which reverses direction periodically, into direct current (DC), which flows in a single direction. The inverter performs the reverse operation (DC to AC).Rectifiers are universally applied to convert household AC mains power into usable DC for electronic devices. As of 2026, classification has evolved beyond simple topologies. The bridge rectifier remains the industry standard for most applications. Contrary to older definitions, a rectifier does not "generate" electricity; it converts voltage types with varying degrees of efficiency. Modern rectifiers are categorized as follows:Primary Rectifier Classifications:Single-phase rectifiers: Common in domestic electronics.Three-phase rectifiers: Used in industrial motors and EV charging stations.Half-wave rectifiers: Low efficiency, used in simple signal applications.Full-wave rectifiers: High efficiency, utilizes the full AC cycle.Controlled rectifiers: Uses SCRs/Thyristors to control voltage output.Active Rectifiers (Synchronous): Uses MOSFETs instead of diodes for >99% efficiency (Standard in 2026 high-end tech).  Ⅲ Rectifier Diode Tutorial: Visual GuideWhat is a Rectifier? (AC to DC): Electronics Basics 7  Rectifier Diode Video Description : This video explains the fundamental physics of the Rectifier Diode and demonstrates basic rectification circuits used in power supply units (PSUs). Ⅳ What Defines a Rectifier Diode in Modern Electronics?A rectifier diode is a high-current semiconductor device specifically optimized to handle the stress of converting AC to DC in bridge configurations. In 2026 digital electronics, Schottky barrier diodes are highly valued for their low forward voltage drop (approx. 0.15V–0.45V) and fast switching speeds. Modern rectifier diodes control currents ranging from milliamperes (mA) to several kilo-Amperes (kA) and block reverse voltages from a few volts up to 10kV in specialized grid applications.While traditional rectifier diodes are designed using Silicon (Si), high-performance sectors now utilize Wide Bandgap (WBG) materials. Germanium (Ge) diodes are largely obsolete in power applications due to heat sensitivity, though they persist in niche RF detection. The modern comparison lies between Silicon and Silicon Carbide (SiC). SiC diodes offer superior thermal conductivity and higher breakdown voltages compared to legacy Silicon diodes.There are two critical technical parameters in a rectifier diode: Absolute Maximum Ratings (permissible limits) and Electrical Characteristics (operational performance). A rectifier diode symbol is shown below, with the arrowhead pointing in the direction of conventional current flow (Anode to Cathode).  Figure 1: Standard Rectifier Diode Symbol  Ⅴ Diode vs. Rectifier: Key Differences ExplainedA rectifier is a circuit application designed to convert AC to DC, whereas a diode is the specific semiconductor component used within that circuit. Think of the diode as the "valve" and the rectifier as the "plumbing system." The diode acts as a switch, allowing current to pass when forward-biased and blocking it when reverse-biased. Ⅵ Technical Parameters (2026 Standards)Silicon remains the most common material for general-purpose rectifier diodes due to cost-effectiveness. However, distinguishing between legacy and modern materials is vital:Silicon (Si): Junction Temperature (Tj) up to 150°C. Forward Voltage Drop ($V_F$) ~0.7V - 1.1V.Germanium (Ge): Rarely used. Low $V_F$ (0.3V) but very low thermal ceiling (Tj = 75°C).Silicon Carbide (SiC): The 2026 standard for EVs and Servers. High Tj (>175°C), high breakdown voltage, and near-zero reverse recovery time. We divide the rectifier diode's technical parameters into two primary groups relevant to engineering data sheets: Ⅶ Rectifier Diode – Current-Voltage (I-V) CharacteristicsThe I-V characteristic curve illustrates how a diode behaves under forward and reverse bias. The "knee voltage" or cut-in voltage is the point where current begins to flow rapidly.Figure 2: Current-Voltage characteristics of the Rectifier Diode   Ⅷ Common Applications in 2026Rectifier diodes are ubiquitous in modern electronics. Their applications have expanded with the rise of renewable energy and electric vehicles:Power Rectification: Converting grid AC (110V/220V) to DC for appliance power supplies.Freewheeling Diodes: Protecting circuits from voltage spikes in inductive loads (motors, relays).Demodulation: Signal isolation in radio receivers (AM radio).Voltage Multipliers: Changing signal amplitude in high-voltage generators.Solar Inverters: Preventing reverse current flow from batteries back to solar panels at night.EV Charging: On-board chargers (OBC) utilizing SiC diodes for rapid battery charging. Ⅸ How a Rectifier Diode Circuit Works (Physics)The functionality of a diode relies on the P-N junction, formed by chemically combining n-type (electron-rich) and p-type (hole-rich) semiconductor materials. The two terminals are the Anode (P) and Cathode (N). "Biasing" refers to applying external voltage to these terminals to control operation.1. Unbiased Rectifier Diode (Equilibrium)When no voltage is applied, the diode is Unbiased. Electrons from the N-side diffuse into the P-side, while holes from the P-side diffuse into the N-side. This recombination creates immobile ions near the junction interface, forming a Depletion Region. A built-in electric field (Barrier Potential) is created, preventing further current flow (approx. 0.7V for Silicon). 2. Forward Biased (Conducting State)When the positive terminal of a source is connected to the Anode and negative to the Cathode, the external voltage overcomes the barrier potential. The depletion region collapses, and current flows freely.3. Reverse Biased (Blocking State)When the positive terminal is connected to the Cathode, the depletion region widens. Ideally, no current flows. However, if the reverse voltage exceeds the diode's Breakdown Voltage, the depletion layer is destroyed (Avalanche Breakdown), allowing massive current flow that typically damages standard rectifier diodes. Figure 4: Circuit configuration for Biasing   Ⅹ Step-by-Step Guide: How to Test a Rectifier DiodeTo determine if a rectifier diode is functional or "blown," you can use a standard digital multimeter. There are two primary methods for testing polarity (Anode vs. Cathode) and health. Method 1: Using Diode Test Mode (Recommended) This is the most accurate method. The function of a diode check injects a small current to measure the forward voltage drop.  Forward-bias Test: Connect the Red probe to Anode and Black to Cathode. A healthy Silicon diode will read between 0.5V and 0.8V.  Reverse-bias Test: Swap the probes. The meter should read "OL" (Over Limit) or "1," indicating infinite resistance. If it reads 0 or emits a continuous beep, the diode is shorted (broken).  Method 2: Using Resistance (Ohmmeter) Mode If your meter lacks a diode mode, use the 2kΩ resistance setting.  Forward-bias: You should see a low resistance reading (typically under 1kΩ, though not strictly 0.7V).  Reverse-bias: The multimeter should show very high resistance or "OL". Note: In practical circuit repair, you must desolder at least one leg of the diode from the PCB to get an accurate reading, otherwise other components will interfere with the measurement. Ⅺ Frequently Asked Questions (FAQ)1. How does a rectifier diode work in simple terms?A rectifier diode acts like a one-way street for electricity. It allows current to flow forward easily (Forward Bias) but blocks it from flowing backward (Reverse Bias). This unique property allows it to "rectify" AC power (which moves back and forth) into DC power (which moves one way).2. What is the primary use of a rectifier in 2026?The primary use remains converting Alternating Current (AC) from the wall outlet into Direct Current (DC) required by virtually all electronic devices, from smartphones to Electric Vehicles.3. Why can a diode be used as a rectifier?An ideal p-n junction diode has zero resistance in the forward direction and infinite resistance in reverse bias. By eliminating the negative half-cycles of an AC waveform, it produces a pulsating DC output.4. What are the main types of rectifiers?Rectifiers are classified by phases (Single-phase vs. Three-phase) and control (Uncontrolled Diodes vs. Controlled Thyristors). In terms of topology, they are separated into half-wave, full-wave center-tapped, and bridge rectifiers.5. What is the most widely used rectifier configuration?The Full-Wave Bridge Rectifier (using four diodes) is the most efficient and widely used configuration for standard power supplies. In high-efficiency modern applications (like server PSUs), "Synchronous Rectifiers" using transistors are becoming dominant.6. How do I know if my rectifier diode is bad?If a multimeter test reads "0" (short circuit) in both directions, or "OL" (open circuit) in both directions, the diode is defective and must be replaced.{ "@context": "https://schema.org", "@type": "Article", "headline": "Rectifier Diodes: The 2026 Guide to Function, Types, and Testing", "datePublished": "2021-11-16", "dateModified": "2026-01-09", "description": "A comprehensive guide to rectifier diodes, covering operation principles, AC to DC conversion, SiC vs Silicon types, and step-by-step testing instructions.", "articleBody": "Diodes are common semiconductor devices. A rectifier diode, a two-lead semiconductor provides only one direction of current to flow...", "mainEntity": [ { "@type": "FAQPage", "mainEntity": [ { "@type": "Question", "name": "How does a rectifier diode work?", "acceptedAnswer": { "@type": "Answer", "text": "A rectifier diode works by allowing current to flow in only one direction (forward bias) while blocking it in the opposite direction (reverse bias), effectively converting AC to DC." } }, { "@type": "Question", "name": "What is a rectifier used for?", "acceptedAnswer": { "@type": "Answer", "text": "Rectifiers are used to convert Alternating Current (AC) mains power into Direct Current (DC) for electronic devices, batteries, and motors." } }, { "@type": "Question", "name": "How do you test a rectifier diode?", "acceptedAnswer": { "@type": "Answer", "text": "You can test a diode using a multimeter in 'Diode Mode'. 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Introduction The rectifier diode is a semiconductor device that converts AC into DC. Usually it contains a PN junction with two terminals, a positive electrode and a negative electrode. The most important characteristic is unidirectional conductivity. In electronic circuits, its breakdown voltage is high, the reverse leakage current is small, and the high temperature performance is good. Generally, it can be made of materials such as semiconductor germanium or silicon. In addition, high-voltage and high-power rectifier diodes are made of high-purity single crystal silicon (it is easy to reverse breakdown when there is more doping). This kind of device has a large junction area and can pass a large current (up to thousands of amperes), but the operating frequency is not high, generally below tens of KHz. Rectifier diodes are mainly used in various low-frequency half-wave rectifier circuits. If require full-wave rectification, several diodes need to be connected to form a rectifier bridge. What is a Rectifier? (AC to DC) Catalog Introduction Ⅰ Common Parameters Ⅱ Rectifier Diodes Selection Ⅲ Rectifier Common Failures Ⅳ Rectifier Diodes Detection Ⅴ Rectifier Diode Replacement 5.1 Replacing Rules 5.2 Commonly Used Rectifier Models List Ⅵ Rectifier Diode Circuit Types 6.1 Half-Wave Rectifier Circuit 6.2 Full-Wave Rectifier Circuit 6.3 Bridge Rectifier Circuit Ⅶ High-frequency Rectifier Diodes Ⅷ FAQ Ⅰ Common Parameters The rectifier diode uses the unidirectional conductivity of the PN junction to convert alternating current into pulsating direct current. Rectifier diodes have a large leakage current, and most of them are diodes packaged with surface mount materials. The parameters of the rectifier diode include the maximum rectifier current, which refers to the maximum current value allowed by the rectifier diode for long-term operation. It is the main parameter of the rectifier diode and the main basis for the option of the rectifier diode. Except it, other important parameters are introduced here.(1) Maximum average rectified current IF: It refers to the maximum forward average current allowed to pass through the diode during long-term operation. The current is determined by the PN junction area and the heat dissipation conditions. It should be noted that the average current passing through the diode cannot be greater than this value, and has heat dissipation.(2) Maximum reverse working voltage VR: It refers to the maximum reverse voltage allowed to be applied across the diode. If it is greater than this value, the reverse current (IR) will increase sharply, and the unidirectional conductivity of the diode will be destroyed, causing reverse breakdown. Usually take half of the reverse breakdown voltage VB as VR.(3) Maximum reverse current IR: It is the reverse current allowed to flow through the diode under the highest reverse working voltage. This parameter reflects the quality of the unidirectional conductivity of the diode. Therefore, the smaller the current value, the better the diode quality.(4) Breakdown voltage VB: It refers to the voltage value at the sharp bend point of the reverse volt-ampere characteristic curve of the diode. When the reverse is a soft characteristic, it refers to the voltage value under a given reverse leakage current condition.(5) The highest operating frequency fm: It is the highest operating frequency of the diode under normal conditions. It is mainly determined by the junction capacitance and diffusion capacitance of the PN junction. If the operating frequency exceeds fm, the unidirectional conductivity of the diode will not be well reflected.(6) Reverse recovery time trr: It refers to the reverse recovery time under the specified load, forward current and maximum reverse transient voltage.(7) Zero-bias capacitor CO: It refers to the sum of the capacitance of the diffusion capacitance and the junction capacitance when the voltage across the diode is zero. It is worth noting that, due to the limitation of the manufacturing process, even the same type of diode has a large dispersion of its parameters. The parameters given in the manual are often within a range. If the test conditions change, the corresponding parameters will also change. For example, the IR of the 1N5200 series silicon plastic rectifier diode measured at 25°C is less than 10uA, and at 100°C IR becomes less than 500uA.     Ⅱ Rectifier Diodes Selection Rectifier diodes are generally planar silicon diodes, which are used in various power rectifier circuits. When selecting a rectifier diode, the parameters such as its maximum rectifier current, maximum reverse working current, cut-off frequency and reverse recovery time should be mainly considered.The rectifier diode used in the ordinary series stabilized power supply circuit does not require high reverse recovery time of the cut-off frequency. The rectifier diode with the maximum rectified current and maximum reverse working current should meet the requirements of the circuit.The rectifier diode used in the rectifier circuit of the switching regulated power supply and the pulse rectifier circuit should be a rectifier diode with a higher operating frequency and shorter reverse recovery time (such as RU series, EU series, V series, 1SR series, etc.) or select fast recovery diodes, or Schottky rectifier diode.     Ⅲ Rectifier Common Failures (1) Inadequate lightning protection and poor overvoltage protection. The rectifier device is not equipped with lightning protection and overvoltage protection devices. Or insufficient routine maintenance of the equipment.(2) Poor operating conditions. In the indirect drive generator set, because the calculation of the speed ratio is incorrect or the ratio of the diameters of the two belt pulleys does not meet the requirements of the speed ratio, the generator runs at a high speed for a long time, so the rectifier is at a higher voltage for a long time. It accelerates the rectifier aging, and was damaged by premature breakdown.(3) Poor operation management. The load failure or diode breakdown doesn’t fixed in time.(4) Poor equipment installation or manufacturing process. The generator set has been operating under large vibration for a long time, which affects the rectifier tube operation. At the same time, because the generator set speed is unstable, the working voltage of the rectifier tube also fluctuates, which greatly accelerate the aging and damage of the rectifier tube.(5) The specifications and models of the rectifier tube do not match. When replacing a new rectifier tube, wrongly replace the tube whose working parameters do not meet the requirements or the wiring is wrong, causing the rectifier tube to breakdown and damage.(6) The safety margin of the rectifier tube is too small. The overvoltage and overcurrent safety margin of the rectifier tube is too small, so that the rectifier tube cannot withstand the overvoltage or the peak value of the overcurrent transient process that occurs in the generator excitation circuit and is damaged. Figure 1. Diode as Rectifier Symbol     Ⅳ Rectifier Diodes Detection Here is a more general and simple method. Remove all the rectifier diodes in circuit, use the 100×R or 1000×R ohm range of a multimeter to measure the two lead wires of the rectifier diode (adjust and test twice). If the resistance values measured twice are very different, for example, the resistance value is as high as a few hundred kΩ to infinity, or the resistance value is only a few hundred Ω or less, indicating that the diode is good (except under special circumstances). If the resistance value measured twice is almost the same and the resistance value is very small, it means that the diode has been broken down and cannot be used. In addition, if the resistance values measured twice are both infinite, it means that the diode has been internally disconnected and cannot be used.     Ⅴ Rectifier Diode Replacement   5.1 Replacing Rules After the rectifier diode is damaged, you should replace with the same model or another model with the same parameters.Generally, rectifier diodes with high withstand voltage (reverse voltage) can be substituted for rectifier diodes with low withstand voltage, while rectifier diodes with low withstand voltage cannot be replaced with rectifier diodes with high withstand voltage. A diode with a high rectification current value can be substituted for a diode with a low rectification current value, while a diode with a low rectification current value cannot be substituted for a diode with a high rectification current value.   5.2 Commonly Used Rectifier Models List Material Model Reverse Voltage Operation (peak) Average Rectified Current   Silicon Rectifier Diode 1N4001 50V 1A (Ir=5uA,Vf=1V,Ifs=50A) 1N4002 100V 1A 1N4003 200V 1A 1N4004 400V 1A 1N4005 600V 1A 1N4006 800V 1A 1N4007 1000V 1A 1N4148 75V 4PF, Ir=25nA,Vf=1V 1N5391 50V 1.5A (Ir=10uA,Vf=1.4V,Ifs=50A) 1N5392 100V 1.5A 1N5393 200V 1.5A 1N5394 300V 1.5A 1N5395 400V 1.5A 1N5396 500V 1.5A 1N5397 600V 1.5A 1N5398 800V 1.5A 1N5399 1000V 1.5A 1N5400 50V 3A (Ir=5uA,Vf=1V,Ifs=150A) 1N5401 100V 3A 1N5402 200V 3A 1N5403 300V 3A 1N5404 400V 3A 1N5405 500V 3A 1N5406 600V 3A 1N5407 800V 1A (Ir=5uA,Vf=1V,Ifs=50A) 1N5408 1000V 1A   Ⅵ Rectifier Diode Circuit Types The power grid supplies users with alternating current, and various electrical devices require direct current. Rectification is the process of converting AC into DC. Utilizing the device with unidirectional conductivity, the current of alternating direction and magnitude can be converted into direct current. The following introduces three main rectifier circuits composed of crystal diodes.   6.1 Half-Wave Rectifier Circuit Figure 2. Half-Wave Rectifier Circuit The figure shows the simplest rectifier circuit. It is composed of power transformer B, rectifier diode D and load resistor Rfz. The transformer transforms the voltage into the required alternating voltage e2, and then D transforms the AC into pulsating DC.The transformer threshold voltage e2 is a sine wave voltage whose direction and magnitude change with time, and its waveform is shown in Figure (a). In the 0~K time, e2 is a positive half cycle, that is, the upper end of the transformer is positive and the lower end is negative. At this time, the diode is in forward conductive conduction, and e2 is added to the load resistor Rfz through it. Within π~2π, e2 is in negative half cycle, the lower end of the transformer secondary is positive, and the upper end is negative. At this time, D bears the reverse voltage and does not conduct, and there is no voltage on Rfz. In the time of π~2π, the process of 0~π time is repeated, and in the time of 3π~4π, the process of π~2π time... half-cycle through Rfz, a single right direction voltage is obtained on Rfz (up positive and lower negative), as shown in Figure (b), which achieves the purpose of rectification. But the load voltage Usc, and the load current also changes with time, so it is usually called pulsating DC. Figure 3. Half-Wave Rectifier Wave This rectification method of removing the first half week and leaving half a week is called half wave rectification. It is not difficult to note that the half-wave rectification is at the expense of consuming half of the AC in circuit, and the current utilization rate is very low. According to it, half-wave rectifier diode is commonly used in high voltage and small current occasions, and is rarely used in general radio devices.   6.2 Full-Wave Rectifier Circuit Figure 4. Full-Wave Rectifier Circuit If some adjustments are made to the structure of the rectifier circuit, a full-wave rectifier circuit that can be obtained. The figure above is the electrical schematic diagram of the full-wave rectifier circuit.The full-wave rectifier circuit can be regarded as a combination of two half-wave rectifier circuits. A tap needs to be drawn in the middle of the secondary coil of the transformer to divide the secondary coil into two symmetrical windings, so as to get two voltages e2a and e2b of equal size but opposite polarity to form two energized circuits.The working principle of the full-wave rectifier circuit can be illustrated by the waveform diagram. Between 0 and π, e2a is a positive voltage to Dl, D1 is turned on, and a up positive and down negative voltage is obtained on Rfz. e2b is a reverse voltage to D2, and D2 is not conductive (see Figure(b) ). In the time of π-2π, e2b is a positive voltage to D2, D2 is turned on, and the voltage obtained on Rfz is still up positive and down negative voltage, therefore e2a is a reverse voltage to D1, and D1 is not conductive (see figure (c). Figure 5. Full-Wave Rectifier Circuit Wave Repeated this way, because the two rectifier elements D1 and D2 conduct electricity in turn, the result is that the load resistor Rfz has the same direction of current at the positive and negative half cycles, as shown in Figure(b). This is full-wave rectification, which not only uses the positive half-cycle, but also cleverly uses the negative half-cycle. Full-wave rectifier greatly improves the rectification efficiency. Figure 6. Full-Wave Rectifier Circuits This circuit requires the transformer to have a secondary center tap that makes the two ends symmetrical, which brings a lot of trouble to the production. In addition, in this circuit, the maximum reverse voltage that each rectifier diode can withstand is twice the maximum value of the transformer secondary voltage, so diodes should withstand higher voltages.   6.3 Bridge Rectifier Circuit Figure 7. Bridge Rectifier Circuit The bridge rectifier circuit is the most used rectification circuit. It has the advantages of a full-wave rectifier circuit as long as two diode ports are connected to form a bridge structure, so its shortcomings are overcome to a certain extent.The bridge rectifier circuit is as follows: Figure 8. Bridge Rectifier Circuit (a) When e2 is a positive half cycle, D1, D3 and the direction voltage, D1, D3 are turned on; D2, D4 are applied with reverse voltage, they are turned off. E2, Dl, Rfz, and D3 are energized a loop in the circuit. On Rfz, a positive and negative half-wave washing voltage is formed. When e2 is a negative half cycle, a positive voltage is applied to D2 and D4, and they are turned on; Apply reverse voltage to D1 and D3, they are cut off. E2, D2Rfz, and D4 are energized a loop in the circuit, and the other half-wave rectified voltage is also formed on Rfz. Figure 9. Bridge Rectifier Circuit (b) If repeated, a full-wave rectified voltage at Rfz is made. The waveform diagram is the same as the full-wave rectifier. It is not difficult to see from the figure that the reverse voltage of each diode in the bridge circuit is equal to the maximum value of the secondary voltage of the transformer, which is half smaller than the full-wave cleaning circuit.     Ⅶ High-frequency Rectifier Diodes The rectifier diode in the switching power supply must have the characteristics of low forward voltage reduction and fast recovery, and should also have sufficient output power. The following three types of high-frequency diodes can be used: fast recovery rectifier, ultra-fast recovery rectifier, and Schottky diode rectifier.Fast recovery and ultra-fast recovery rectifier diodes have moderate and high forward voltage drop, and the range is from 0.8 to 1.2V. These two types of rectifier diodes also have higher cut-off voltage parameters. Therefore, they are particularly suitable for use in low-power auxiliary power circuits with output voltages around 12V.Compared with general rectifier diodes, the reverse recovery time difference between fast recovery rectifier diodes and ultra-fast recovery rectifier diodes is reduced to the nanosecond level, thus greatly improving the efficiency of the power supply. According to experience, when choosing a fast recovery rectifier diode, its reverse recovery time should be at least 1/3 of the rise time of the switching transistor. These two kinds of rectifier diodes also reduce the switching voltage spike, because it will affect the ripple of the output DC voltage.Whether fast recovery rectifier diodes and ultra-fast recovery rectifier diodes used in switching power supplies need a heat sink, which depends on the maximum power of the circuit. Under normal circumstances, the allowable junction temperature is 175°C during manufacture. The manufacturer has a technical parameters provided for the designer to calculate the maximum output operating current, voltage, and case temperature. Even under the action of a large forward current, the forward voltage drop of Schottky rectifier diodes is very low, only about 0.4V. Moreover, as the junction temperature increases, its forward voltage drop decreases. Therefore, Schottky rectifier diodes are particularly suitable for low-voltage output circuits around 5V. Its reverse recovery time is negligible, because this device is a semiconductor device with majority carrier. During the switching process of the device, there is no need to remove the stored charge of the minority carrier.Schottky rectifier diodes have two major shortcomings: First, the reverse cut-off voltage tolerance is low, about 100V; second, the reverse leakage current is large, making the device more susceptible to have heat breakdown than other types of rectifier devices. Of course, these shortcomings can also be overcome by adding a transient overvoltage protection circuit and appropriately controlling the junction temperature.     Ⅷ FAQ 1. How does a rectifier diode work?A rectifier is a device that converts an Alternating Current (AC) into a Direct Current (DC) by using one or more contact diodes. ... In simple words, a diode allows current in just one direction. This unique property of the diode allows it to act sort of a rectifier by converting an alternating current to a DC source.   2. What is a function of rectifier diode?A rectifier diode is an electrical device that converts alternating current (AC), which periodically reverses direction, to direct current (DC).   3. What is the function of diode in rectifier circuit?A characteristic of diodes is that current flows (forward direction) or current does not flow (reverse direction) depending on the direction of applied voltage. This works to convert alternating current (AC) voltage to direct current (DC).   4. Which is used as rectifier?We know that the core use of rectifier is to convert AC current into DC current. The rectifier consists of semiconductor diodes to do this function.   5. What is the limitation of a diode rectifier?Disadvantages of Full Wave Bridge RectifierIt needs four diodes. The circuit is not suitable when a small voltage is required to be rectified. It is because, in this case, the two diodes are connected in series and offer double voltage drop due to their internal resistance.   6. What is the ideal rectifier diode efficiency?It is the ratio of DC output power to the AC input power. The rectifier efficiency of a full-wave rectifier is 81.2%.   7. What is a fast recovery rectifier?Definition: Fast Recovery Diode is a semiconductor device which possesses short reverse recovery time for rectification purpose at high frequency. A quick recovery time is crucial for rectification of high-frequency AC signal. Diodes are mostly used in rectifiers because they possess ultra-high switching speed.   8. Which diode is fast recovery diode?FRD stands for fast recovery diodes. They offer high-speed support and generally have a trr of approximately 50 to 100 ns. With a VF of approximately 1.5V, it is rather large when compared to general rectifying diodes. Another generic term for the FRD type would be a “High-speed Diode.”   9. What is ultra fast recovery diode?A fast diode is a faster-than-standard current rectifier. ... A fast rectifier typically recovers ten times faster than a standard rectifier, and an ultrafast designation is usually applied to rectifiers designed to beat the standard rectifier recovery by being more than fifty times faster.   10. What is the difference between a Schottky diode and a rectifier diode?Schottky diode, also known as barrier diode is mainly used in low voltage circuits because the forward voltage drop of Schottky diode(Vf) is less than a rectifier diode. The forward voltage drop of a Schottky diode is typically in the range of . 25 to 0.5 V whereas the Vf of a rectifier diode is around 0.7 volts.   11. What is Schottky barrier rectifier?The Schottky diode or Schottky Barrier Rectifier is named after the German physicist Walter H. Schottky, is a semiconductor diode designed with a metal by the semiconductor junction. It has a low-forward voltage drop and a very rapid switching act. ... Actually, it is one of the oldest semiconductor devices in reality.

IntroductionIn the landscape of modern electronics in 2025, the Zener diode remains a fundamental component for voltage stabilization and reference. Unlike standard diodes, Zener diodes are engineered to operate in the reverse breakdown region. By utilizing the specific breakdown voltage of the PN junction, they maintain a constant voltage across their terminals even when the current varies significantly.Zener diodes serve critical roles as voltage regulators, surge suppressors, and reference elements in power supply circuits. Given their importance, proper maintenance and accurate fault detection are essential skills for technicians and engineers. This guide details how to detect, test, and distinguish Zener diodes using modern troubleshooting techniques.Ⅰ How to Test Zener Diodes with Three Methods?1.1 Resistance Measurement (Basic Health Check)The resistance measurement method describes the basic health of the component—specifically, checking for shorts or open circuits. While modern digital multimeters (DMMs) are standard in 2025, analog multimeters can still be useful for this specific test due to their load characteristics.The Principle: Using an analog multimeter set to the Rx10K block (which typically uses an internal 9V or 15V battery), you can bias the PN junction.Forward Bias: Connect the red probe (negative in analog meters) to the Anode and black to the Cathode. You should see low resistance.Reverse Bias: Connect in reverse. Ideally, the resistance should be high. However, if the battery voltage exceeds the Zener voltage (e.g., a 5V Zener tested with a 9V internal battery), you will measure a resistance drop, indicating the Zener is functioning (breaking down) correctly.Using a Digital Multimeter: Set the meter to Diode Mode. Touch the probes to the diode. In one direction (forward bias), you should see a voltage drop between 0.6V and 0.8V. In the reverse direction, it should show "OL" (Open Loop) unless the Zener voltage is lower than the meter's test voltage (rare in modern DMMs). If you read 0.000V in both directions, the diode is shorted.1.2 Voltage Measurement (The Most Accurate Method)To determine the exact Zener voltage (Vz), testing the component "live" or in a test circuit is required. This is the professional standard for verifying if a Zener diode is drifting or operating within tolerance.Procedure:Connect a DC Power Supply in series with a current-limiting resistor (e.g., 1kΩ to 10kΩ) and the Zener diode (Reverse Biased).Set the power supply voltage higher than the expected Zener voltage.Use a digital multimeter in DC Voltage mode to measure across the Zener diode.Result: If the reading matches the component's rated voltage (e.g., 5.1V, 12V), the diode is healthy. If the voltage fluctuates significantly or equals the input voltage, the diode is faulty.1.3 Measuring High-Voltage Zeners (Insulation Tester)For industrial Zener diodes with high regulation voltages (above 20V or 50V), a standard multimeter's test voltage is insufficient. In these cases, a Megger (Insulation Resistance Tester) or a high-voltage DC supply can be used.Method: Connect the Megger leads to the diode (reversed). Slowly generate voltage. When the resistance reading stabilizes at a specific voltage drop, that represents the Zener breakdown voltage. Warning: Ensure the current is limited to prevent destroying the device, as Meggers can output high voltages meant for insulation testing, not semiconductor characterizing.Figure 1. Standard Zener Diode SymbolⅡ How to Measure the Leakage of Zener Diode?Leakage current is a silent killer in precision circuits. A Zener diode might pass a basic voltage test but fail under load or temperature changes due to excessive leakage.Advanced Testing: A standard multimeter cannot effectively detect minor leakage. Instead, use a Curve Tracer or an Oscilloscope with a component tester function. By applying a reverse voltage gradually, you monitor the current. A healthy Zener should conduct negligible current until it hits the "Knee Voltage." If the current rises linearly before the breakdown voltage, the diode is "leaky" (soft breakdown) and should be replaced.Ⅲ How to Figure the Polarity of the Zener Diode?Correct installation is vital. Here is how to identify the Anode (+) and Cathode (-):Visual Inspection (Through-Hole): Look for the black or blue band on the glass/plastic body. This band indicates the Cathode (-) side.Visual Inspection (SMD): On Surface Mount Devices, the Cathode is usually marked with a white bar or a chamfered edge.Multimeter Test: Set to Diode Mode. Place probes on terminals. The orientation that gives a reading (approx 0.7V) indicates the Red probe is on the Anode and the Black probe is on the Cathode.Figure 2. Zener Diode Regulator ConfigurationⅣ How to Identify Color Code Zener Diode?While many modern diodes have the part number printed directly (e.g., "5V1" or "1N4733"), older glass-passivated diodes use color bands similar to resistors.The color bands typically represent the JEDEC type number (e.g., 1Nxxxx). Alternatively, in the European BZX series, bands may denote voltage: Example: A diode with Brown (1) and Red (2) bands might represent 12V (depending on the specific manufacturer coding system). Always cross-reference with a datasheet or use a modern SMD/Component Tester (LCR Meter) to verify the breakdown voltage automatically.Ⅴ How to Distinguish Zener Diodes and Ordinary Diodes?Physically, Zener diodes and standard signal diodes (like the 1N4148) often look identical (small, glass, orange/red body with a black band).The Distinction Test: The defining characteristic is the Reverse Breakdown Voltage.Standard Diode: Will block reverse voltage up to very high limits (e.g., 100V+). Under a 12V reverse test, it acts as an Open Circuit.Zener Diode: Will conduct current when the reverse voltage exceeds its rating (e.g., 5.1V).Practical Trick: Apply 12V DC via a 1kΩ resistor to the diode in reverse. Measure the voltage across the diode. If it reads ~12V, it is likely a standard diode. If it reads a lower, stable voltage (e.g., 5.1V, 9.1V), it is a Zener Diode.Figure 3. Zener Diode Voltage Regulator CircuitⅥ FAQ1. How do you identify a 12V Zener diode?The most reliable method is to place the diode in a reverse-biased circuit with a power supply set to roughly 15V-20V and a series resistor. If the voltage across the diode clamps and stabilizes at approximately 12V, it is a 12V Zener. If you use a standard multimeter diode test, it will only show the forward voltage drop (~0.7V), which does not reveal the Zener voltage.2. How do you know if a Zener diode is bad?Common Failure Signs:Short Circuit: Reading 0Ω or 0V in both directions (most common failure).Open Circuit: Reading "OL" in both directions.Drift: The diode regulates voltage, but at the wrong value (e.g., a 5V Zener regulating at 3V or 8V).3. What is the difference between a rectifier diode and a Zener diode?A standard rectifier diode is designed to conduct current in only one direction (Forward Bias) and block voltage in the reverse direction. A Zener diode is designed to conduct in the forward direction like a normal diode, but also safely conduct in the reverse direction once a specific voltage threshold (Zener Voltage) is reached.4. What happens when a Zener diode is shorted?When a Zener diode fails short, it acts like a straight piece of wire. It allows maximum current to flow in both directions with zero resistance. In a power supply circuit, this usually causes the fuse to blow or the series resistor to overheat and burn out immediately.5. Can I test a Zener diode in-circuit?In-circuit testing is often inaccurate due to parallel components (capacitors or other resistors) affecting the reading. However, you can check for a dead short. If you measure 0Ω across the Zener while it is on the board, it is likely dead. For accurate voltage testing, lift one leg of the component off the PCB.6. Why is a Zener diode used in reverse bias?Zener diodes are heavily doped. This doping creates a very thin depletion region that allows electrons to tunnel across the junction when a specific reverse voltage is applied (Zener Effect). This property is what provides the stable reference voltage required for regulation.7. What happens if you forward bias a Zener diode?If you connect a Zener diode in forward bias (Anode to Positive), it behaves exactly like a standard silicon diode. It will conduct current with a voltage drop of approximately 0.7V. It does not provide voltage regulation in this orientation.8. How do I identify an SMD Zener diode?SMD (Surface Mount Device) Zeners are often too small for full part numbers. They use Marking Codes (typically 2 or 3 alphanumeric characters). You must look up this code in an "SMD Codebook" or datasheet to identify the voltage rating. Visually, they often come in SOT-23 (3-leg) or SOD-123 (2-leg) packages with a band marking the cathode.

For electronics enthusiasts, technicians, and engineers, the diode is a fundamental component. Knowing how to verify its condition is a critical skill for troubleshooting circuits. Whether you are using a classic analog multimeter or a modern digital multimeter (DMM), the principles remain the same.In this updated article, we will cover the testing methods for 11 different types of diodes, ranging from standard rectifiers to specialized laser and high-frequency components.I. Testing of a Standard DiodeVideo Overview: The basics of testing diode polarity and continuity.Modern Tip for 2025: Most technicians now use Digital Multimeters.Analog Meter: Looks for needle deflection (resistance).Digital Meter (DMM): Use the "Diode Mode" (symbol: ➔+). A good silicon diode drops between 0.5V and 0.8V. If it reads "OL" (Open Loop) in both directions, it is open. If it reads 0.00V, it is shorted.II. Testing 11 Specialized Types of Diodes2.1 Testing of Low-power Crystal DiodesA. Discriminating Positive and Negative Electrodes(1) Housing Symbol: Observe the symbol mark on the housing. Usually, the diode is marked with a standard arrow symbol. The end with the triangular arrow is the positive electrode (Anode), and the flat line is the negative electrode (Cathode).(2) Color Bands/Dots: On point-contact diodes, look for polar color points (white or red). Generally, the marked end is positive. However, on standard cylindrical diodes, the colored ring/band indicates the negative (Cathode) side.(3) Multimeter Measurement: Using the resistance setting (Ohms), the connection that results in a smaller resistance value indicates forward bias. For analog meters, the black lead acts as positive internal voltage; for digital meters, the red lead is positive.B. Detecting Highest Working Frequency ($f_M$)The operating frequency depends on the internal construction. Point-contact diodes are typically high-frequency, while surface-contact diodes are for low-frequency rectification. When testing with an analog multimeter at $R \times 1k$, high-frequency tubes often show a forward resistance of less than 1kΩ.C. Detecting Highest Reverse Breakdown Voltage ($V_{RM}$)The highest reverse working voltage is the peak AC voltage the diode can block. Note that the actual breakdown voltage is usually much higher (often 2x) than the rated working voltage to ensure safety margins.2.2 Testing of Glass-Sealed Silicon High-Speed Switching DiodesCommon examples include the 1N4148. The testing method is identical to ordinary diodes. However, note that the forward resistance might appear slightly higher than power rectifiers. Test values (Analog): Forward resistance 5kΩ to 10kΩ ($R \times 1k$ scale); Reverse resistance is infinite.2.3 Testing of Fast Recovery and Ultra-Fast Recovery DiodesThese are critical in Switching Power Supplies (SMPS). Testing follows the plastic-encapsulated silicon rectifier method.Step 1: Use $R \times 1k$ block. Forward resistance is roughly 4.5kΩ; reverse is infinite.Step 2: Use $R \times 1$ block. Forward resistance drops to a few ohms; reverse remains infinite.2.4 Testing of Bidirectional Trigger Diode (DIAC)Commonly found in dimmer switches (e.g., DB3). Resistance Check: With a multimeter at $R \times 1k$, resistance should be infinite in both directions. If the pointer swings or the DMM reads low ohms, the component has a leakage fault.Voltage Test: To test the breakover voltage ($V_{BO}$), you need a high-voltage source (like a Megohmmeter). Measure the voltage at which conduction begins. The symmetry is good if the forward and reverse breakover voltages are close in value.2.5 Testing of Transient Voltage Suppression Diode (TVS)TVS diodes protect circuits from voltage spikes.Unipolar TVS: Tests like a normal diode. Forward resistance ~4kΩ, reverse infinite.Bipolar (Two-way) TVS: Should read infinite resistance in both directions during a standard low-voltage multimeter test. If it conducts, it is likely shorted (which is its failure mode after absorbing a massive spike).2.6 Testing of High-Frequency DiodesA. Polarity: Usually identified by color codes. Similar to standard diodes, the band (often green) indicates the Cathode (negative).B. Measurement: Using a 500-type multimeter at $R \times 1k$, normal forward resistance is 5kΩ to 5.5kΩ, with infinite reverse resistance.2.7 Testing of Varactor DiodeUsed in tuning circuits. Set the multimeter to $R \times 10k$. Regardless of lead swapping, the resistance between pins should remain infinite. Any resistance reading suggests leakage or breakdown. To test the actual capacitance change, you would need an LCR meter or specialized tester.2.8 Testing of Monochromatic Light-Emitting Diodes (LEDs)Note on Voltage: Modern LEDs (especially Blue and White) typically require >3V to light up. The traditional "1.5V battery" trick may not work.The Test: Most Digital Multimeters in "Diode Mode" output enough voltage to make an LED glow faintly. If using an external power source: Connect a 3V battery (like a CR2032) or two 1.5V batteries in series. Result: When positive connects to positive, the LED should light up. If it remains dark in both orientations, it is open.2.9 Testing of Infrared (IR) LEDsA. Polarity: Long pin is Anode (+), Short pin is Cathode (-). Internally, the wider electrode is usually the negative side.B. Resistance Test: At $R \times 1k$, forward resistance is ~30kΩ, reverse >500kΩ.C. The Camera Trick (New): Since human eyes cannot see IR light, power the LED and look at it through your smartphone camera. Digital sensors can "see" IR light—it will appear purple/white on the screen if the LED is working.2.10 Testing of Infrared Receiving DiodeA. Polarity: On the receiving window side, pins are usually positive (left) and negative (right), but always verify with the datasheet. Look for a beveled/oblique edge on the casing; the pin closest to the bevel is usually negative.B. Test: In ambient light, measure resistance. Shield the window with your hand (darkness) -> resistance should increase. Expose it to light -> resistance should decrease. This change confirms the sensor is reactive.2.11 Testing of Laser DiodeSAFETY WARNING: Never look directly into a laser diode or point it at eyes.Using a multimeter at $R \times 1k$: Determine pins similar to a normal diode. Note: Laser diodes have a higher forward voltage drop than standard diodes. The meter pointer might deflect only slightly (high resistance) even in the forward direction. Reverse resistance should be infinite.Frequently Asked Questions (FAQ)1. What is a diode and its symbol?A diode is an electronic component that functions as a one-way valve for electricity, allowing current to flow in only one direction. In circuit diagrams, it is represented by a triangle pointing towards a line (the line represents the barrier/cathode).2. What is special about a diode?Its ability to block reverse current is unique. Furthermore, special types like LEDs emit photons (light) when electrons change energy levels across the junction. This electroluminescence makes them essential for modern lighting.3. Are diodes AC or DC?Diodes work with both but handle them differently. They allow DC to pass. When applied to AC, they block the negative half of the cycle, effectively converting Alternating Current (AC) into pulsating Direct Current (DC). This process is called Rectification.4. Why do we use a Zener diode?Unlike normal diodes that burn out if forced to conduct backwards, Zener diodes are designed to conduct in reverse at a specific, precise voltage (Breakdown Voltage). This makes them perfect for Voltage Regulation and reference voltages.5. What is the unit of a diode?The diode itself is a component, not a quantity, so it has no "unit." However, its characteristics are measured in standard units: Forward Voltage ($V_F$): Volts (V) Current Rating: Amperes (A) Power Dissipation: Watts (W)6. Do diodes have resistance?Yes, but it is non-linear. Unlike a resistor which has a fixed value, a diode's resistance changes dynamically based on the voltage applied. When forward-biased, resistance is very low; when reverse-biased, it is extremely high.7. Does a diode reduce current?Indirectly, yes. Because a diode consumes a small amount of voltage (Voltage Drop, typically 0.7V for Silicon), the total voltage available to the load decreases, which can slightly reduce current according to Ohm's Law. It also completely blocks current flowing in the wrong direction.8. How are diodes classified?They are classified by material (Silicon, Germanium), construction (Point contact, Surface mount/SMD), and function (Rectifier, Zener, Schottky, LED, Photodiode, Laser, TVS).9. What is the most common diode?The 1N4007 is likely the most common power rectifier diode, found in almost every adapter. For low-signal switching, the 1N4148 is the industry standard.10. What is the difference between a Zener and a Schottky diode?Schottky Diodes are designed for speed and low voltage drop (efficiency), often used in high-speed switching. Zener Diodes are designed for voltage stability, meant to operate in the reverse breakdown region to regulate voltage.11. What is the difference between Schottky diode and normal diode?A normal PN junction diode connects P-type and N-type semiconductors. A Schottky diode connects an N-type semiconductor to a Metal plate. This results in a much lower forward voltage drop (approx. 0.2V-0.4V) and faster switching speeds compared to normal silicon diodes (0.7V).12. Why is it called a diode?The name comes from the Greek root "di" (two) and "ode" (path/electrode). It literally refers to a device with two electrodes: the Anode and the Cathode.13. Is a diode the same as a resistor?No. A resistor limits current equally in both directions (linear). A diode acts as a gate, allowing current only one way (non-linear). Using one in place of the other usually causes circuit failure.14. How much voltage can a diode take?This depends on the "Peak Inverse Voltage" (PIV) rating. Small signal diodes might handle 75V, while rectifier diodes like the 1N4007 can withstand up to 1000V.15. Can a resistor replace a diode?Generally, no. Since a resistor conducts both ways, replacing a diode (rectifier) with a resistor would allow AC to pass where DC is required, potentially blowing up capacitors or destroying sensitive chips.

When it comes to low-power, high-current, and ultra-high-speed semiconductor devices, many electronics hobbyists or engineers must first think of Schottky diodes (SBD). But do you really know how to use Schottky diodes? Compared with other diodes, what is special about Schottky diodes? This article will answer these questions for you and introduce Schottky diodes in details. This short video gives a brief introduction to Schottky Diode Catalog I. Schottky Diode Brief Introduction II. How does Schottky Diode Work? III. The Structure of Schottky Diode IV. How to Test Schottky Diode? V. Pros and Cons of Schottky Diode VI. Where to Use Schottky Diode? VII. How to Use Schottky Diode Correctly? FAQ I. Brief Introduction to Schottky Diode  Schottky diodes are named after their inventor, Dr. Schottky. The full name is: Schottky RecTIfier Diode (abbreviated as SR), also called: Schottky barrier diode, or SBD.   Schottky diode is a low-power, ultra-high-speed semiconductor device. The most notable feature is its extremely short reverse recovery time (can be as small as a few nanoseconds), and the forward voltage drop is only about 0.4V. It is mostly used as high-frequency, low-voltage, high-current rectifier diodes, freewheeling diodes, protection diodes, and also useful as rectifier diodes and small-signal detector diodes in circuits such as microwave communications. It is more common in communication power supplies, inverters, etc.   A typical application of Schottky diodes is in the switching circuit of a bipolar transistor BJT. By connecting a Shockley diode to the BJT to clamp, the transistor is actually close to the off state when the transistor is on, thereby improving the transistor’s performance. Switching speed. This method is a technique used in the TTL internal circuits of typical digital ICs such as 74LS, 74ALS, and 74AS.   The biggest feature of Schottky diodes is that the forward voltage drop VF is relatively small. In the case of the same current, its forward voltage drop is much smaller. In addition, its recovery time is short. It also has some shortcomings: the withstand voltage is relatively low, and the leakage current is slightly larger. It must be fully considered when selecting. II. How does Schottky Diode Work? Schottky diodes are metal-semiconductor devices made of precious metals (gold, silver, aluminum, platinum, etc.) A as the anode and N-type semiconductor B as the cathode. The barrier formed on the contact surface of the two has rectification characteristics.   Because there are a large number of electrons in N-type semiconductors, and there are only a small amount of free electrons in noble metals, electrons diffuse from the high concentration of B to the low concentration of A. Obviously, there are no holes in metal A, and there is no diffusion movement of holes from A to B.   As electrons continue to diffuse from B to A, the electron concentration on the surface of B gradually decreases, and the electrical neutrality of the surface is destroyed, so a potential barrier is formed, and the direction of the electric field is B→A. But under the action of this electric field, the electrons in A will also produce a drifting movement from A→B, thereby weakening the electric field formed by the diffusion movement.   When a space charge region with a certain width is established, the drifting movement of electrons caused by the electric field and the diffusion movement of electrons caused by different concentrations reach a relative balance, forming a Schottky barrier.   The internal circuit structure of a typical Schottky rectifier is based on an N-type semiconductor, and an N-epitaxial layer with arsenic as a dopant is formed on it. The anode uses materials such as molybdenum or aluminum to make a barrier layer. Use silicon dioxide (SiO2) to eliminate the electric field in the edge area and improve the withstand voltage of the tube.   The N-type substrate has a small on-state resistance, and its doping concentration is 100% higher than that of the H-layer. An N+ cathode layer is formed under the substrate, and its function is to reduce the contact resistance of the cathode. By adjusting the structural parameters, a Schottky barrier is formed between the N-type substrate and the anode metal.   When a forward bias is applied to both ends of the Schottky barrier (the anode metal is connected to the positive pole of the power supply, and the N-type substrate is connected to the negative pole of the power supply), the Schottky barrier layer becomes narrower and its internal resistance becomes smaller; on the contrary, if When reverse bias is applied to both ends of the Schottky barrier, the Schottky barrier layer becomes wider and its internal resistance becomes larger.   In summary, the structure principle of Schottky rectifier is very different from PN junction rectifier. The PN junction rectifier is usually called the junction rectifier, and the metal-semi-conductor rectifier is called the Schottky rectifier.   Aluminum-silicon Schottky diodes manufactured by the silicon plane process have also come out, which not only saves precious metals, but also Significantly reduce costs and improve the consistency of parameters. III. The Structure of Schottky Diode The structure and materials of the new high-voltage SBD are different from the traditional SBD. Traditional SBD is formed by contacting metal and semiconductor. The metal material can be aluminum, gold, molybdenum, nickel, titanium, etc., and the semiconductor is usually silicon (Si) or gallium arsenide (GaAs).   Since electrons have higher mobility than holes, in order to obtain good frequency characteristics, N-type semiconductor materials are selected as the substrate. In order to reduce the junction capacitance of the SBD and increase the reverse breakdown voltage without making the series resistance too large, a high-resistance N-thin layer is usually epitaxially on the N+ substrate.   CP is the parallel capacitance of the shell and tube, LS is the lead inductance, RS is the series resistance including the semiconductor body resistance and lead resistance, and Cj and Rj are the junction capacitance and junction resistance (both are functions of bias current and bias voltage), respectively.   As we all know, there are a large number of conductive electrons inside a metal conductor. When the metal is in contact with the semiconductor (the distance between the two is only an order of magnitude of the atom), the Fermi level of the metal is lower than the Fermi level of the semiconductor. At the sub-energy level corresponding to the conduction band of the semiconductor inside the metal, the electron density is less than that of the conduction band of the semiconductor.   Therefore, after the two contact, electrons will diffuse from the semiconductor to the metal, so that the metal is negatively charged and the semiconductor is positively charged. Since metal is an ideal conductor, negative charges are only distributed in a thin layer with the size of an atom on the surface.   For N-type semiconductors, the donor impurity atoms that have lost electrons become positive ions, which are distributed in a larger thickness. As a result of the diffusion and movement of electrons from the semiconductor to the metal, a space charge zone, self-built electric field and potential barrier are formed, and the depletion layer is only on the side of the N-type semiconductor (all the barrier zone falls on the semiconductor side).   The direction of the self-built electric field in the barrier zone points from the N-type region to the metal. With the increase of the thermionic self-built field, the drift current opposite to the diffusion current direction increases, and finally a dynamic equilibrium is reached, forming a contact potential between the metal and the semiconductor Barrier, this is the Schottky barrier.   When the applied voltage is zero, the diffusion current of electrons is equal to the reverse drift current, achieving dynamic equilibrium. When a forward bias is applied (that is, a positive voltage is applied to a metal and a negative voltage is applied to a semiconductor), the self-built field is weakened and the barrier on the semiconductor side is lowered, thus forming a positive current from the metal to the semiconductor.   When a reverse bias is applied, the self-built field increases, and the barrier height increases, forming a smaller reverse current from the semiconductor to the metal. Therefore, the SBD, like the PN junction diode, is a non-linear device with unidirectional conductivity. IV. How to Test Schottky Diode? Here we show you three testing method for three different diodes. 1. Detect low-power crystal diodes   A. Discrimination of positive and negative electrodes   (1) Observe the symbol mark on the housing. Usually the diode is marked with the symbol of the diode on the housing of the diode, one end with a triangular arrow is the positive electrode, and the other end is the negative electrode.   (2) Observe the color dots on the shell. The case of point contact diodes is usually marked with polar color points (white or red). Generally, the end marked with a colored dot is the positive electrode. Other diodes are marked with a color ring, and the end with the color ring is the negative electrode.   (3) Based on a measurement with a smaller resistance value, the end connected to the black test lead is the positive electrode, and the end connected to the red test lead is the negative electrode.   B. Detect the highest working frequency fM. The operating frequency of crystal diodes can be found in the relevant characteristic table. In practice, they are often distinguished by observing the contact wires inside the diode.    For example, point contact diodes are high-frequency tubes, and surface contact diodes are mostly low-frequency tubes. In addition, you can also use the multimeter R×1k block to test, generally the forward resistance is less than 1k high frequency tube.   C. Detect the highest reverse breakdown voltage VRM. For alternating current, because of constant changes, the highest reverse working voltage is also the peak alternating current voltage that the diode bears.   It should be pointed out that the highest reverse working voltage is not the breakdown voltage of the diode. Under normal circumstances, the breakdown voltage of the diode is much higher than the maximum reverse working voltage (about twice as high).   2. Detection of high frequency varistor diodes   A. identification diode positive and negative   The difference in appearance between high-frequency varistor diodes and ordinary diodes is that their color code is different. The color code of ordinary diodes is generally black, while the color code of high-frequency varistor diodes is light. Its polarity law is similar to that of ordinary diodes, that is, the end with the green ring is the cathode, and the end with the green ring is the anode.   B. Measure the forward and reverse resistance to judge whether it is good or bad   The specific method is the same as the method of measuring the forward and reverse resistance of ordinary diodes. When using a 500-type multimeter to measure the R×1k gear, the forward resistance of a normal high-frequency varistor diode is 5k～55k, and the reverse resistance is infinity.   3. Transient voltage suppression diode (TVS) detection   Use a multimeter to measure the quality of the tube. For a unipolar TVS, according to the method of measuring ordinary diodes, the forward and reverse resistance can be measured. Generally, the forward resistance is about 4kΩ, and the reverse resistance is infinite.   For the two-way polar TVS, the resistance between the two pins should be infinite when the red and black test leads are arbitrarily exchanged. Otherwise, the tube has poor performance or has been damaged. V. Pros and Cons of Schottky Diode Pros:  Schottky diodes have the advantages of high switching frequency and reduced forward voltage, but their reverse breakdown voltage is relatively low, mostly not higher than 60V, and the highest is only about 100V, which limits its application range.   Like in the switching power supply (SMPS) and power factor correction (PFC) circuit, the freewheeling diode of the power switch device, the high frequency rectifier diode of 100V or more used in the transformer secondary, the 600V～1.2kV high speed diode in the RCD snubber circuit, and For PFC boosting 600V diodes, only fast recovery epitaxial diodes (FRED) and ultra-fast recovery diodes (UFRD) are used.   The reverse recovery time Trr of UFRD is also above 20ns, which cannot meet the needs of 1MHz～3MHz SMPS in fields such as space stations. Even for SMPS with hard switching of 100kHz, due to the large conduction loss and switching loss of UFRD, the case temperature is very high, and a larger heat sink is required, which increases the size and weight of SMPS, which does not meet the requirements of miniaturization and lightness. Development trend.   Therefore, the development of high-voltage SBDs above 100V has always been a research topic and a hot spot of concern. In recent years, SBD has made breakthrough progress. High-voltage SBDs of 150V and 200V have been put on the market, and SBDs with more than 1kV made of new materials have also been successfully developed, thus injecting new vitality and vitality into their applications.   Cons:  The biggest disadvantage of Schottky diodes is their low reverse bias voltage and large reverse leakage current. For example, Schottky diodes using silicon and metal as materials have the highest reverse bias voltage rating. To 50V, and the reverse leakage current value is a positive temperature characteristic, it is easy to increase rapidly as the temperature rises, and it is necessary to pay attention to the hidden concern of thermal runaway in practical design.   In order to avoid the above-mentioned problems, the reverse bias voltage of the Schottky diode in actual use will be much smaller than its rated value. However, the technology of Schottky diodes has also progressed, and its reverse bias voltage rating can reach up to 200V. VI. Where to Use Schottky Diode? The structure and characteristics of SBD make it suitable for high-frequency rectification in low-voltage and high-current output occasions. It is used for detection and mixing at very high frequencies (such as X-band, C-band, S-band and Ku-band). Used as a clamp in high-speed logic circuits. SBD is often used in ICs. SBD*TTL integrated circuits have long become the mainstream of TTL circuits and are widely used in high-speed computers.   In addition to the characteristic parameters of ordinary PN junction diodes, SBD electrical parameters used for detection and mixing also include intermediate frequency impedance (referring to the impedance presented by the SBD to the specified intermediate frequency when the rated local oscillator power is applied, generally between 200Ω and 600Ω) , Voltage standing wave ratio (generally ≤ 2) and noise figure, etc. VII. How to Use Schottky Diode Correctly? Schottky diodes are widely used in circuits such as switching power supplies, frequency converters, and drivers. In different applications, different factors need to be considered, and different devices have different performances. Therefore, when selecting Schottky diodes, the following key parameters need to be considered comprehensively.   1. The conduction voltage drop VFVF is the voltage drop across the diode when the diode is forward-conducting. When the current through the diode is larger, the VF is larger; when the diode temperature is higher, the VF is smaller.   2. The reverse saturation leakage current IRIR refers to the current that flows through the diode when the reverse voltage is added to the two ends of the diode. The reverse leakage current of the Schottky diode is relatively large. The choice of Schottky diode is to choose a diode with a smaller IR as much as possible.   3. The rated current IF refers to the average current value calculated according to the allowable temperature rise during long-term operation of the diode.   4. The maximum surge current IFSM allows excessive forward current to flow. It is not a normal current, but an instantaneous current, which is quite large.   5. Even if the maximum reverse peak voltage VRM does not have reverse current, as long as the reverse voltage is continuously increased, the diode will be damaged sooner or later.   This reverse voltage that can be applied is not an instantaneous voltage, but a forward and reverse voltage repeatedly applied. Because the AC voltage is added to the rectifier, its maximum value is a specified important factor.   The maximum reverse peak voltage VRM refers to the maximum reverse voltage that can be applied to avoid breakdown. Currently Schottky's highest VRM value is 150V. FAQ 1. What is Schottky diode used for? Schottky diodes are used for their low turn-on voltage, fast recovery time and low-loss energy at higher frequencies. These characteristics make Schottky diodes capable of rectifying a current by facilitating a quick transition from conducting to blocking state. 2. What is the difference between Schottky diode and normal diode? In the normal rectifier grade PN junction diode, the junction is formed between P type semiconductor to N type semiconductor. Whereas in Schottky diode the junction is in between N type semiconductor to Metal plate. The schottky barrier diode has electrons as majority carriers on both sides of the junction. 3. How does Schottky diode work? In a Schottky diode, a semiconductor–metal junction is formed between a semiconductor and a metal, thus creating a Schottky barrier. The N-type semiconductor acts as the cathode and the metal side acts as the anode of the diode. This Schottky barrier results in both a low forward voltage drop and very fast switching. 4. What are the two important features of a Schottky diode? We have seen here that the Schottky Diode also known as a Schottky Barrier Diode is a solid-state semiconductor diode in which a metal electrode and an n-type semiconductor form the diodes ms-junction giving it two major advantages over traditional pn-junction diodes, a faster switching speed, and a low forward bias. 5. What is Schottky diode made of? Schottky diodes made from palladium silicide (PdSi)[clarification needed] are excellent due to their lower forward voltage (which has to be lower than the forward voltage of the base-collector junction). 6. Why Schottky is called hot carrier diode? When a Schottky diode is in unbiased condition, the electrons lying on the semiconductor side have a very low energy level when compared to the electrons present in the metal.Thus, the electrons cannot flow through the junction barrier which is called the Schottky barrier. If the diode is forward biased, electrons present in the N-side get sufficient energy to cross the junction barrier and enters the metal.These electrons enter into the metal with tremendous energy. Consequently, these electrons are known as hot carriers. Thus the diode is called a hot-carrier diode. 7. What is Schottky barrier rectifier? The Schottky diode or Schottky Barrier Rectifier is named after the German physicist “Walter H. Schottky”, is a semiconductor diode designed with a metal by the semiconductor junction. It has a low-forward voltage drop and a very rapid switching act. ... Actually, it is one of the oldest semiconductor devices in reality. 8. What is meant by Schottky effect? Schottky effect, increase in the discharge of electrons from the surface of a heated material by application of an electric field that reduces the value of the energy required for electron emission. ... The effect is named after its discoverer, the German physicist Walter Schottky. 9. Why Schottky barrier is formed? When a metal is put in direct contact with a semiconductor, a so called Schottky barrier can be formed, leading to a rectifying behavior of the electrical contact. 10. What is the barrier potential of Schottky diode? The forward voltage drop ranges from 0.3 volts to 0.5 volts. The barrier of forward voltage drop is made of silicon. The forward voltage drop is proportional to the doping concentration of N type semiconductor. Due to high concentration of current carriers, the V-I characteristic of Schottky diode is steeper.

The diode and the negative end of the power supply are connected in series to monitor the current, and the fixed range digital multimeter (DMM) is used to detect the current. This simple design example can realize the current monitoring from a number of μA to 100mA in a single range. This design example has proved to be very useful and simple. Only 3 to 4 modules are needed to monitor the current from the μA over to 100mA in a single range.   Home Energy Monitor Project: Current   As defined by the diode formula IF≅I0 × exp (eVF/kT), the voltage on the diode increases with the logarithmic current flowing through it. Where IF is a forward current, IO is a reverse saturation current, the charge is (1.602 × 10 ~ (-19) C) V _ F is a forward voltage T is the temperature (K), k is the Boltzmann constant (1.380 × 10 ~ (-23) J/K). Depending on the purpose, the following formulas can be extracted: VF∝logIF（temperature fixed）       Catalog   I Shunt Diode II Adding Extra Diodes III. LTspice IV Conclusion FAQ     I Shunt Diode Now let ' s look at a diode with a measuring instrument . When the current is low , it indicates the milliampere ( mA ) level current that flows through the meter rather than the diode; while in a large current it displays the voltage on the diode, and the logarithm of the current thus derived ( imagining the diode as a self-adjusting shunt ) . Therefore the bottom of the meter scale is therefore quite linear and the top has enough logarithmic properties and the middle is a transition phase , so the entire range is very useful. As shown in Fig.1, using a Schottky rectifier, a 100μA/1.7kΩ meter and an appropriate series resistor can monitor the current from 10 μA to over 100mA within a single range, and the indicated speed is limited to the pendulum speed of the meter. Fig. 1 Schottky rectifier, 100 μ A / 1.7 kΩ meter and suitable series resistance This simple circuit often has more problems than the number of components, in addition to the high-precision calibration process, the circuit also has two main drawbacks: series voltage drop and temperature stability. The diode voltage drop is as high as 400mV, so it is best to use a new or charged battery when monitoring, otherwise your measured components may show that the battery is low. Or treat the circuit as a convenient low-voltage test circuit that might add a short-circuit switch.   II Adding Extra Diodes At the bottom of the scale, almost all current flows through the instrument, which is limited by the machine and magnetic temperature coefficients, and the measured temperature coefficient is very low. But at large currents, a voltage drop can be seen on the diode, which will drop at a rate of about 2mV/K, as predicted by the diode formula. This not only affects the slope of low of logarithm, but also affects the transition point from linear to logarithmic. In addition, the meter windings account for a large part of the total series resistance, and the TCR of copper at room temperature is 3930 ppm/kg. Fig.2 shows the relation curves of deviation and current of 1N5817 at 0℃, 25℃ and 50℃. These curves take into account the TCR of the measuring circuit and the temperature coefficient of the diode, but ignore the self-heating effect of the latter, but there is no problem at relatively stable temperature. Fig. 2 Deviation and current curve Self-heating mainly exists in D1 will have no impact on current. Suppose the current flowing through is 100mA, the voltage drop D1 is 400mV—that's 40mW. According to the manual, the basic thermal resistance of a D0-41 1N5815 with a slightly longer pin and a large amount of radiating copper is 50 K/W. When these data are taken into account, the temperature rise of the node is only 2℃ at 100mA, which is equivalent to the reduction of VF by about 4mV, or the error of about 1% at full scale. Try to keep the diode to a short pin and high thermal quality, noting that there may be high transient currents during conduction, as these can lead to errors until the temperature of the node cools again. Fig. 3 An improved version of the offset temperature coefficient Fig. 4 The bias and current curve after adding a diode Fig. 4 shows the curve of the circuit. Note that most of the curve is now in logarithmic form, and that extra diode effectively suppresses the initial linear region. However, the selection of this diode is critical because the forward voltage of D2 should be slightly lower than that of D1, but other features should match.   III LTspice D1 using 10MQ060N and D2 using BAT54—this is the first pair of components emulated. Both are cheap, modeled by LTspice and are therefore recommended components. A pair of 10MQ060N works almost consistently (but a pair of BAT54 is inconsistent). In most of the time, this group combines with other components showing worse temperature variations and strange indications, so it is necessary to  model the circuit before building it. If the sensitivity and resistance of the instrument are appropriate, R1 can be omitted. On the same thermal properties, the D1 and D2 can track mutual temperature changes. Silicon P-N junction diodes generally have a very straight (log IF) / VF relation, while Schottky's straight line is not. This is because their structures have higher series resistance, are more closed to linear than logarithmic at very low currents, and have protection loops to control the potential gradient of P-N diodes that are parallel to Schottky nodes. Therefore, in practice, the exact logarithmic law will change with the current and the type of component. Although a used diode may be fine for the first pair, due to the inevitable inaccuracy of the circuit, the double diode design still needs to be carefully selected. Schottky diodes can provide more reference resources. 100 μ A /1700 Ω indicators, which are very common, very tightly connected, very useful, and their linear and structure are well consistent with units, just match the 35mm × 14mm aperture, so select them. The calibration points used in Fig.5 are generated by arranging a series of combinations of monitors, batteries, fixed and variable resistors, and the DMM series. Existing test scales are marked at the appropriate points and then removed and scanned, which are used as templates for the final layout.  The simulation results are used to generate the reference point in Fig.5 (left), and the results well reflect the actual operation, although the multimeter is poor. These scales can save time, but are not as accurate as they are newly made (obviously these measuring structures need different scales), and R1 can be calibrated slightly (the instrument is set at ±20%). Both scales consider the non-linearity of the instrument structure. Fig.5 The calibration point (right) of the monitor, battery, fixed and variable resistor, and DMM combination IV Conclusion Whatever, now that these circuits are embedded in most of my development projects and even in production testing devices, they are effective in finding a variety of faults and problems, from power lines short-circuiting to the pull-up pins of miscoding. In order to facilitate the monitoring of the current, it is necessary to connect the appropriate diode with the negative end of the power supply and monitor its forward voltage drop. After some simple calibration, you can monitor the supply current in full sync with the other parameters you want to detect.   FAQ   1. What is a shunt diode? In electronics, a shunt is a device that creates a low-resistance path for electric current, to allow it to pass around another point in the circuit. ... The origin of the term is in the verb 'to shunt' meaning to turn away or follow a different path.   2. What is shunt and its uses? shunt is a device which allows electric current to pass around another point in the circuit by creating a low resistance path. A shunt (aka a current shunt resistor or an ammeter shunt) is a high precision resistor which can be used to measure the current flowing through a circuit.   3. How does a shunt diode work? The shunt regulator operates by maintaining a constant voltage across its terminals and it takes up the surplus current to maintain the voltage across the load. One of the most common examples of the shunt regulator is the simple Zener diode circuit where the Zener diode acts as the shunt element.   4. What are the disadvantages of shunts? a. It has poor efficiency for large load currents. b. It has high output impedance. c. The output DC voltage is not absolutely constant because both VBB and VZ voltages decrease with increase in room temperature.   5. Where is shunt used? The shunt is used in the galvanometer for measuring the large current. It is connected in parallel to the circuit of the galvanometer. The galvanometer is the current sensing devices. The direction of flow of current inside the circuit is determined by the pointer of the galvanometer.   6. Why shunt is always connected in parallel? A shunt resistance should be connected in parallel to the galvanometer so as to keep its resistance low. Such low resistance galvanometer ( ammeter) is used in series with the circuit to measure the strength of current through the circuit.   7.How is shunt current calculated? How to Calculate a Shunt: a. Write down the Ohm's law expression of "V = I * R" where "V" is the voltage drop across shunt resistor, "I" is the current flowing through shunt and "R" is the shunt resistance. b. Substitute value of voltage "V" and current "I" in the Ohm's law expression.   8. What size shunt do I need for battery monitor? A 100 amp shunt would be plenty if you are only using 12v devices like water pump, furnace blower and lights. We have an inverter and pass up to 200 amps sometimes. The shunt that came with our monitor is good for 500 amps. It doesn't hurt to have a shunt larger than you need.   9. Why shunt is used in galvanometer? Since galvanometer is a very sensitive instrument that it can not measure the heavy currents . to do so A shunt is connected with parallel with galvanometer to convert it into ammeter. ... so after that it can measure heavy currents in the circuit.   10. Is a shunt a resistor? A shunt is a low-ohm resistor that can be used to measure current. Shunts are always employed when the measured current exceeds the range of the measuring device.