New Breakthrough: Materials Defy Corrosion by CO2 and H2S!

Share on social networks
Inspenet-Selección de materiales

Table of Contents

Author: Carlos Álvarez, September 17, 2023.

Introduction

Corrosion is a pervasive problem in industry, especially when it comes to materials used in aggressive environments. Among the most common corrosive agents are carbon dioxide (CO 2 ) and hydrogen sulfide (H 2 S), which can cause damage to pipes, tanks and equipment. However, in recent decades, there have been significant advances in the development of materials resistant to this type of corrosion, which has revolutionized the way industries address this challenge.

In this article, we will explore the latest advances in the search for materials that can resist corrosion in the presence of CO 2 and H 2 S, and how these advances are impacting various industrial applications.

The threat of corrosion

Before delving into advances in corrosion-resistant materials, it is important to understand the threat posed by CO 2 and H 2 S 1 . Both gases are highly corrosive and can cause significant damage in a variety of industrial environments.

Carbon dioxide (CO 2 ) is found in many industrial applications, from oil and gas production to power generation. When this substance comes into contact with metals such as steel, it can form carbonic acid, which leads to corrosion. This process can be especially destructive in oil and gas production equipment and piping systems, at high pressures and temperatures.

On the other hand, hydrogen sulfide (H 2 S) is an extremely toxic and corrosive gas commonly found in the oil and gas industry. This gas can react with metals to form metal sulfides, which are highly corrosive and can weaken metal structures over time. This is especially dangerous in oil and gas processing facilities, where it is present in large quantities.

Advances in the selection of corrosion-resistant materials

The fight against corrosion by CO 2 and H 2 S has led to intense research and development work in search of resistant materials 2 . One of the most notable advances has been the improvement in the selection of suitable materials to resist these degrading compounds. Some of the most common materials used in the industry include:

1. Duplex Stainless Steel:

Duplex stainless steel is an alloy that combines the properties of stainless steel and carbon steel. This makes it highly resistant to corrosion, making it an option in offshore applications and in the chemical industry. The key to its resistance is its balanced chemical composition and dual microstructure.

2. Nickel and Nickel alloys:

Nickel and nickel alloys are known for their excellent corrosion resistance in aggressive environments. These materials are widely used in the chemical industry and in the production of sulfuric acid, where H 2 S and other corrosives are common.

3. Glass fiber reinforced polymers:

In some applications, glass fiber reinforced polymers have proven to be an effective solution to resist corrosion. These materials are lightweight, strong, and can withstand highly corrosive environments, such as the chemical industry and mining.

4. Coatings and special coatings:

In addition to base materials, advanced coatings and coatings have been developed that can be applied to metal surfaces to protect them from corrosion. These coatings include epoxies, polyurethanes, and fluorinated polymers, among others.

Innovations in materials engineering

Advances in material selection are only part of the equation. Materials engineering has also played a crucial role in improving corrosion resistance in CO 2 and H 2 S environments. Some of the most notable innovations in this field include:

1. Nanomaterials and nanotechnology:

Nanotechnology has allowed the development of coatings and materials with unique properties. Nanomaterials can be more resistant to corrosion and have greater durability compared to their macro-scale counterparts.

2. Computational modeling and simulation:

The ability to model and simulate the behavior of materials in corrosive environments has improved significantly. This has allowed engineers to predict the useful life of materials and optimize their performance in real-world conditions.

3. Self-healing Materials:

Advances in materials resistant to CO2 and H2S corrosion have a significant impact on several industries. Below are some of the most notable applications:

Applications in industry

Advances in materials resistant to CO2 and H2S corrosion have a significant impact on several industries. Below are some of the most notable applications:

1. Oil and gas industry:

Oil and gas exploration and production often take place in extremely corrosive environments. Corrosion-resistant materials allow for greater durability and safety in equipment and pipes used in this industry.

2. Power generation:

Power plants that use fossil fuels also benefit from these advances, as they can operate more efficiently and with less need for maintenance.

3. Chemical industry:

The chemical industry handles highly corrosive substances, so resistant materials are essential to guarantee the integrity of the facilities and the safety of workers.

4. Marine infrastructure:

Harbors, ships and marine structures constantly face corrosion due to exposure to salt water and humidity. Resistant materials extend the life of these structures.

challenges

Despite significant advances in CO 2 and H 2 S corrosion resistance, there are still challenges to overcome 3 . Some areas of ongoing research include:

1. High temperature resistance:

In high temperature applications, such as the petrochemical industry, corrosion resistance is especially critical. Researchers are working on developing materials that can withstand extreme conditions without degradation.

2. More affordable materials:

Some of the corrosion resistant materials can be expensive to produce. The search for more affordable alternatives is an important goal to make these solutions accessible to a broader range of industries.

3. Sustainability:

Sustainability is a growing concern in the industry, and the production and disposal of corrosive materials can have a significant environmental impact. More sustainable corrosion-resistant materials and recycling methods are being investigated.

Conclusions

Proper material selection plays a critical role in controlling corrosion caused by gases such as CO 2 and H 2 S in industrial environments. The choice of corrosion-resistant materials is essential to guarantee the integrity and useful life of equipment and structures exposed to these aggressive environments.

Combining careful material selection with proper monitoring and maintenance strategies can help prevent costly failures and safety risks. As research continues and challenges are overcome, progress in this field is likely, allowing industries to operate more safely and efficiently in corrosive environments.

Bibliographic references

  1. CANDELA ROCÍO BARBISAN. What is CO₂ Corrosion and how is it defined?; Consulted on September 14, 2023; https://www.definicionabc.com/ciencia/corrosion-co2.php
  2. . ÁNGEL SO, BENJAMÍN VALDÉZ SALAS, MICHAEL SCHORR WIENER, MÓNICA CARRILLO BELTRÁN, ROGELIO RAMOS IRIGOYEN, MARIO CURIEL ALVAREZ. Materials and corrosion in the natural gas industry; Consulted on September 14, 2023; https://www.omniascience.com/books/index.php/monographs/catalog/download/70/269/372-1?inline=1
  3. TERESA PEREZ. Corrosion in the Oil and Gas Industry: A Growing Challenge for Materials; Consulted on September 15, 2023; https://www.iapg.org.ar/congresos/2014/integridad/trabajos/Sala1/3.Jueves/17.00a17.30/integridad.pdf

Share this article in your social network
Rate this post
1 star2 stars3 stars4 stars5 stars (No rating yet)
Post Rating LoaderLoading...
Recent News