What is Wet Etching? A Comprehensive Guide to the Etching Process

Wet etching is a widely used technique in microfabrication and semiconductor manufacturing. This process involves the use of liquid chemicals to remove material from a substrate, typically metals, semiconductors, or other materials used in electronic devices. Wet etching is crucial in creating precise features, patterns, and structures on surfaces, which are essential for a wide range of applications, from microelectronics to MEMS (Micro-Electromechanical Systems).

In this article, we will explain what wet etching is, how it works, its advantages and disadvantages, and common applications of the process. Additionally, we'll cover why wet etching is still an essential part of modern manufacturing despite the rise of alternative etching methods like dry etching.

What is Wet Etching?

Wet etching is a chemical process used to etch or engrave patterns on a substrate by using liquid chemicals (known as etchants). The etchant chemically reacts with the material on the surface of the substrate to remove layers of the material, exposing the underlying structure or creating desired features.

The substrate could be a semiconductor wafer, metal surface, or dielectric material. The process typically requires the substrate to be immersed in or sprayed with the etching solution, allowing the chemicals to interact with the material and selectively remove it.

How Does Wet Etching Work?

The wet etching process follows these general steps:

  1. Preparation of the Substrate: Before etching begins, the substrate must be cleaned to remove contaminants or residues that might interfere with the etching process.

  2. Application of the Etchant: The substrate is then immersed in or sprayed with a liquid etchant. The etchant solution consists of chemicals that are reactive with the material on the substrate. For example, an acid-based etchant like sulfuric acid (H₂SO₄) may be used to etch silicon.

  3. Chemical Reaction: The etchant chemically reacts with the material on the substrate, breaking down and dissolving the material. This reaction is selective and targets specific areas or layers of the material, depending on the etchant's composition and the material being etched.

  4. Rinsing and Drying: Once the desired etching is completed, the substrate is thoroughly rinsed with water to remove any residual etchant. The substrate is then dried, usually with nitrogen gas or other drying methods.

Types of Wet Etching

Wet etching can be classified into two main types: isotropic etching and anisotropic etching.

  • Isotropic Etching: In isotropic etching, the material is removed uniformly in all directions. This type of etching tends to create rounded, non-vertical sidewalls and is less precise for creating fine features.

  • Anisotropic Etching: Anisotropic etching, on the other hand, etches the material in specific directions, usually vertically. This process results in well-defined, sharp sidewalls, which are crucial for applications that require precise etching of fine features.

Advantages of Wet Etching

Wet etching offers several advantages, including:

  1. Cost-Effective: Wet etching is generally less expensive than other etching techniques like dry etching. The equipment required is simpler, and the chemicals are often less costly.

  2. High Selectivity: Wet etching can achieve high selectivity between different materials, making it an effective technique for etching complex structures.

  3. Uniform Etching: For large-area etching, wet etching can provide more uniform results compared to some other methods, especially when the substrate is fully immersed in the etching solution.

  4. Simplicity: The wet etching process is relatively simple to execute, requiring less complex equipment than dry etching techniques like plasma etching.

Disadvantages of Wet Etching

While wet etching has many benefits, it also comes with a few limitations:

  1. Limited Precision: Wet etching is often isotropic, which means it can etch uniformly in all directions, limiting the precision and ability to create very fine features or sharp sidewalls.

  2. Environmental and Safety Concerns: The use of strong acids or other toxic chemicals in wet etching can create environmental and safety risks. Proper handling, disposal, and ventilation are necessary to mitigate these risks.

  3. Etching Damage: Because the etchant is liquid, there is a risk of unintended damage to the substrate, especially if the etching process is not carefully controlled.

  4. Slow Processing Time: Compared to dry etching, wet etching may take longer to achieve the desired results, especially when etching thick or hard-to-remove layers.

Common Applications of Wet Etching

Wet etching is used in various industries and applications, including:

  • Semiconductor Manufacturing: Wet etching is essential for patterning and etching silicon wafers during semiconductor device fabrication. It's used to define features such as transistors, capacitors, and interconnects.

  • MEMS Fabrication: Wet etching is used in the fabrication of MEMS devices, such as sensors, actuators, and microstructures. These devices require precise etching to create small, complex structures.

  • Printed Circuit Boards (PCBs): Wet etching is used to remove unwanted copper from PCB surfaces, creating the necessary electrical paths and traces for the circuit.

  • Surface Cleaning: Wet etching can also be used to clean and prepare surfaces by removing oxides, contaminants, or unwanted materials before further processing.

Conclusion

Wet etching is a vital technique in many industries, from semiconductor manufacturing to MEMS fabrication. Its simplicity, cost-effectiveness, and high selectivity make it an attractive option for certain types of etching, especially when fine precision is not required. However, its limitations, such as lower resolution and potential environmental concerns, mean that it is often used in conjunction with other etching methods, like dry etching, to achieve the desired results.

Whether you're involved in semiconductor manufacturing, PCB fabrication, or MEMS design, understanding wet etching and its applications will help you select the right etching process for your needs.

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The chemical etching process

material preparation
1. material cut
2. Material Clean
5. Developing
6. Etching
3. Lamination
4. Image Printing
7. Deinking
8. Stripping & Inspection

Etched stainless steel components

Chemical etching offers a number of benefits for product applications that require economical complexity and stress and burr-free features, all delivered in short lead times.

Etching does not alter the surface finish of stainless steel and is specified for premium automotive interior trim applications, including speaker grilles, tread plates, badges and inlays.

Safety-critical springs and flexures used in satellites, ABS braking, biosensors and fuel injection can now flex millions of times because stainless steel etching does not alter the fatigue strength, recoil and flatness of spring steels.

Complex, corrosion-resistant micro-filters used in showerheads and insect meshes can be manufactured in economical production volumes, as etching only charges for the first hole.

Car speaker grilles
tread plates
BIPOLAR PLATE
micro filters
automotive interior trim
Coffee Filter
insect meshes
Hair Dryer Filter

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Automotive Industry
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Chemical etching process: 10 frequently asked questions

Want to ask a question about chemical etching or share a component drawing for technical review?


Q1. What is the chemical etching process?
The chemical etching process is a sheet metal machining process that is used to manufacture complex components with high levels of accuracy.Comprising nine steps, it works by printing the component design onto a photoresist mask which is laminated onto the metal.
The areas of photoresist which have not been printed are developed, exposing the metal, which is subsequently etched away.
Q2. What metals can be chemically etched?
Almost any metal and metal alloy can undergo chemical etching. This includes steel and stainless steels, nickel, copper, aluminium.
What makes photochemical etching so effective is that it works well on hard-to-machine metals, including highly corrosive-resistant metals such as titanium and its alloys.
Q3. What chemical is used in etching?
Most metals are etched using ferric chloride, a safe to use, recyclable etchant. Ferric chloride can be regenerated and reused.
Other proprietary etchants such as nitric acid, are used for specialist metals and alloys.
Q4. What sheet sizes and thicknesses can be etched?
Sheet metals between 0.010mm and 1.5 mm thick can be etched. The thicker the sheet the longer it takes to etch, meaning metals above 1.5mm are uneconomical to process.
Q5. How accurate is chemical etching?
Excellent accuracy can be achieved with photochemical etching. Standard minimum etching tolerances are ±10% of the metal thickness being etched, to a minimum of ±0.025 mm.
With development, greater accuracy can be achieved so it is encouraged that customers partner with TONGJIN Etching early in the design phase so an appropriate etching method can be developed.
Q6. What are the benefits of chemical etching?
Chemical etching is highly advantageous and offers many benefits. This process does not use mechanical force, unlike stamping which subjects sheet metals to extreme pressures. Nor does it put thermal stress on the cutting edge, unlike laser cutting.
Alongside this, chemically etched parts remain flat, burr- and stress-free, leaving the material properties unaffected.
Chemical etching can also produce very accurate engraved features at the same time the material is being profiled, such as fluidic channels, logos or part numbers. These features come at no additional cost.
Q7: What level of detail can chemical etching achieve?
The minimum standard etched opening achievable is 0.1 mm, but with development, etching can achieve even finer features.
Q8. How much does chemical etching cost?
Chemical etching uses digital tooling which is inexpensive, very easy to adapt and does not wear out, unlike presswork tooling.
Material thickness and component size are key cost drivers as you pay by the sheet, not by the part – the more parts per sheet, the lower the unit price. Thicker sheets take longer to etch and this is reflected in the cost of the component.
Q9. What are the maximum quantities chemical etching can produce?
There is no maximum quantity that chemical etching can produce.  Low-cost digital tooling ensures prototype quantities can be supplied quickly and economically.
As one of the largest sheet metal etching companies in the world, TONGJIN Etching supplies its customers with component quantities measured in the millions.
Q10. How long does chemical etching take?     
Chemical etching lead times are measured in days, not weeks or months, unlike traditional metal machining technologies.
Subject to quantities required and capacity, standard components which require no additional post-processing can be supplied in less than two working weeks. Urgent demands can be supplied even quicker.

Customer Reviews

I am extremely impressed with the precision...
Swapnil from United StatesWednesday, Jan 26, 2019
"I am extremely impressed with the precision and quality of the chemical etching performed by your team. The intricate designs on our metal components were etched flawlessly, exceeding our expectations. Thank you for delivering such a high-quality product."
Your chemical etching service has significantly improved the durability...
Sarah from United KingdomWednesday, Jan 20, 2020
"Your chemical etching service has significantly improved the durability and functionality of our products. The etched patterns not only enhance the aesthetics but also provide excellent grip and tactile feel. Our customers are thrilled with the results, and we couldn't be happier with your exceptional craftsmanship."
We have been relying on your chemical etching expertise for several projects...
Eduardo from ItalyWednesday, Mar 16, 2022
"We have been relying on your chemical etching expertise for several projects, and each time, you have consistently delivered outstanding results. Your attention to detail, quick turnaround time, and excellent customer service make you our preferred choice. Your commitment to excellence is commendable."
has given our brand a unique edge in the market...
Taner from TurkeyFriday, April 26, 2023
"The chemical etching performed by your team has given our brand a unique edge in the market. The intricate logos and designs etched onto our products have attracted significant attention and set us apart from our competitors. We appreciate your professionalism and skill."

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