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Keywords: lightning, integrated circuits, electrical overstress, EOS, electrostatic discharge, ESD, reliability, spark, triboelectric voltage, short rise time, HBM, human body model, Schottky diodes, Zener diode, transient suppression, TVS, MOV Related Parts
APPLICATION NOTE 4491
Damage from a Lightning Bolt or a Spark—It Depends on How Tall You Are!
Bill Laumeister, Strategic Applications Engineer
Sep 12, 2012
Abstract: Large steel buildings, automobiles, mountains, even people survive real atmospheric lightning. Humans can also create their own miniature lightning bolts (sparks) and survive. When those sparks reach an IC, however, major trouble results. In this tutorial, we will discuss ways to protect printed circuit boards (PCBs) against ESD destruction. We will show that analog parts with bigger geometries are the best to use to protect a field-programmable gate array (FPGA) with their small geometries. By taking these measures, the ICs in an FPGA remain more reliable and deliver consistent quality performance.
Lightning can be fun and entertaining, or dangerous and destructive. Maybe all these things at once—it just depends on where you are, what you are doing, and your height. For an IC, lightning is never good.
A few years ago we were in a 10-story, steel-frame hotel building. An afternoon lightning storm approached across a large open field. Because of the building's steel frame, we felt comfortably safe. Our computers were not plugged in, so that was no concern. It was a spectacular show for about 10 minutes as the storm passed.
Large steel buildings, automobiles, mountains, even people survive real atmospheric lightning. Humans can also create their own miniature lightning bolts (sparks) and survive. When those sparks reach an IC, however, major trouble results. Nanometer-tall transistors need protection to survive even human sparks. In this tutorial, we will discuss ways to protect printed circuit boards (PCBs) against ESD destruction. We will show that analog parts with bigger geometries are the best to use to protect a field-programmable gate array (FPGA) with their small geometries. By taking these measures, the ICs in an FPGA remain more reliable and deliver consistent quality performance.
A Spark from Two Perspectives
Where do human-generated sparks come from? They are caused by a triboelectric charge. That is a big word. This happens when two materials come into contact (rubbing helps) and are then separated. Some electrons will transfer to one of the items. How many electrons move and to which surface depends on the material's composition. This is a common phenomenon because almost all materials, insulators, and conductors exhibit triboelectric properties. We are familiar with many common sources. Petting the cat's fur, rubbing a balloon on one's hair, and walking across a rug can all exhibit the triboelectric effect.
A tutorial on the fundamentals of electrostatic discharge1 illustrates the voltages that humans produce during various activities. Table 1 lists those voltages versus relative humidity (RH).
Table 1. Human Activity and the Static Charge Generated
Typical Voltage Levels
Means of Generation
10% to 25% RH
65% to 90% RH
Walking across a carpet
Walking across vinyl tile
Working at an ungrounded bench
Picking up a polybag from a bench
Sitting in a chair with urethane foam
No wonder it hurts when we walk across a rug and touch a door knob! A general rule is that 5,000V can jump about one centimeter (0.4 inches) in 50% RH air. For someone five- or six-feet tall, this is a spark; it is painful, but we survive. Now change your perspective. What havoc would that spark cause to something a few micro-inches tall, like a transistor in an integrated circuit (IC)? In this situation, a centimeter spark is a massive, frightening, lightning display.
Now, we can turn to ICs. Microprocessors have long led the density improvements of digital semiconductors. Fabrication technology has resulted in smaller and smaller transistors. In 1971, the Intel® 4004 computer processing unit (CPU) was introduced in a 10µm geometry. In the 1980s and 1990s, the process made parts smaller than a bacterium. In 2012, ICs are approaching densities 1,000 times smaller than the 1971 technology and the features on the chip are smaller than a virus. In 2012 one can buy FPGAs with 28nm features and 6.8 billion transistors in one package2 and the future promises to double that density in the next few years. The small transistors are closely packed together and need to operate on low voltages (typically 1V and below) to control the heat generated.
To put 28nm in perspective, note the zeros: it is 28 billionths of a meter (0.000000028). Let the distance between San Francisco and New York City represent one meter (about 4000 kilometers or 2500 miles). Now 28nm (one part in 36 million) is 0.11 meters or 4.4 inches. How big must a lightning bolt be to damage such small geometry devices and how does one protect such necessary and useful FPGAs?
The easy answer is to use the very I/O interface devices that bridge the digital and analog worlds. Analog mixed-signal ICs are made in comparatively large geometries (10 to 100 times larger than digital) and with higher voltage (typically 20V to 80V and higher), which makes them more robust than the tiny digital transistors. Though today's analog mixed-signal devices are generally tolerant of ESD, they do benefit from discrete ESD devices.3
Understanding the Damage from a Spark
Semiconductor manufacturers take electrical overstress (EOS) and electrostatic discharge (ESD) very seriously. First, for the obvious reason, that EOS and ESD can destroy parts during fabrication, package assembly, and test. But more importantly, these negative forces directly impact the quality and lifetime of the circuit in the customer's hands.
At first a part that is electrically overstressed may appear to function properly. It might even function in a slightly degraded manner but still pass the automatic test equipment's (ATE) examination, only to fail later in the field. EOS and ESD failures are preventable and are, without doubt, critical quality-control issues.
Building an IC in manufacturing is the first place where EOS and ESD damage can occur. Figure 1A shows a schematic diagram of the PCB. We might think that the IC is protected by the series capacitor. This is not the case. The second opportunity for damage is when the customer mounts the IC on a PCB to build a product. Looking closer at Figure 1B we see that the capacitor has a 50V working voltage, but the distance between the two metallic end connections is only 0.28 inches (7mm). Since the spark just jumped 0.4 inches (1cm), the small gap around the capacitor is easily compromised. The result may be that the IC pays with its life (Figure 1C). Finally, the EOS or ESD damage can occur when the customer operates the product in their environment.
Figure 1. Sources of board-level EOS and ESD problems.
There certainly are many opportunities for considerable damage. We can actually see the result of EOS and ESD destruction inside an IC. To do this, the package epoxy material must be removed. This is usually done with hot acids in a double-glove isolation box. This process is incredibly dangerous. The fumes are deadly. One breath will cause a painful death; one drop of acid on human skin would result in, at best, the amputation of a hand or arm, or at worst death.
Microphotograph Figure 2A shows no apparent damage. The bond wire and pad labeled REF is provided so we can orient ourselves and compare photos. The liquid crystal material is painted on the die (pink color) and is similar to the liquid crystal used in mood rings and children's forehead thermometers. It changes color with small changes in temperature. When power is applied to the IC, the area drawing excess current, marked here with a yellow box, heats and changes color. It is a hot spot. This is interesting, but what caused the problem?
Figure 2A. A circuit in visible light shows no apparent damage from EOS or ESD. The liquid crystal area (marked in yellow) of the circuit is damaged by heat.
The REF bond wire (Figure 2B) indicates that this image is rotated 45 degrees. As we progressively zoom in, we see electromigration. The EOS has caused a short circuit as the damage grew under the influence of the electrical stress. This process can happen over time and progress during many short stresses until, suddenly, the part fails.
Figure 2B. Scanning electron microscope photos of the circuit in Figure 2A.
For comparison, now we examine another IC where a lightning bolt caused quick destruction (Figure 3).
Figure 3. A circuit (left) under visible light shows no apparent damage from the lightning bolt. The same circuit (right) under a microscope shows a hot spot with damage.
The "7" in the upper left corner of each image in Figure 3 is for orientation. There is not much to see under visible light, but under magnification the liquid crystal shows the temperature rise and resulting EOS.
Figure 4 plots the data from the circuit in Figure 3 and we see that the known good part exhibits a clean, repeatable plot. The current increases in the vertical axis with 4.5V applied. When the current approaches 250µA, a knee is formed; as the voltage increases, the current stays at 250µA. Figure 4 also shows that the defective part continues to draw more current above the knee.
Figure 4. Semiconductor curve tracer plots for the circuit in Figure 3. Curve tracer current/div.is 50µA; voltage/div. is 1V.
Under closer scrutiny, part serial number 1 (SN1) shows a hole in the gate oxide (Figure 5). The lightning bolt shorted the gate to the substrate, causing excess current to flow. Of course, the transistor paid with its life. Typical gate oxide is 5nm to 15nm in thickness, depending on the fabrication process. In dense digital microprocessor parts, the oxide may be 1.2nm to 3nm thick. To illustrate how thin that is, in silicon 1.2nm is ~5 or 6 atoms thick. Thus, to a gate that is a few nanometers tall, almost any spark is a giant lightning bolt.
Figure 5. Scanning electron microscope photos of the circuit in Figure 3. The lightning bolt caused a hole in the gate oxide, which shorted the circuit.
Combat the Spark and Protect the Circuit
We will quickly discuss how to protect the ICs and the PCB from a spark and EOS/ESD.
The risetime of a spark is very fast, so any way that we can slow it down will reduce the peak voltage. ESD structures (Figures 6 and 7) are typically used in two places in a system: at the board level inputs and outputs with series resistors; and inductors along with capacitors to ground that can act as a lowpass filter. PCBs are thus protected from EOS/ESD by a combination of discrete silicon (small signal or reference) Schottky diodes, avalanche (Zener) diodes, transient voltage suppression (TVS) diodes, gas-tube discharge devices, resistors, inductors, and metal oxide varistors (MOVs).
Figure 6. An inventory of suggested discrete components which can protect against unwanted electrical vulnerabilities.
Figure 7. Simplified ESD structures.
The ESD structures of Figure 7A through C are internal to the ICs. External discrete components used for EOS/ESD protection tend to be physically larger and carry larger currents. In addition to the ESD protection built into many products, specialized ESD protection devices like the MAX14541 and MAX3203 are available to designers.
It is important to note that many circuits have built-in EOS/ESD protection, even though that is not their primary function. Consider for a moment the MAX5481 family of 10-bit nonvolatile (NV) potentiometers, the MAX5134 quad 16-bit DAC, and the MAX6001 family of low-power, low-cost voltage references. A close look at the data sheets shows that ESD is not mentioned. But the ESD specification depends on the IC fabrication process and is stated on the reliability reports for each part. You can find the ESD information by starting at the QuickView page for each part on Maxim's website. Near the bottom of the page is the technical documents area and the reliability report.4 A click here brings up the reliability report page. If the reliability report is not online, it can be requested.
Whether large or small, steel buildings, automobiles, mountains, and even people survive real atmospheric lightning. Five- to six-foot tall humans can, and regularly do, create their own miniature lightning bolts (sparks) and barely even notice. That is never the case with nanometer-tall transistors. They need protection to survive even human sparks. As we have seen, protection against EOS and ESD destruction of the board circuits and ICs is critical for reliable, quality product performance. Circuit designers should be vigilant to employ EOS/ESD protection circuitry in their designs or to ensure that they are using circuits with built-in ESD protection from the outset. It is a serious oversight to ignore any seemingly trivial spark...no matter how tall you are...or are not.
Reliability Report for MAX5134AGTG+3, "Item C.) E.S.D. and Latch-Up Testing; The DB34 die type has been found to have all pins able to withstand a HBM transient pulse of +/-1500 V per JEDEC JESD22-A114-D." For the complete report, go to www.maximintegrated.com/reliability/product/MAX5134A.pdf.
Reliability Report for MAX6001EUR+4 (MAX6002, MAX6003, MAX6004). "Item C.) E.S.D. and Latch-Up Testing; The RF23-6 die type has been found to have all pins able to withstand a HBM transient pulse of 2500 V." For the complete report, go to www.maximintegrated.com/reliability/product/MAX6001.pdf.
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