Gas Processing Market By Process Type (Separation, Dehydration and Sweetening, Fractionation); By Application (LNG Production, Petrochemical Feedstock Recovery, Industrial Fuel Gas Supply, Gas Reinjection & Enhanced Recovery); By Equipment (Compressors, Heat Exchangers, Gas Treatment Units, Fractionation Towers, Valves & Filters); By End User (Integrated Oil & Gas Companies, Independent Midstream Operators, National Oil Companies, Utilities & Industrial Users); By Geography, Segment Revenue Estimation, Forecast, 2024–2030

Introduction And Strategic Context

The Global Gas Processing Market will witness a steady CAGR of 5.6%, valued at USD 178.3 billion in 2024 and projected to reach USD 246.8 billion by 2030, according to Strategic Market Research.

 

Gas processing refers to the industrial chain of operations that remove impurities and separate valuable hydrocarbons—such as ethane, propane, butane, and natural gasoline—from raw natural gas streams. It forms the bridge between extraction and downstream utilization, converting raw field gas into commercially viable and cleaner fuel streams.

 

Between 2024 and 2030, the market’s strategic relevance is intensifying as global energy systems transition toward lower-carbon fuels. Natural gas, often positioned as a “bridge fuel,” remains central to balancing decarbonization goals with energy security. Gas processing plants play a pivotal role in enabling that transition—especially as demand for liquefied natural gas (LNG) and petrochemical feedstocks continues to rise.

 

Industry dynamics are shifting too. Aging infrastructure in North America and Europe is giving way to modular and low-emission processing facilities, while Asia and the Middle East are leading with mega-scale gas projects tied to export terminals. Operators are modernizing to handle sour and complex gases, reflecting a shift from pure volume optimization to value extraction and environmental compliance.

 

Stakeholders in this market include equipment OEMs, EPC contractors, NGL (natural gas liquids) producers, refinery-integrated operators, and government-owned oil & gas enterprises. Investor interest is also reviving—particularly in cryogenic processing, sulfur recovery units, and carbon capture-integrated facilities that align with net-zero targets.

 

Market Segmentation And Forecast Scope

The gas processing market operates across a wide industrial spectrum — from field-level separation units to massive cryogenic complexes feeding global LNG chains. Its segmentation reflects not just equipment categories but evolving energy priorities across continents. The following breakdown provides a structured lens into how stakeholders navigate technology, application, and geography between 2024 and 2030.

By Type of Process

Gas processing systems can be broadly grouped into three main operational segments: separation, dehydration and sweetening, and fractionation. Separation facilities handle the initial conditioning of raw gas, removing oil, water, and particulates. Dehydration and sweetening units follow, targeting CO2, H2S, and other contaminants that compromise pipeline integrity or product quality. Finally, fractionation units separate natural gas liquids (NGLs) into individual components like ethane, propane, and butane. Among these, fractionation holds the largest market share—around one-third of total investment value in 2024—given its critical role in supplying feedstocks for petrochemicals and LPG production.

Analysts expect advanced cryogenic fractionation systems to see the fastest adoption rate through 2030, driven by efficiency gains, energy recovery integration, and alignment with LNG export expansion.

 

By Application

Gas processing finds applications across multiple industrial domains, each with distinct economics and technology requirements:

• LNG Production – The largest and most capital-intensive segment, encompassing large-scale liquefaction and pre-treatment plants.

• Industrial Fuel Gas Supply – Covers processing for domestic heating, power generation, and small industrial consumers.

• Petrochemical Feedstock Production – Focused on recovering NGLs and methane streams for downstream chemical and plastics manufacturing.

• Gas Reinjection and Enhanced Recovery – Used in upstream fields where processed gas is reinjected to maintain reservoir pressure or improve oil yield.

In 2024, LNG production remains the dominant application, accounting for nearly 40% of global capacity, but the petrochemical feedstock category is growing fastest as emerging markets build integrated gas-chemical hubs.

 

By Equipment

Core processing equipment includes compressors, heat exchangers, gas treatment units, filters, valves, and fractionation towers. Compressors and heat exchangers represent the largest equipment expenditures due to their role in continuous, high-pressure operations. Manufacturers are increasingly embedding automation and predictive analytics into these components. The focus is shifting from hardware to smart equipment that can self-calibrate, reduce downtime, and optimize energy use.

 

By End User

Major end users encompass:

• Integrated Oil & Gas Companies – Own and operate end-to-end processing assets.

• Independent Midstream Operators – Specialize in gas gathering and third-party processing contracts.

• National Oil Companies (NOCs) – Lead large-scale infrastructure projects, especially in the Middle East and Asia.

• Utility and Industrial Users – Procure processed gas for power generation or chemical production.

Integrated companies dominate high-capex segments, while independent midstream firms are expanding in North America through modular and third-party tolling models.

 

By Region

Regional segmentation mirrors both resource availability and infrastructure maturity:

• North America – Mature infrastructure, with heavy investment in upgrading gas processing capacity in shale regions.

• Europe – Smaller but focused on modernization, emissions reduction, and hydrogen integration.

• Asia Pacific – Fastest-growing market led by China, India, and Australia, where LNG expansion and industrial gas use are accelerating.

• Middle East & Africa – Massive processing projects tied to national energy diversification strategies.

• Latin America – Gradual growth, centered on Brazil and Argentina, supported by offshore gas developments.

 

Market Trends And Innovation Landscape

The gas processing industry is quietly undergoing one of its most transformative phases in decades. What was once a static, utility-driven operation is now being reshaped by digitalization, sustainability mandates, and process intensification. The convergence of these factors between 2024 and 2030 is setting a new tone for investment, engineering design, and operational philosophy across global markets.

1. Decarbonization and Low-Emission Process Design

Environmental compliance has become the defining trend. Governments and industry consortia are pushing for methane abatement, carbon capture integration, and flare minimization. Modern plants now incorporate carbon recovery units and low-bleed pneumatic systems to cut emissions at the source. In many new projects, carbon capture utilization and storage (CCUS) is no longer an add-on—it’s being built directly into the front-end engineering design. Operators in the Middle East and Western Europe are piloting gas sweetening units that capture CO2 for downstream reuse in enhanced oil recovery or synthetic fuels.

This shift is not just environmental—it’s economic. Plants that integrate CCUS early are finding it easier to secure financing and long-term offtake agreements with energy transition investors.

 

2. Rise of Modular and Mobile Processing Units

Traditional gas processing plants are capital-heavy and slow to build. In contrast, modular and skid-mounted processing systems are gaining traction, especially in remote and offshore fields. These compact units offer scalability and quicker deployment, often reducing construction time by 30–40%. Companies operating in North American shale plays and African frontier basins are using modular units to monetize stranded gas that would otherwise be flared. The appeal lies in agility—bringing processing closer to the wellhead rather than waiting for centralized infrastructure.

 

3. Digitalization and AI-Driven Optimization

Digital twins, predictive maintenance, and AI-enabled control systems are moving from pilot projects to plant-wide adoption. Automation suppliers are embedding advanced analytics into process control platforms, enabling real-time monitoring of energy consumption, leak detection, and throughput optimization. In high-throughput cryogenic plants, digital control systems are achieving measurable efficiency improvements—sometimes up to 8–10% in energy recovery. This has become a competitive differentiator: efficiency isn’t just about savings, it’s about maintaining uptime and reliability under variable gas compositions.

 

4. Materials and Membrane Advancements

The material science behind gas separation is evolving. Polymeric and ceramic membranes capable of selective CO2, H2S, and nitrogen removal are increasingly viable alternatives to traditional amine systems. They reduce corrosion, water usage, and maintenance cycles. While not yet dominant, membrane-based gas separation is drawing significant R&D funding from European and Japanese firms seeking compact, eco-efficient alternatives to solvent-based systems.

 

5. Integration with Hydrogen and Circular Energy Systems

The global pivot to hydrogen is reshaping gas processing design. Methane reforming, blue hydrogen production, and synthetic gas routes all require robust gas conditioning. Many gas processing operators are rebranding themselves as “low-carbon gas processors,” integrating hydrogen purification and CO2 recovery capabilities into their plants. This integration is strategic: gas processing is becoming the foundation of broader clean-fuel ecosystems, connecting natural gas, hydrogen, and ammonia production under shared infrastructure.

 

6. Advanced Cryogenics and NGL Recovery

Innovation in cryogenic expansion and turbo-expander technology continues to drive incremental efficiency gains. Modern units can achieve higher ethane recovery with lower energy intensity. Hybrid cryogenic-adsorption systems are emerging, especially for small-scale LNG and NGL applications where flexibility and modularity are key.

 

7. Sustainability-Linked Financing and Digital Compliance

A new wave of financing is linking interest rates and project capital costs to emission metrics. Banks and private equity funds now demand transparent data on methane intensity and energy efficiency. This has triggered a surge in demand for automated emissions monitoring systems embedded in gas processing plants. Simply put, environmental performance has become a prerequisite for capital access, not a marketing add-on.

 

Competitive Intelligence And Benchmarking

The gas processing market sits at the intersection of engineering, technology, and energy transition. While it’s historically been dominated by a few global engineering giants, the competitive field is shifting toward integrated solution providers—those that combine hardware, digital platforms, and sustainability features in one package. The next decade will be defined less by sheer plant capacity and more by who can deliver efficiency and environmental performance at scale.

Key Players and Strategic Positioning

Shell Global Solutions
Shell remains one of the few energy companies with both operating and licensing expertise in gas processing. Their proprietary gas treating and sulfur recovery technologies are widely adopted in large-scale LNG and GTL facilities. The company’s focus is now on low-carbon gas processing and integrated CCUS, embedding carbon management into its process design software. Shell’s competitive edge lies in combining operational experience with technology licensing—bridging the gap between design and deployment.

 

Honeywell UOP
Honeywell UOP is one of the most established names in gas processing, particularly in NGL recovery and amine treating systems. Its recent portfolio expansion includes modular gas processing units and digital plant optimization platforms under its “Connected Performance Services.” These tools use predictive analytics to reduce energy intensity and maximize yield. The company’s strength lies in continuous process innovation and field-deployable modular systems suited for both large and small gas assets.

 

Schlumberger (SLB)
Schlumberger’s pivot toward integrated production and midstream services has positioned it as a flexible technology partner. Through its Production Systems division, SLB offers dehydration, gas treatment, and compression technologies optimized for onshore and offshore fields. The company’s approach blends digital twin modeling with compact, skid-mounted processing systems—a trend gaining strong traction in remote basins. Their modular mindset and global project execution capabilities give SLB an advantage in emerging markets where infrastructure is still developing.

 

Linde Engineering
Linde’s engineering division leads in cryogenic gas separation and liquefaction technologies. Its process design for ethane and NGL recovery is considered best-in-class, especially for energy efficiency and low-temperature reliability. Linde is now focusing on carbon capture-ready gas processing and hydrogen co-production systems, integrating its experience from industrial gas plants into oil and gas projects. The company’s clear differentiation is its depth in cryogenics and long-term project partnerships.

 

ExxonMobil Catalysts and Licensing
While ExxonMobil is known primarily as a producer, its licensing division has quietly become a major force in gas treating technologies. The firm’s proprietary amine-based systems and sulfur recovery catalysts are deployed in several mega gas facilities. Recent developments include low-emission solvents designed to meet stricter environmental rules in Europe and Asia. ExxonMobil’s value proposition lies in reliability and chemical depth rather than hardware—it dominates the chemistry side of gas processing.

 

BASF SE
BASF plays a specialized but critical role through its portfolio of gas treatment chemicals, including its OASE line for CO2 and H2S removal. With the rise of carbon capture integration, BASF’s expertise in solvent optimization and process customization has become central to new gas processing designs. BASF’s focus on green chemistry and lifecycle analysis differentiates it in an increasingly sustainability-driven market.

 

Technip Energies
A leader in EPC (Engineering, Procurement, and Construction) for gas processing and LNG, Technip Energies has evolved into a hybrid engineering-tech company. The firm is now embedding digital process simulation and emission monitoring across its project portfolio. It has also partnered with startups developing membrane-based gas separation systems. Technip’s strength lies in global delivery capability combined with early adoption of disruptive gas treatment technologies.

 

Competitive Dynamics at a Glance

The current market hierarchy can be viewed through three competitive tiers:

• Tier 1 – Integrated Global Leaders: Honeywell UOP, Shell Global Solutions, Linde Engineering, and Technip Energies dominate full-cycle solutions and licensing.

• Tier 2 – Specialized Innovators: BASF and ExxonMobil Catalysts lead in process chemistry and solvent technology.

• Tier 3 – Modular and Agile Entrants: Smaller engineering firms and equipment manufacturers (like Enerflex or JGC Holdings) are carving niches through cost-efficient modular solutions.

What’s becoming increasingly evident is that competition isn’t just technical—it’s philosophical. Companies that combine sustainability, digital intelligence, and operational efficiency are redefining leadership standards.

 

Regional Landscape And Adoption Outlook

The global gas processing market follows the geography of gas itself — abundant in some regions, emerging in others, and deeply tied to local policy, infrastructure maturity, and investment appetite. Between 2024 and 2030, regional dynamics are being reshaped by two competing forces: the decarbonization imperative and the energy security push. Together, these trends are defining where capital flows and which technologies dominate.

North America

North America remains the heartbeat of gas processing innovation, thanks to the shale gas revolution and strong infrastructure reinvestment. The U.S. leads the world in gas processing capacity, concentrated mainly in the Permian, Marcellus, and Eagle Ford basins. Expansions are primarily modular or tied to LNG export terminals along the Gulf Coast. Refurbishments are widespread — older amine treating and cryogenic systems are being upgraded to accommodate higher NGL recovery rates and tighter methane controls.

Digitalization is now standard operating practice in North American facilities. Predictive analytics, leak detection systems, and AI-driven process control are integrated into nearly every new project. The focus has shifted from building new plants to enhancing efficiency and compliance of existing ones. Canada, meanwhile, is catching up through its LNG export initiatives in British Columbia and Alberta. The country’s push toward cleaner gas exports positions it as a rising player in premium low-carbon gas processing.

 

Europe

Europe’s gas processing landscape is constrained but evolving under intense environmental scrutiny. Many plants in the UK, Norway, and the Netherlands are being retrofitted with carbon capture units to align with the EU’s emission directives. New processing investment is limited, but there’s growing emphasis on hybrid facilities that can handle both natural gas and hydrogen blends.

Germany and Norway are front-runners in integrating CCUS with gas treatment and reforming units, setting precedents for net-zero compatible gas processing. Eastern Europe, by contrast, faces funding challenges, relying more on cross-border gas imports than domestic processing. However, the continent’s heavy investment in renewable gases (biomethane and synthetic methane) is sparking interest in micro-scale gas purification systems—a niche but promising segment.

 

Asia Pacific

Asia Pacific is the world’s most aggressive growth zone for gas processing capacity. Demand is expanding rapidly across China, India, Indonesia, and Australia, where governments view gas as both a transition fuel and a cornerstone of industrial development. China’s policy push toward energy diversification has led to a surge in sour gas processing plants, many equipped with high-efficiency sulfur recovery systems. India, similarly, is modernizing its onshore and offshore gas assets with digital control systems and modular sweetening units.

Australia remains a global hub for LNG-oriented gas processing, with sustained investments in large-scale cryogenic facilities. The region is also seeing collaboration between local EPCs and global licensors like Linde and Honeywell UOP to localize technology production. Despite high growth, infrastructure bottlenecks and skilled labor shortages continue to slow project execution in Southeast Asia.

 

Middle East and Africa (MEA)

MEA remains a powerhouse of gas reserves and processing expansion. The Middle East, led by Qatar, Saudi Arabia, and the UAE, is channeling billions into next-generation gas projects focused on LNG exports and hydrogen co-production. Qatar’s North Field expansion and Saudi Arabia’s unconventional gas development (like the Jafurah project) are reshaping the processing landscape with world-scale sour gas treatment and CO2 capture integration.

In Africa, Nigeria, Mozambique, and Algeria are building processing hubs to monetize their gas resources and reduce flaring. Africa’s opportunity lies in modular and mobile gas processing solutions, which are ideal for monetizing smaller, scattered fields. However, financing constraints and political uncertainty continue to limit the pace of development in several sub-Saharan countries.

 

Latin America

Latin America’s gas processing market is steady but regionally uneven. Brazil and Argentina dominate, supported by offshore pre-salt gas fields and Vaca Muerta’s shale basin. These regions are investing in integrated processing-LNG chains to expand exports and improve domestic supply reliability. Colombia and Peru are emerging quietly as regional players, leveraging public-private partnerships to build small-scale processing facilities aimed at rural electrification and industrial fuel supply.

Across the continent, a key challenge persists—balancing export ambitions with affordable domestic energy access. The result is a market driven more by national energy policy than by pure commercial competitiveness.

 

Global Outlook

By 2030, Asia Pacific and the Middle East will account for over half of new gas processing capacity additions, while North America remains the technology incubator for digitalized and low-carbon solutions. Europe will act as the testing ground for green gas and hydrogen integration, and Latin America and Africa will serve as the growth frontiers where modular, distributed processing models prove their worth.

 

End-User Dynamics And Use Case

The gas processing market operates through a web of end users that range from multinational oil majors to small, independent operators managing niche production fields. Each category of end user has distinct priorities, investment behaviors, and technology preferences. The balance between efficiency, compliance, and cost optimization defines how each one approaches processing infrastructure. From 2024 to 2030, these dynamics are becoming more pronounced as environmental standards tighten and digital tools reshape plant operations.

Integrated Oil & Gas Companies

Integrated oil and gas giants — such as Shell, ExxonMobil, Chevron, and TotalEnergies — dominate large-scale gas processing infrastructure. Their plants typically sit upstream of LNG export terminals or major petrochemical complexes. These companies prioritize operational reliability, energy efficiency, and carbon reduction. Most are investing in digital twin technology and advanced gas sweetening systems to achieve near-zero venting and flaring. They’re also integrating carbon capture units directly into processing trains to align with global sustainability goals.

Their advantage lies in scale and capital access. But the trade-off is slower innovation, as large corporate structures often delay adoption of modular or experimental designs. Still, their growing commitment to sustainability is reshaping the benchmark for compliance across the entire sector.

 

Independent Midstream Operators

Independent midstream firms like Targa Resources, Enterprise Products Partners, and Enerflex operate gathering, compression, and processing assets under third-party contracts. Their business model relies on providing toll-based services to multiple upstream producers. They’re highly sensitive to price cycles and tend to favor modular processing plants that can be scaled up or relocated quickly. This flexibility has made them vital players in North American shale basins and parts of Latin America where production volumes fluctuate.

For these operators, efficiency and uptime equal profitability. Many have adopted remote monitoring systems and cloud-based analytics platforms to predict maintenance needs and reduce downtime. While they may not lead in R&D, they’re pragmatic adopters of proven technologies.

 

National Oil Companies (NOCs)

In regions like the Middle East, Africa, and Asia, national oil companies remain the primary end users of large gas processing assets. Entities like QatarEnergy, ADNOC, and Saudi Aramco are building world-scale facilities tied to export and hydrogen development strategies. Their focus extends beyond domestic supply—they’re positioning gas processing as a national economic asset, a way to capture value across the energy chain.

These companies often push the frontier in sour gas and ultra-deep processing, thanks to access to both government funding and international technology partners. However, their reliance on foreign expertise still slows technology transfer and local capacity building.

 

Utilities and Power Producers

Power utilities, particularly in Asia and Europe, are becoming more active in downstream gas processing. They require purified natural gas with consistent calorific values to fuel combined-cycle power plants. Smaller on-site processing units are being integrated into utility infrastructure to stabilize fuel quality. Japan and South Korea, for instance, have utilities co-investing in gas processing facilities linked to LNG import terminals to ensure supply reliability and reduce transmission losses.

 

Petrochemical and Industrial Users

Refineries and petrochemical plants represent another growing user group. With global demand for ethane and propane feedstocks climbing, these facilities often co-locate near gas processing hubs to minimize logistics costs. This vertical integration is giving rise to hybrid sites that combine gas processing, fractionation, and petrochemical conversion. It’s a cost-efficient model gaining popularity across Asia Pacific and the Middle East. In this segment, reliability and feedstock purity outweigh flexibility. Even minor disruptions in processing can ripple through chemical production lines.

 

Use Case Highlight

A compelling example comes from the Jafurah Gas Development Project in Saudi Arabia. Operated by Saudi Aramco, it represents one of the largest unconventional gas processing projects globally. The facility integrates sour gas treatment, NGL recovery, and carbon capture systems within a single complex. By embedding digital process control and emission-tracking technology from the ground up, the site achieved a 15% reduction in energy intensity compared to conventional designs. The processed gas feeds both domestic industries and hydrogen production initiatives, underscoring the dual role of gas processing in energy transition and economic diversification.

This project illustrates how the next generation of gas processing plants will operate—not as isolated industrial sites, but as multi-purpose energy hubs tied to national decarbonization strategies.

 

Recent Developments + Opportunities & Restraints

The gas processing market has entered an era of accelerated modernization. Between 2023 and 2025, a steady flow of investments, technology collaborations, and regulatory initiatives has transformed how projects are financed, designed, and operated. The following summarizes key movements and structural trends shaping the near-term outlook of the sector.

Recent Developments (Last 2 Years)

• Honeywell UOP announced the launch of its new modular gas processing solution in mid-2024, integrating digital control systems and amine recovery optimization to reduce energy consumption by nearly 10%.

• Linde Engineering partnered with QatarEnergy in 2024 to supply low-emission cryogenic and CO2 recovery units for the North Field expansion, marking one of the first large-scale carbon-integrated gas processing projects in the Middle East.

• Technip Energies secured an EPC contract in India in late 2023 for a sour gas treatment plant incorporating advanced sulfur recovery and flare minimization systems—representing a new regional benchmark in emission control.

• ExxonMobil introduced an updated suite of low-carbon solvents in 2023 under its gas treating technology portfolio, specifically designed to meet tightening EU and APAC regulations on greenhouse gas emissions.

• Saudi Aramco’s Jafurah Gas Project reached a major construction milestone in 2024, integrating digital twin technology and real-time methane monitoring to optimize sour gas recovery and processing performance.

 

Opportunities

• Carbon Capture Integration: The blending of gas processing and carbon management is becoming a core investment theme. Plants equipped with built-in CCUS or CO2 recovery units are commanding higher project valuations and securing faster approvals from both financiers and regulators.

• Rising LNG Export Infrastructure: Expansion of LNG capacity in Asia Pacific and the Middle East is driving long-term demand for large-scale gas pre-treatment facilities. Projects in India, Indonesia, and Oman are expected to set new benchmarks for combined gas processing and liquefaction efficiency.

• Digitalization and Predictive Analytics: The move toward connected plants and real-time optimization is gaining momentum. End users are adopting AI-driven process controls to extend equipment life, reduce downtime, and minimize methane leaks. This digital layer is turning conventional gas plants into adaptive energy assets.

• Modularization for Frontier Fields: Compact, skid-mounted systems are emerging as the preferred option for small and remote gas fields in Africa, South America, and Central Asia. They reduce both time-to-market and capex exposure, enabling operators to monetize previously stranded reserves.

 

Restraints

• High Capital and Operating Costs: Advanced cryogenic and sweetening systems require heavy upfront investment, limiting smaller or independent operators’ participation in large-scale projects. Volatile gas prices also complicate return-on-investment timelines.

• Regulatory and Permitting Delays: Environmental permitting has become more stringent, especially in Europe and North America. Lengthy review cycles for emissions control, water usage, and waste management are delaying plant expansions and retrofits.

• Skilled Workforce Shortage: The transition to data-driven operations demands a hybrid skill set—operators who understand both process engineering and digital systems. Training gaps are emerging as a significant operational constraint, particularly in developing regions.

 

7.1. Report Coverage Table

Report Attribute	Details
Forecast Period	2024 – 2030
Market Size Value in 2024	USD 178.3 Billion
Revenue Forecast in 2030	USD 246.8 Billion
Overall Growth Rate	CAGR of 5.6% (2024 – 2030)
Base Year for Estimation	2024
Historical Data	2019 – 2023
Unit	USD Million, CAGR (2024 – 2030)
Segmentation	By Process Type, By Application, By Equipment, By End User, By Geography
By Process Type	Separation, Dehydration and Sweetening, Fractionation
By Application	LNG Production, Petrochemical Feedstock Recovery, Industrial Fuel Gas Supply, Gas Reinjection & Enhanced Recovery
By Equipment	Compressors, Heat Exchangers, Gas Treatment Units, Fractionation Towers, Valves & Filters
By End User	Integrated Oil & Gas Companies, Independent Midstream Operators, National Oil Companies, Utilities & Industrial Users
By Region	North America, Europe, Asia-Pacific, Middle East & Africa, Latin America
Country Scope	U.S., Canada, Germany, China, India, Japan, Saudi Arabia, Brazil, Australia, Nigeria
Market Drivers	- Expansion of LNG and petrochemical projects across Asia Pacific and the Middle East - Rapid adoption of carbon capture-integrated gas processing units - Rising investments in digitalized and modular plant systems
Customization Option	Available upon request