Civil Engineering Market - Global Industry Size, Share, Trends, Opportunity, and Forecast, Segmented By Service Type (Planning & Design, Construction, Maintenance, Others), By Construction Type (New Construction, Renovation & Retrofit), By End User (Government, Private Sector, Public-Private Partnerships), By Region & Competition, 2020-2030F

Market Overview

The Global Civil Engineering Market was valued at USD 9.92 trillion in 2024 and is expected to reach USD 13.06 trillion by 2030 with a CAGR of 4.53% during the forecast period.

The Civil Engineering Market encompasses a broad range of services and solutions related to the planning, design, construction, and maintenance of infrastructure projects. These include roads, bridges, tunnels, dams, buildings, airports, water systems, and other public and private sector facilities that support societal functions. Civil engineering plays a crucial role in shaping cities, enhancing connectivity, and ensuring sustainable development. It involves various disciplines such as structural, environmental, geotechnical, transportation, and construction engineering, all working in coordination to deliver safe, functional, and cost-effective infrastructure.

This market is driven by increasing demand for infrastructural improvements and urban development worldwide. Governments across both developed and developing nations are prioritizing investment in public infrastructure, including smart cities, transport corridors, renewable energy facilities, and water management systems. Population growth, rising urban migration, and economic expansion are creating substantial pressure on existing infrastructure, thus fueling the need for new construction and upgrades. Additionally, the increasing frequency of natural disasters and climate-related risks is encouraging investments in resilient and sustainable infrastructure solutions.

Technological advancements are also significantly contributing to the growth of the Civil Engineering Market. Innovations such as Building Information Modeling (BIM), 3D printing in construction, prefabrication techniques, and the integration of artificial intelligence and IoT in infrastructure management are improving project efficiency, reducing costs, and enhancing safety standards. These developments are attracting both public and private sector investments, further accelerating market expansion.

Key Market Drivers

Urbanization and Population Growth Driving Infrastructure Demand

The Civil Engineering Market is experiencing significant growth due to rapid urbanization and population growth, particularly in emerging economies. As global populations concentrate in urban centers, the demand for robust infrastructure—such as roads, bridges, public transit systems, and residential developments—continues to surge. Urban areas are projected to house over 68% of the world’s population by 2050, necessitating expansive construction projects to accommodate this shift.

Governments and private entities are investing heavily in smart cities, transit-oriented developments, and mixed-use projects to address urban sprawl and enhance livability. For instance, countries like India and China are prioritizing megaprojects, such as high-speed rail networks and new urban hubs, to support economic growth and connectivity. This trend is further amplified by the need to modernize aging infrastructure in developed nations, where deteriorating roads, bridges, and water systems require substantial upgrades to meet current safety and efficiency standards.

The complexity of these projects demands advanced civil engineering expertise, including innovative design, sustainable materials, and efficient project management. Additionally, the rise of megacities has spurred the development of vertical construction, with high-rise buildings and skyscrapers becoming essential to maximize land use in densely populated areas. The integration of digital technologies, such as Building Information Modeling (BIM), is enabling civil engineers to optimize project planning and execution, ensuring cost efficiency and timely delivery.

Furthermore, urbanization drives the need for resilient infrastructure to withstand environmental challenges, such as flooding or earthquakes, prompting engineers to incorporate adaptive designs and disaster-resistant materials. The private sector is also playing a pivotal role, with public-private partnerships (PPPs) becoming a preferred model for funding large-scale projects, particularly in regions with constrained public budgets. These partnerships facilitate the development of critical infrastructure, such as airports, ports, and highways, while sharing financial risks between stakeholders.

The global push for sustainable urban development further amplifies the demand for civil engineering solutions that prioritize energy efficiency, reduced carbon footprints, and green building standards. As cities expand, the Civil Engineering Market must address challenges related to land scarcity, regulatory compliance, and community impact, requiring innovative approaches to design and construction. The convergence of these factors underscores urbanization and population growth as a primary driver, compelling the Civil Engineering Market to evolve rapidly to meet the infrastructure demands of a growing, urbanized world.

By 2050, approximately 68% of the global population, or roughly 6.7 billion people, is expected to live in urban areas, according to United Nations projections. This shift is driving an estimated USD3.5 trillion in global infrastructure investment annually, with 60% of this spending directed toward urban projects like transportation networks and housing developments. In 2024, over 300 major urban infrastructure projects were initiated globally, reflecting the scale of demand for civil engineering services.

Technological Advancements Enhancing Project Efficiency

Technological advancements are transforming the Civil Engineering Market by enhancing project efficiency, reducing costs, and improving outcomes. Innovations such as Building Information Modeling (BIM), drones, 3D printing, and artificial intelligence (AI) are revolutionizing how projects are designed, executed, and maintained. BIM enables real-time collaboration among stakeholders, providing detailed digital representations of projects that streamline planning and minimize errors.

Drones are increasingly used for site surveys, offering precise topographical data and reducing the time and cost associated with traditional surveying methods. Meanwhile, 3D printing is gaining traction for constructing complex structural components, enabling faster production with reduced material waste. AI and machine learning are optimizing project management by predicting risks, improving resource allocation, and enhancing safety protocols. For instance, AI-driven analytics can forecast potential delays or cost overruns, allowing project managers to take proactive measures.

The adoption of modular construction techniques, supported by prefabrication technologies, is also accelerating project timelines while maintaining quality. These advancements are particularly critical in large-scale projects, such as bridges, tunnels, and skyscrapers, where precision and efficiency are paramount. Additionally, the integration of Internet of Things (IoT) devices enables real-time monitoring of infrastructure health, facilitating predictive maintenance and extending asset lifespans. The push for digital transformation is also driven by the need to meet stringent regulatory requirements and sustainability goals, as technologies enable engineers to design structures with lower environmental impacts.

However, the adoption of these technologies requires significant investment in training and infrastructure, posing challenges for smaller firms. Despite these hurdles, the competitive advantage offered by technological innovation is compelling firms to modernize their operations. The Civil Engineering Market is also benefiting from advancements in materials science, with the development of high-strength, eco-friendly materials like self-healing concrete and carbon-fiber composites.

These materials enhance durability while aligning with global sustainability objectives. As governments and private entities prioritize smart infrastructure, the demand for technology-driven civil engineering solutions is expected to grow, positioning the market for sustained expansion.

In 2024, approximately 70% of civil engineering firms globally adopted Building Information Modeling (BIM), resulting in a 15% reduction in project costs and a 20% decrease in delivery time, according to industry surveys. Additionally, drone usage in construction sites increased by 35% from 2022 to 2024, with over 10,000 drones deployed for surveying and monitoring major projects worldwide.

Sustainability and Green Building Standards

The growing emphasis on sustainability and green building standards is a critical driver for the Civil Engineering Market, as stakeholders prioritize environmentally responsible construction practices. Global concerns about climate change, resource depletion, and carbon emissions are pushing governments, developers, and engineers to adopt sustainable design principles. Green building certifications, such as LEED and BREEAM, are becoming standard requirements for new projects, driving demand for energy-efficient materials, renewable energy integration, and low-impact construction methods.

Civil engineers are tasked with designing structures that minimize environmental footprints while maintaining functionality and cost-effectiveness. For example, the use of recycled materials, such as reclaimed steel and concrete, is gaining traction, reducing waste and resource consumption. The development of net-zero buildings, which produce as much energy as they consume, is another priority, particularly in commercial and institutional projects. Governments are implementing stricter regulations, such as carbon emission caps and energy efficiency mandates, compelling the industry to innovate.

In response, civil engineering firms are investing in sustainable technologies, such as solar-integrated facades and green roofs, to meet these standards. The rise of circular economy principles is also influencing project design, encouraging the reuse and repurposing of materials to extend their lifecycle. Additionally, sustainable urban planning is driving the creation of eco-friendly cities, with projects incorporating green spaces, efficient public transit, and water recycling systems. These initiatives require advanced engineering expertise to balance environmental goals with structural integrity.

The financial benefits of sustainability, such as reduced operational costs and increased property values, are further incentivizing adoption. However, challenges such as higher upfront costs and the need for specialized expertise can hinder implementation, particularly in developing regions. Despite these obstacles, the global push for sustainability is reshaping the Civil Engineering Market, fostering innovation and creating opportunities for firms that prioritize green solutions.

In 2024, over 25,000 buildings globally achieved LEED certification, reflecting a 40% increase from 2020. Additionally, sustainable construction materials accounted for 30% of total material usage in civil engineering projects, with recycled concrete usage growing by 25% annually. Global investments in green infrastructure reached USD1.2 trillion in 2024, driven by government mandates for net-zero buildings.

Government Investments in Infrastructure Development

Government investments in infrastructure development are a major driver of the Civil Engineering Market, as nations prioritize economic growth, connectivity, and resilience. Public sector funding is fueling large-scale projects, including highways, airports, railways, and water management systems, to support urbanization and industrial expansion. In developed economies, governments are allocating significant budgets to repair and upgrade aging infrastructure, such as bridges and dams, to meet modern safety and efficiency standards. For example, the United States has committed billions to infrastructure revitalization through legislative initiatives, creating opportunities for civil engineering firms. In emerging markets, governments are investing in transformative projects, such as high-speed rail networks and smart cities, to drive economic development and global competitiveness.

Public-private partnerships (PPPs) are increasingly utilized to share financial and operational risks, enabling the execution of complex projects with limited public funds. These investments are also driven by the need to address climate change, with governments funding resilient infrastructure, such as flood defenses and renewable energy facilities, to mitigate environmental risks. Civil engineering firms are tasked with delivering projects that align with national development goals while adhering to stringent regulatory and environmental standards. The complexity of these projects requires expertise in project management, cost estimation, and stakeholder coordination.

Additionally, government policies promoting digital infrastructure, such as 5G networks and smart grids, are creating new opportunities for civil engineers to design supporting systems. While funding availability and political priorities can create uncertainties, the long-term commitment to infrastructure development ensures sustained demand for civil engineering services.

In 2024, global government spending on infrastructure reached USD4.8 trillion, with 45% allocated to transportation and 25% to water and energy projects. Over 1,200 public-private partnership projects were initiated globally, with a combined value of USD900 billion, according to public budget reports. The United States alone allocated USD550 billion for infrastructure upgrades between 2022 and 2024.

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Key Market Challenges

Regulatory Complexities and Approval Delays

One of the foremost challenges faced by the civil engineering market is the growing complexity of regulatory frameworks and the prolonged timelines associated with obtaining necessary permits and approvals. As infrastructure projects expand in scale and scope, they become subject to multiple layers of scrutiny involving environmental impact assessments, land acquisition regulations, building codes, zoning laws, safety standards, and labor compliance mandates. These regulatory obligations vary significantly across countries, states, and even local jurisdictions, thereby introducing a high degree of administrative uncertainty and operational risk for engineering firms and construction contractors.

Delays in regulatory approvals often result in cost overruns, schedule disruptions, and capital lock-ins, particularly in the case of public-private infrastructure projects where funding is milestone-based. In some regions, overlapping responsibilities among government agencies or inadequate digitalization of permitting systems further compound these delays. Additionally, environmental regulations are becoming increasingly stringent due to rising awareness about climate change and resource sustainability. While these environmental safeguards are essential, they can extend project preparation time by several months or even years, especially when addressing ecological sensitivities or conducting stakeholder consultations.

Furthermore, evolving tax regimes, changes in construction law, and frequent policy reversals in certain emerging markets can disrupt investment planning and erode investor confidence. Engineering firms are often required to allocate substantial resources toward legal, environmental, and regulatory compliance teams, which increases their overheads and reduces profitability margins. In highly urbanized regions, securing approvals for demolitions, retrofitting, or brownfield developments becomes even more arduous due to community resistance, historical preservation considerations, and legal disputes over land use rights.

In essence, while the civil engineering market continues to expand in response to global infrastructure demand, the intricate and evolving nature of regulatory environments remains a structural barrier. This necessitates that market participants maintain robust compliance mechanisms, engage proactively with stakeholders, and invest in regulatory expertise to ensure project continuity and risk mitigation.

Shortage of Skilled Labor and Talent Retention Issues

The civil engineering market is grappling with an acute shortage of skilled labor and engineering professionals, a challenge that is both persistent and global in scope. As infrastructure development accelerates across regions, the demand for qualified civil engineers, project managers, construction supervisors, environmental consultants, geotechnical specialists, and on-site technicians continues to outpace supply. This talent gap is particularly pronounced in high-growth economies where massive urbanization and government-backed infrastructure programs are underway.

Several factors contribute to this shortage. First, the civil engineering sector is often perceived by younger generations as physically demanding and less technologically advanced compared to fields such as software engineering or finance. As a result, fewer students are enrolling in civil engineering and construction management programs, creating a pipeline issue. Second, aging workforces in developed economies are leading to a significant loss of experienced professionals, and replacement through younger entrants has not been proportional. Third, in many regions, especially in remote or high-risk areas, attracting and retaining skilled labor is difficult due to poor working conditions, long hours, and limited access to basic amenities.

Moreover, the rise in demand for digital engineering tools such as Building Information Modeling, Geographic Information Systems, and drone-based site inspections requires the workforce to possess both traditional civil engineering knowledge and advanced technical proficiency. Bridging this digital skill divide poses a considerable challenge for companies, especially small and medium-sized enterprises with limited training budgets. In addition, frequent job-switching, wage inflation, and a lack of long-term incentives have also resulted in high attrition rates among mid-level professionals, adversely affecting project continuity and institutional knowledge retention.

To mitigate these issues, civil engineering firms must invest in comprehensive training and certification programs, collaborate with academic institutions to develop industry-ready curricula, and implement strong human resource strategies to enhance employee engagement. Failure to address the skilled labor shortage could slow down project delivery timelines, compromise quality and safety standards, and undermine the overall competitiveness of the sector.

Key Market Trends

Integration of Digital Technologies in Infrastructure Development

A prominent trend shaping the Civil Engineering Market is the rapid integration of digital technologies into infrastructure planning, design, and execution processes. Engineering firms are increasingly adopting digital tools such as Building Information Modeling, Geographic Information Systems, artificial intelligence, machine learning, and Internet of Things to improve project precision, operational efficiency, and long-term asset performance.

Building Information Modeling is enabling multidisciplinary collaboration by offering real-time, data-rich visualizations of infrastructure projects. It streamlines the design process, minimizes errors, enhances clash detection, and supports lifecycle management from concept to demolition. Geographic Information Systems are being utilized for spatial analysis, terrain modeling, and site feasibility studies, aiding civil engineers in making informed planning decisions. Artificial intelligence and machine learning are helping in predictive maintenance, risk modeling, and optimizing construction workflows, especially in large-scale and complex infrastructure ventures.

The use of drones, sensors, and remote monitoring equipment is transforming on-site operations by improving safety, enabling automated inspections, and offering live project updates. This trend is not only accelerating construction timelines but also reducing labor costs and enhancing quality control. Additionally, digital twins—virtual replicas of physical infrastructure—are gaining traction for real-time performance monitoring and predictive analytics.

As urban development and infrastructure investment continue to rise globally, the demand for digital transformation in civil engineering is expected to increase significantly. Governments and private developers are now mandating the use of digital tools to ensure sustainability, transparency, and accountability in infrastructure delivery. This trend is also fostering greater interoperability among project stakeholders and driving the adoption of cloud-based platforms for data management.

Growing Emphasis on Sustainable and Green Engineering Practices

Sustainability has emerged as a critical trend in the Civil Engineering Market, driven by increasing regulatory mandates, environmental awareness, and stakeholder demand for eco-friendly infrastructure solutions. Civil engineers are now prioritizing the use of sustainable materials, low-carbon construction methods, and energy-efficient designs to reduce the environmental impact of their projects.

Green engineering practices are being embedded into every stage of the infrastructure lifecycle. During the design phase, engineers are incorporating passive solar orientation, energy-efficient ventilation, and green building materials such as recycled concrete, low-emission asphalt, and sustainable steel. During construction, techniques like prefabrication, modular building, and lean construction are reducing material waste and minimizing on-site emissions. Water conservation, renewable energy integration, and stormwater management are also becoming standard features in both public and private infrastructure developments.

Governments across regions are introducing green building certifications, tax incentives, and performance-based regulations to promote environmentally responsible infrastructure. Programs such as Leadership in Energy and Environmental Design (LEED) and other national sustainability codes are encouraging project developers to meet specific environmental benchmarks. Additionally, lifecycle cost analysis and carbon footprint assessments are being incorporated into procurement criteria and project evaluations.

Moreover, the emphasis on climate-resilient infrastructure is driving innovation in flood control systems, coastal protection structures, and seismic-resistant designs. Engineers are increasingly using nature-based solutions, such as green roofs, bio-retention basins, and permeable pavements, to mitigate climate risks while enhancing urban livability. The trend is also leading to greater collaboration among environmental scientists, urban planners, and civil engineers.

Rise of Public-Private Partnerships in Infrastructure Projects

The rise of public-private partnerships is significantly influencing the structure and dynamics of the Civil Engineering Market. Governments across the globe are increasingly relying on collaborations with private sector players to fund, design, construct, and operate critical infrastructure projects such as highways, airports, water systems, and energy facilities. These partnerships are enabling faster project delivery, innovation, and cost efficiency, especially in regions facing fiscal limitations.

Public-private partnerships allow governments to leverage private sector expertise, financial resources, and risk management capabilities. In return, private entities receive long-term revenue streams through concessions, user fees, or availability payments. This collaborative model is becoming increasingly prevalent in sectors such as transport, urban development, and environmental infrastructure, where large-scale investment is required but public funding alone is insufficient.

The trend is also driving demand for integrated project delivery approaches, where civil engineering firms work closely with financial institutions, legal advisors, and government agencies from the early planning stages. This collaborative environment fosters transparency, risk sharing, and alignment of project objectives, which improves the probability of on-time and on-budget completion. Additionally, performance-based contracts and outcome-driven metrics are encouraging innovation, quality assurance, and operational efficiency.

Emerging markets in Asia Pacific, Latin America, and Africa are witnessing a surge in public-private partnership activity as they pursue rapid infrastructure expansion. International development banks and multilateral agencies are also promoting such partnerships through technical assistance, risk guarantees, and concessional financing. Furthermore, digital tools and standardized contract frameworks are simplifying the structuring and monitoring of public-private partnership projects, making them more attractive to investors.

To capitalize on this trend, civil engineering firms are building specialized capabilities in financial structuring, regulatory navigation, and stakeholder engagement. Those with a strong track record in managing public-private partnership projects are being preferred for high-value infrastructure contracts. 

Segmental Insights

Service Type Insights

In 2024, the Construction segment dominated the Civil Engineering Market by Service Type and is expected to maintain its dominance throughout the forecast period. This dominance is primarily attributed to the significant surge in infrastructure development projects globally, including transportation networks, urban residential complexes, commercial buildings, industrial facilities, and large-scale public infrastructure.

The construction segment plays a pivotal role in translating planning and design into physical structures, thereby capturing the highest share of civil engineering expenditure. Governments across both developed and developing regions are increasingly allocating substantial budgets for the construction of highways, railways, airports, water treatment plants, and renewable energy facilities, further reinforcing the segment’s leadership. Additionally, private sector investments in real estate and industrial expansion have fueled demand for construction services, supported by favorable regulatory frameworks, financing models, and international collaborations.

The construction segment also benefits from rapid technological advancements such as prefabrication, modular building, automation, and the use of digital construction tools, which enhance productivity and cost-efficiency. Moreover, the post-pandemic recovery phase has witnessed a resurgence in construction activity, particularly in urban areas where population growth and migration trends necessitate new housing, transportation links, and social infrastructure. As nations pursue climate-resilient and smart infrastructure goals, the demand for sophisticated construction capabilities is expected to increase, placing this segment at the center of long-term strategic initiatives.

Furthermore, ongoing public-private partnership initiatives and infrastructure stimulus programs are expected to generate continuous construction activity across various sectors. In contrast, while the Planning and Design, Maintenance, and Other segments remain critical to project success, they constitute smaller proportions of total civil engineering investments. Therefore, based on project volume, value, and continued global emphasis on infrastructure expansion, the Construction segment is projected to retain its dominant position in the Civil Engineering Market during the forecast period.

Construction Type Insights

In 2024, the New Construction segment emerged as the dominant category within the Civil Engineering Market by Construction Type and is anticipated to maintain its leading position throughout the forecast period. This dominance is primarily driven by the increasing global demand for new infrastructure to support urbanization, industrialization, and population growth. Developing nations, particularly in Asia Pacific, the Middle East, and Africa, are experiencing rapid economic expansion and urban migration, necessitating the creation of new transportation systems, residential communities, commercial centers, and utility networks.

In addition, governments across the world are launching ambitious infrastructure development programs focused on smart cities, renewable energy facilities, and transportation corridors, which predominantly fall under new construction initiatives. These programs are being reinforced by increased public investment, international financing, and policy reforms aimed at accelerating project approvals and private sector participation. Moreover, the expansion of industrial zones, logistics parks, healthcare facilities, and educational institutions further contributes to the high volume of new construction projects.

Technological advancements in construction materials, automation, and project management tools are also making new construction more efficient and scalable. While the Renovation and Retrofit segment plays a critical role in modernizing aging infrastructure and enhancing sustainability, it is typically limited to specific geographies, particularly in mature economies where legacy systems require upgrades.

However, the scale, investment intensity, and strategic relevance of new infrastructure developments far surpass the contributions of renovation and retrofit activities. As a result, the New Construction segment commands the largest share of civil engineering activity and is expected to continue dominating the Civil Engineering Market during the forecast period, supported by ongoing megaprojects, urban infrastructure expansion, and growing demand for future-ready facilities across both public and private sectors.

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Regional Insights

Largest Region

In 2024, the Asia Pacific region dominated the Civil Engineering Market and is projected to maintain its dominance during the forecast period. This regional leadership is primarily driven by the region’s accelerated pace of urbanization, population growth, and economic development, particularly in countries such as China, India, Indonesia, Vietnam, and the Philippines. Governments across the Asia Pacific region are heavily investing in large-scale infrastructure development programs that include transportation networks, smart cities, industrial corridors, energy plants, water and sanitation systems, and urban housing projects.

These initiatives are part of long-term national strategies aimed at improving connectivity, boosting productivity, and enhancing the overall quality of life. In addition to public sector investments, the region has witnessed a significant influx of private capital, foreign direct investments, and multinational partnerships that have further propelled the demand for civil engineering services. The rapid industrialization and the growing need for logistics, warehousing, and manufacturing infrastructure have also contributed to the expansion of the civil engineering sector in the region.

Furthermore, regional governments are implementing policy reforms and easing regulatory barriers to fast-track project execution and encourage public-private partnerships. The Asia Pacific region is also embracing modern construction technologies, digital engineering tools, and sustainable building practices, further enhancing the efficiency and scalability of infrastructure development. In contrast, while regions such as North America and Europe remain important markets with significant renovation and modernization needs, the sheer volume, scale, and diversity of new construction projects in Asia Pacific place it at the forefront of global civil engineering activity.

With strong economic fundamentals, ambitious infrastructure agendas, and a growing focus on resilience and sustainability, the Asia Pacific region is expected to continue leading the Civil Engineering Market in the coming years, making it the most influential region in terms of investment flow, project execution, and sectoral growth.

Emerging Region

The Middle East and Africa region is emerging as a significant growth area in the forecast period for the Civil Engineering Market, driven by an increasing focus on infrastructure diversification, urban development, and economic transformation. Countries across the region, including the United Arab Emirates, Saudi Arabia, Egypt, Qatar, South Africa, and Nigeria, are launching ambitious infrastructure initiatives aimed at reducing dependence on oil-based economies and promoting sectors such as tourism, logistics, real estate, and renewable energy.

Mega infrastructure projects such as Saudi Arabia’s NEOM smart city, the expansion of Dubai’s transportation and logistics network, and Egypt’s new administrative capital are generating substantial demand for civil engineering services related to planning, design, and construction. These projects are not only large in scale but also incorporate advanced technologies, sustainable design principles, and futuristic urban planning, positioning the region as a hub for innovative infrastructure development.

Additionally, governments in the Middle East and Africa are implementing economic reforms, establishing infrastructure investment funds, and promoting public-private partnerships to attract foreign direct investments and accelerate project delivery. The rapid urbanization and growing middle-class population across African nations are also creating new demand for housing, transportation, water management systems, and social infrastructure, thereby fueling growth in the civil engineering sector.

Moreover, global engineering firms and contractors are increasingly entering the region through joint ventures and strategic collaborations, encouraged by favorable policy environments and a growing project pipeline. While challenges such as political instability and funding constraints exist in some parts of the region, the overall momentum toward modernization, economic diversification, and international cooperation is positioning the Middle East and Africa as a high-potential, emerging region in the Civil Engineering Market. The sustained efforts to enhance regional connectivity, promote smart cities, and invest in critical infrastructure are expected to drive robust growth in this region throughout the forecast period.

Recent Development

• In April 2025, AECOM appointed Simon Ng as Senior Vice President for Strategic Business Development – Alternative Delivery in Canada. This leadership move reflects the company’s commitment to expanding its presence in the Canadian market through innovative infrastructure delivery approaches. Simon Ng is expected to play a key role in advancing alternative project delivery models, fostering public-private collaboration, and enhancing client engagement strategies to support large-scale infrastructure development across the region, aligning with AECOM’s broader growth and operational objectives.
• In February 2025, AECOM strengthened its regional leadership by appointing Bane Gaiser as Chief Executive of the Buildings + Places Global Business Line, Richard Whitehead as Regional Chief Executive for Europe and India, and Sam Donelson as Regional Chief Executive for U.S. East and Latin America. These strategic appointments aim to enhance regional operational effectiveness, drive localized growth, and align business strategies with evolving market demands, reinforcing AECOM’s commitment to delivering tailored solutions across diverse global geographies.
• In early April 2025, Fluor was issued a letter of intent to provide engineering, procurement, and construction management services for a second large-scale pharmaceutical facility located in Lebanon, Indiana. This new assignment, structured as a reimbursable contract, forms part of what is recognized as the largest active pharmaceutical ingredient manufacturing project in the history of the United States. The development highlights Fluor’s growing footprint in the life sciences sector and its expertise in delivering complex, high-value infrastructure solutions.
• In June 2025, WSP announced its agreement to acquire Ricardo, a United Kingdom-based engineering consultancy, for approximately £281 million. This strategic acquisition is expected to strengthen WSP’s capabilities in the rail, energy, and environmental advisory sectors, while also expanding its geographic presence and service offerings across key markets, including the United Kingdom, Australia, and the Netherlands. The transaction aligns with WSP’s long-term growth strategy and reinforces its position as a leading global provider of sustainable infrastructure and consulting solutions.

Key Market Players

• AECOM
• Bechtel Corporation
• Fluor Corporation
• Jacobs Engineering Group Inc.
• WSP Global Inc.
• China Communications Construction Company Limited
• China State Construction Engineering Corporation Ltd.
• Larsen & Toubro Limited
• Balfour Beatty plc
• Skanska AB

Report Scope:

In this report, the Global Civil Engineering Market has been segmented into the following categories, in addition to the industry trends which have also been detailed below:

•  Civil Engineering Market, By Service Type:

o   Planning & Design

o   Construction

o   Maintenance

o   Others

• Civil Engineering Market, By Construction Type:

o   New Construction

o   Renovation & Retrofit

• Civil Engineering Market, By End User:

o   Government

o   Private Sector

o   Public-Private Partnerships

• Civil Engineering Market, By Region:

o   North America

§  United States

§  Canada

§  Mexico

o   Europe

§  Germany

§  France

§  United Kingdom

§  Italy

§  Spain

o   South America

§  Brazil

§  Argentina

§  Colombia

o   Asia-Pacific

§  China

§  India

§  Japan

§  South Korea

§  Australia

o   Middle East & Africa

§  Saudi Arabia

§  UAE

§  South Africa

Competitive Landscape

Company Profiles: Detailed analysis of the major companies present in the Global Civil Engineering Market.

Available Customizations:

Global Civil Engineering Market report with the given market data, TechSci Research offers customizations according to a company's specific needs. The following customization options are available for the report:

Company Information

• Detailed analysis and profiling of additional market players (up to five).

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