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How we make our memory

Ever wondered how memory is manufactured? Here’s a behind-the-scenes look at the rigorous process we undertake to manufacture memory and ensure that you get a high-quality product.

Part I: From silicon to finished wafer

Memory chips are integrated circuits with various transistors, resistors, and capacitors that must be formed on each and every chip. These integrated circuits begin as silicon, which is usually extracted from sand. Turning silicon into memory chips is an exacting, meticulous procedure involving engineers, metallurgists, chemists and physicists.

Memory is produced in a large facility called a fab, which contains many clean room environments. Semiconductor memory chips are manufactured in clean rooms because the circuitry is so small that even tiny bits of dust can damage it. Micron's main facility in Boise covers over 1.8 million square feet and has class 1 and class 10 clean rooms. In a class 1 clean room, there is no more than 1 particle of dust in a cubic foot of air. In comparison, a clean, modern hospital has about 10,000 dust particles per cubic foot of air. The air inside a clean room is filtered and circulated continuously. Production team members wear special caps, gowns, and masks that help keep the air particle-free.

Step 1: Silicon ingots

The first step from silicon to integrated circuit is the creation of a pure, single-crystal cylinder, or ingot, that is made of silicon and that measures six to eight inches in diameter. Once formed, silicon ingots are sliced into thin, highly polished wafers that are either six or twelve inches in diameter and less than 0.025 inches thick. The circuit elements of the chip (transistors, resistors, and capacitors) are then constructed in layers on the silicon wafer. Circuits are developed, tested by simulation, and perfected on computer systems before they are actually built. When the design is complete, glass photomasks are made—one mask for each layer of the circuit. Photomasks are opaque plates with holes or transparencies that allow light to shine through in a defined pattern, and these masks are essential to the next step in the manufacturing process: photolithography.

Step 2: Photolithography

In the sterile clean room environment, wafers are exposed to a multi-step photolithography process which is repeated once for each mask required by the circuit. Masks are used (a) to define the different parts of a transistor, capacitor, resistor, or connector that will complete the integrated circuit, and (b) to define the circuitry pattern for each layer on which the device is fabricated.

At the beginning of the production process, bare silicon wafers are covered with a thin layer of glass, followed by a nitride layer. The glass layer is formed by exposing the silicon wafer to oxygen at temperatures of 900 degrees Celsius for an hour or more, depending on how thick the layer needs to be. Glass (silicon dioxide) is formed when the silicon material in the wafer is exposed to oxygen. At high temperatures, this chemical reaction (called oxidation) occurs at a very fast rate.

Step 3: Photoresist

Next, the wafer is uniformly coated with a thick, light-sensitive liquid called photoresist. Portions of the wafer are selected for exposure by carefully aligning a mask between an ultraviolet light source and the wafer. In the transparent areas of the mask, light passes through and exposes the photoresist.

When exposed to ultraviolet light, photoresist undergoes a chemical change, which allows a developer solution to remove exposed photoresist and leave an unexposed portion on the wafer. For each mask required by the circuit, the photolithography/photoresist process is repeated.

Step 4: Etch

In the etch step, wet acid or plasma dry gas is placed on the wafer to remove the portion of nitride layer that is unprotected by hardened photoresist. This leaves a nitride pattern on the wafer in the exact design of the mask. When the hardened photoresist is removed (cleaned) with another chemical, hundreds of memory chips can now be etched onto the wafer.


Part II: Layering the wafer and completing the circuit

In Part I of the manufacturing process, all of the circuit elements (transistors, resistors, and capacitors) were constructed during the initial mask operations. The next steps connect these elements together by creating a set of layers.

Step 5: Aluminum layering

To begin connecting the circuit elements together, an insulating layer of glass (called BPSG) is deposited on the wafer, and a contact mask is used to define the contact points (or windows) of each of the circuit elements. After contact windows are etched, the entire wafer is covered with a thin layer of aluminum in a sputtering chamber. When a metal mask is applied to the aluminum layer, a network of thin metal connections or wires is formed, creating a path for the circuit.

Step 6: Passivation layering

The entire wafer is then covered with an insulating layer of glass and silicon nitride to protect it from contamination during assembly. This protective coating is called the passivation layer. A final mask and passivation etch process follows, removing the passivation material from terminals, which are called bonding pads. The now-free bonding pads are used to electrically connect the die to metal pins on the plastic or ceramic package, and the integrated circuit is now complete.

Before the wafer is sent to die assembly, every integrated circuit on the wafer is tested. Functional and nonfunctional chips are identified and mapped into a computer data file. A diamond saw then cuts the wafer into individual chips. Nonfunctional chips are discarded and the rest are ready to be assembled. These individual chips are referred to as die.

Before die are encapsulated, they are mounted to lead frames where thin gold wires connect the bonding pads on the chip to the frames to create an electrical path between the die and lead fingers.


Part III: Die preparation and testing

In Part II of the manufacturing process, the integrated circuit was created and the finished wafer was cut into dies. The next steps prepare the die for use in finished modules.

Step 7: Encapsulation

During Encapsulation, lead frames are placed onto mold plates and heated. Molten plastic material is pressed around each die to form its individual package. The mold is opened, and the lead frames are pressed out and cleaned.

Step 8: Electroplating

Electroplating is the next process where the encapsulated lead frames are "charged" while submerged in a solution of tin and lead. Here, the tin and lead ions are attracted to the electrically charged lead frame, which creates a plated uniform deposit, increasing the conductivity of the die and providing a clean surface so that the die can be mounted.

Step 9: Trim and form

In trim and form, lead frames are loaded into trim-and-form machines, where leads are formed and the chips are then severed from the frames. Individual chips are then put into antistatic tubes for handling and transportation to the test area for final testing.

Step 10: Burn-in testing

In burn-in testing, every chip is tested to see how it performs under accelerated stress conditions. Burn-in testing is a critical component of module reliability. By testing modules in accelerated stress conditions, we’re able to weed out the few modules in every batch that will fail after minimal use. To conduct burn-in testing, we use industry-leading AMBYX ovens that our engineers developed specifically for burn-in testing. Once memory chips pass burn-in testing, they are inspected, sealed, and ready to be assembled.

Step 11: PCB assembly and construction

Once memory chips are made, they need a way to be connected to your computer’s motherboard. Printed circuit board (PCB) solves this problem by providing a to connect the chips to your system’s motherboard. To accomplish this, chips are mounted to printed circuit board (PCB) and the final product is a finished memory module.

PCBs are built in arrays, or sheets, which are made up of several identical boards. After assembly, the array gets separated into individual modules, similar to how a chocolate bar can be broken into smaller squares. By varying the total number of PCBs in each array based on size, Micron maximizes the number of modules made from a given amount of raw materials.


Part IV: Module assembly

In Part III of the manufacturing process, the die and PCB were prepared for final module assembly. The final steps cover the module assembly process.

Step 12: Screen print

When the module design is perfected and the PCBs produced, memory module assembly begins! Assembly entails an intricate soldering procedure that attaches memory chips to the PCB. This begins with screen printing.

In screen printing, a stencil is used to screen solder paste onto finished PCB. Solder paste is a tacky substance that holds chips in place on the PCB. The use of the stencil ensures that solder paste affixes only where components (chips) will attach. The points of attachment are easy to find, thanks to fiducials, which are marks on the PCB that determine where chips need to be placed.

Once the solder paste has been applied, automated “pick and place” assembly machines scan the fiducials to determine where to place chips on the PCB. Pick and Place machines are programmed to know which chips are placed where, so when a machine picks a chip from a feeder and places it on the PCB, it knows exactly where the chip is at. The chip placement process occurs for all remaining chips and for any other components on the module. Of all the steps in memory manufacturing, this is the fastest: chips are placed on finished PCB in just a few seconds!

Step 13: Soldering and attachment

Next, the assembled chips and boards pass through an oven. The heat melts the solder paste into a liquid. When the solder cools, it solidifies, leaving a permanent bond between the memory chips and the PCB. The surface tension of the molten solder prevents the chips from misaligning during this process.

Once the chips are attached, the array is separated into individual modules. Micron team members visually inspect each module. Many modules also undergo additional inspections using automated X-Ray equipment to ensure that all joints have been soldered properly. All Micron Memory Modules meet IPC-A-610 acceptance criteria - the industry standard recognized worldwide.

Step 14: Post-assembly Quality Testing

Micron then tests and tags the modules. We use custom equipment to automatically test performance and functionality. This eliminates any possibility of an operator mistakenly placing a failed module in a passing location. Certain modules are programmed with an identifying "Dog Tag" that your PC will recognize and read.

Step 15: Shipment

Before being sent out to computer manufacturers and consumers, a statistically significant portion of finished modules are randomly selected for a final quality inspection. Once modules are approved for use, they are placed into ESD-safe plastic trays and bags, and are made ready for delivery. After an extensive manufacturing process, your memory is ready for use. It’s been rigorously tested and approved!



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