Global Hydrogen Gas Turbine Market 2025 – 2034

Reports Description

As per the Hydrogen Gas Turbine Market analysis conducted by the CMI Team, the global Hydrogen Gas Turbine Market is expected to record a CAGR of 7.18% from 2025 to 2034. In 2025, the market size is projected to reach a valuation of USD 4.96 Billion. By 2034, the valuation is anticipated to reach USD 9.26 Billion.

Overview

Hydrogen gas turbines represent a forward-looking class of power generation technology that is engineered to run on pure hydrogen or blends with natural gas, thereby replacing the carbon-rich combustion typical of conventional turbines. Their advent offers a pathway to deep emission cuts in the electricity sector, especially for industrial users and grid operators that require firm and flexible generation.

Both greenfield installations and retrofits of legacy units can benefit, as modern combustion systems are tolerant of hydrogen mixes up to 100 percent. When fed with electrolyte-produced hydrogen, these machines produce near-zero CO₂ and low levels of local pollutants, positioning them as key assets in long-term decarbonisation plans. Continuous improvements in materials, sensor-driven controls, and propulsion cycles are raising efficiency, extending hardware life, and widening fuel envelopes.

Strong climate commitments are driving a rapid uptick in the hydrogen-gas-turbine pipeline across North America, Europe, and Asia-Pacific. Governments and consortia are funding large-scale electrolyser parks, liquefaction terminals, and demonstration plants where derivatives from wind and solar power will displace fossil gas.

In parallel, turbine developers such as Siemens Energy, GE Vernova, Mitsubishi Power, Ansaldo Energia, Baker Hughes, Doosan Heavy, and OPRA are validating combustion profiles, adaptive controls, and system dynamics in multi-megawatt test cells. Although high capital costs, hydrogen supply chains, and storage pressure levels remain hurdles, evolving policy signals, industrial partnerships, and learning-by-doing are narrowing the gaps, enabling first commercial deployments from the middle of this decade.

Key Trends & Drivers

The Hydrogen Gas Turbine Market Trends have tremendous growth opportunities due to several reasons:

• Industrial Decarbonization: Hydrogen turbines can also facilitate deep decarbonization when hydrogen is used in high-temperature energy applications such as steel, cement, and oil refining. In addition, the launch of India’s National Green Hydrogen Mission in January 2025 presents an opportunity, which includes $2.5 billion in funding for hydrogen use in steel and fertilizer sectors. In February 2025, Finland opened Harjavalta’s first large-scale green hydrogen plant intended to serve local industries as well as integrate with the district heat. These Harjavalta investments confirm the increasing focus on green hydrogen infrastructure to decarbonize energy-intensive industries through the use of hydrogen turbines. Growing policy and funding support reinforce the idea that turbines are becoming indispensable in industrial energy approaches.

• Energy Security Focus: Nation-states are adopting hydrogen turbines for enhanced domestic energy resilience while reducing import fossil fuel dependency. Australia proposed local-sourcing policies for gas and hydrogen infrastructure supply chains as part of sovereignty efforts in June 2025. That same month, the European Commission suggested subsidizing the use of hydrogen power in heavy industry to shield them from volatile energy prices as part of the Clean Industrial Deal. All these policies indicate a global shift towards self-reliance in critical energy assets and infrastructure, which positions hydrogen turbines as key enablers for strengthening grid security and minimizing exposure to global fuel markets.

• Private–Public Collaborations: The expansion of public-private pilot projects is essential, alongside their international scaling. For that reason, The EU Clean Hydrogen Partnership launched an invitation to tender with a budget of €220 million dedicated to the distribution and production of hydrogen within the EU in January 2023. In 2023, India’s National Green Hydrogen Mission implemented regionally auction-driven hub creation, successfully aggregating private-sector electrolyser and supplier investment. The 2024 pilot deployment of a totally hydrogen-fueled SGT-400 turbine in France by the HYFLEXPOWER consortium (Siemens Energy and ENGIE partners) exemplifies these collaborative models. These frameworks are synergizing funding, technical resources, and risk-sharing resulting in accelerated ecosystem maturity.

Key Threats

The Hydrogen Gas Turbine Market has several primary threats that will influence its profitability and future development. Some of the threats are:

• Regulatory Uncertainty: Executives across industries contend that persistent shifts in clean-energy tax rules are putting hydrogen-turbine initiatives on hold and eroding confidence among potential backers. In May 2025 the U.S. House Ways and Means Committee proposed pulling forward the phase-down schedule for two key provisions, sections 45Y and 48E of the Inflation Reduction Act, now set to expire in 2028. At roughly the same moment analysts cautioned that an aggressive legislative agenda could slash the 45V hydrogen credit if rival proposals gain traction. By June 2025 Reuters, quoting senior senators, revealed a fresh tariff scheme targeting Chinese clean-energy components that might overlap with steeper cuts to wind and solar rebates, further amplifying the policy whipsaw. Such uncertainty chills long-horizon project development and makes financing terms unpredictable for turbine developers.

• Competing Technologies: Hydrogen turbines now contend with an expanding field of decarbonization options, including battery storage, small modular nuclear reactors, direct-air carbon capture, and synthetic fuels. In March 2024 Exxon’s chief executive cautioned that ongoing inflation-reduction-act credits are the linchpin for blue-hydrogen viability, strip them away and several planned megaprojects are likely to stall. At the same moment early-stage CCUS ventures and SMR pilots gained momentum, diverting venture capital and corporate R&D dollars from hydrogen turbines. By June 2025, Business Insider reported a broader clean-tech investment pullback sparked by shifting U.S. policy, while European and Asian markets pivoted toward fusion, advanced storage, and other low-carbon pathways. Against this backdrop, hydrogen turbines must demonstrate compelling cost and reliability metrics or risk relegation to a niche role.

• Volatile Hydrogen Supply: For hydrogen turbines to thrive, operators need a steady and cheap hydrogen flow, but persistent upstream bottlenecks still obstruct that goal. In June 2025 backers axed the Central Queensland export terminal after costs overran projections and government incentives dimmed, leaving the project officially dead. Compounding this, the Queensland administration quietly repealed its renewable-energy-target framework and trimmed green-hydrogen subsidies the previous month, underscoring persistent policy flip-flop. Absent a stable production ecosystem and supportive regulatory landscape, turbine operators struggle to lock in the ten- to twenty-year supply contracts that any large fleet demands. Such uncertainty in the hydrogen value chain remains among the most consequential threats to turbine scale-up.

Opportunities

• Digital Twins and AI: Modern digital-twin platforms now incorporate AI diagnostics, steadily boosting the efficiency and reliability of hydrogen-fueled turbines. In April 2024 engineers deployed a real-time digital replica that tracks azimuthal thermoacoustic instability in the burner and allows predictive adjustments, thereby raising safety margins. The ongoing 2024 HYFLEXPOWER pilot of a 100-percent-hydrogen SGT-400 turbine also leverages continuous flame and turbulence monitors to refine operation. Collectively, these tools enable operators to foresee anomalies, calibrate combustion precisely, and in turn reduce unscheduled downtime and maintenance spending across entire fleets.

• ESG and Carbon Credits: Deploying hydrogen turbines fits neatly with a company’s ESG goals and opens doors to new carbon-credit markets. In early 2025 Indias Green Hydrogen Certification Scheme will let producers earn independently verified credits, making the economics of hydrogen turbines stronger. Likewise, Helsinki’s Harjavalta plant, scheduled to go live later that year, will generate credits by feeding certified green hydrogen to local heavy industry. Linking turbine operation to this certified hydrogen thus speeds decarbonization, reassures investors with clear ESG evidence, and adds revenue from verifiable climate data.

• Blended-Fuel Zones: Running gas turbines on hydrogen-natural gas mixtures provides a practical step toward cleaner power, since it matches emissions goals with what the current system can handle. In October 2023 the HYFLEXPOWER team pushed Siemens SGT-400 engines to burn nearly pure hydrogen for the first time, following a successful trial with a 30-percent blend late in 2022. Those runs confirmed that dry low-emission combustion and modular burners perform steadily no matter how much hydrogen is fed in. By mapping turbine behavior over this range of fuels, the pilots create room for blended-fuel zones on the grid and let operators phase in larger hydrogen shares as pipes and compressors are upgraded.

Category Wise Insights

By Type

• Turbojet: Typically, turbojets are gas turbine engines that create thrust exclusively through the rapid expulsion of high-velocity gas, which is mainly used in military aircraft and supersonic jets. Even though turbojets are small in size, their efficiency is lacking compared to more modern engine designs. In October 2023, Rolls-Royce began testing a turbojet they intended to use for training jets that could operate on a 20% hydrogen blend. Sponsored by the UK MOD, the aim of the project was to test hypersonic performance. It represented a groundbreaking achievement in military aviation powered by hydrogen. Tests conducted in the UK and Germany underscored its relevance for transatlantic defense collaboration.

• Turbofan: As with all gas turbines, a turbofan features a large front mounted fan as its first characteristic and it also serves to improve fuel efficiency and noise compared to earlier engines. Because of these attributes, it is widely used in commercial airline aircraft. Its propulsion system is a hybrid, consisting of both jet exhaust and bypass air. In March 2024, GE Aviation announced the XA100 turbofan designed to operate on a 60% hydrogen fuel blend. Airbus and Rolls-Royce have formed a consortium for the development of this engine. These measures further advance green air travel and are in line with CORSIA compliance goals.

• Turboprop: For regional and short-haul aircraft where fuel efficiency is paramount, gas turbines that power propellers are employed. They are ideal for short-haul flights. A turboprop prototype was demonstrated by Pratt & Whitney Canada in June 2025 as a part of their Clean Skies campaign, using a 20-60% hydrogen blend. The engine ran 5,000 simulated flight cycles. Canada’s Transport Authority regarded this as a significant advancement towards reducing emissions in regional air travel.

• Turboshaft: These engines are used for industrial machines and helicopters as they generate shaft power instead of thrust. Their small size and ability to change the amount of power they produce make them well-suited to use in rotary-winged aircraft. In February 2024 Safran tested a hydrogen-ready turboshaft with a 60% blend under France’s aerospace decarbonization program. They announced the certification for european rotary aviation by 2027. This demonstrates the capability of minimised emissions for turboshaft powered vertical flight.

By Design Type

• Heavy-Duty Gas Turbines: These are large industrial gas turbines that are optimized for continuous operation, generating power at a high output level. They are primary in utilities and energy-intensive industries. In April 2025, Siemens Energy commenced commercial testing of a 430 MW turbine modified to run on 100% green hydrogen in Germany. This accomplishment helps to achieve the net-zero goals of the country and acts as a proof of concept for large-scale grid hydrogen applications. Moreover, it is one of the earliest comprehensive hydrogen deployments in heavy-duty turbines globally.

• Aero-derivative Gas Turbines: These are lighter and smaller than heavy-duty turbines and are modified from aircraft engines. They are used in decentralized and peaking power plants. They can quickly startup and are flexible in terms of fuel used. In January 2025, GE Vernova tested the LM2500 aero-derivative turbine on a 60% hydrogen blend offshore Australia. The project benefits hybrid power systems in island nations and coastal grids and further advances the National Hydrogen Strategy goals of Australia.

By H₂ Fuel Composition

• Up to 20%: Turbines can utilize hydrogen blends up to 20% with minimal modifications to the systems. This provides an introductory approach toward decarbonization. In Saudi Arabia NEOM in November 2022 started co-firing in grid-connected turbines with 20% hydrogen and natural gas. This has demonstrated emissions reduction bolstered by the lack of infrastructure overhaul required. This model is now being used for replication across the Gulf and Europe.

• 20% to 60%: This is a mid-range blend that needs advanced different combustion systems. It can still lower CO₂ emissions significantly while using some natural gas. As of October 2023, Siemens Energy completed their 1,000 hour test of the SGT-800 turbine on 50% hydrogen. The GENHY trial in Europe has shown success, which is incentivizing other regions to retrofit turbines. Trade associations are developing commercial warranty frameworks for this market segment.

• 60% to 100%: These blends have near zero carbon emissions but are not easy to integrate because of the design overhaul needed for the turbine systems. In April 2025, the HYFLEXPOWER consortium demonstrated 100% hydrogen operation of the Siemens SGT-400 gas turbine in France. It attained full load and industrial low-NOx combustion under regulatory conditions. Hydrogen turbine deployment roadmaps for grid-scale integration are being formulated by regulators and OEMs.

By Application

• Steel Mills: The demanding thermal intensity and energy consumption of steel mills makes them ideal candidates for hydrogen turbines that offer cleaner process heat and on-site power generation. In March 2025, Utility Global introduced its H₂Gen® system at a North American steel facility to enable the use of blast furnace gas as a source of hydrogen for turbines. Simultaneously, Finland’s green steel initiative, “Hybrit,” obtained commercial funding in June 2025, planning to install turbines powered by hydrogen to pursue full decarbonization goals for steel production. These measures comply with EU CBAM regulations as well as international steel emission reduction goals. The adoption of hydrogen turbines is becoming crucial for reduced-emission steelmaking in developed economies.

• Oil & Gas: In the oil and gas sector, gas turbines are employed for power generation and gas compression. Operational emissions can be lowered through hydrogen blends. In June 2025, Mitsubishi Power and Georgia Power completed a trial of co-firing hydrogen and natural gas in an M501GAC turbine at Plant McDonough in the U.S. This was one of the first attempts in the industry to use hydrogen in large-scale utility systems. Other plants in the U.S. are now being considered for this replication. It exemplifies the incremental decarbonization potential of legacy oil and gas assets using hydrogen.

• Aerospace & Defense: The use of hydrogen turbines in auxiliary and propulsion systems within the aerospace and defense industries deepens emission mitigation and enhances energy autonomy. In March 2025, Baker Hughes was awarded a contract by the U.S. Government to implement NovaLT turbines in secure defense data centers marking a shift from oil and gas towards defense infrastructure. These turbines can be deployed modularly and are ready for hydrogen use. This further shows the shift of governmental focus towards more resilient energy systems designed for hydrogen use. It also shows the dependence on and need for government contracts on grant innovations.

• Power Generation: The use of hydrogen turbines is aiding power plants in achieving grid-stabilizing electricity while moving away from fossil fuel dependency. A German utility company EnBW activated a hydrogen-ready turbine station in Stuttgart-Münster in April 2025, which marks one of the earliest commercial sites in Europe. This facility is structured to progress from natural gas to a hydrogen-only operation over time. Utility companies can now capitalize on their existing infrastructure while still constructing future-ready plants, thus the replicability of hydrogen powered plants in and around EU regions is becoming more apparent.

• Others: Outside of the primary industries, hydrogen turbines are finding new applications in data centers as well as in industrial parks and district heating systems where clean, on-demand power is necessary. In June 2025, China initiated a national hydrogen pilot program with the goal of deploying turbines greater than 10 MW at a variety of facilities. The program intends to utilize more than 1,000 tons of renewable hydrogen fuel per year. These initiatives are designed to promote the use of hydrogen for applications beyond conventional power generation. It supports the emerging role of hydrogen as an energy source for clean industrial energy systems with a decentralized structure.

By Distribution Channel

• Direct Sales: Turbine manufacturers perform direct sales interfacing with end customers like utilities, governmental bodies, or industries during the provisioning of systems and services. The GE Vernova operators became the earliest contractors in Australia for the 100% hydrogen-ready aeroderivative turbines in May 2025 and concurrently reserved the installation and maintenance support services. This method highlights the systematized importance of partner business collaboration during the delivery of remote customized hydrogen turbines on a grid technology adaptation custom hydrogen turbine design.

• Indirect sales: Sales that are specified as indirect sales are through EPC contractors, integrators or other energy equipment distributors, who are selling the turbines as one combined product. This model is popular in regions with complex regulatory frameworks or infrastructural barriers. Southeast Asia and Latin America have been experiencing downstream indirect growth as partners navigate permitting and local sourcing. These pathways expand access to new markets while alleviating strain on OEMs. It facilitates the large-scale deployment of turbines in emerging hydrogen economies.

Impact of Latest Tariff Policies

Recent tariff initiatives announced by the United States and several European nations are already reverberating through the global supply chain for hydrogen gas turbines. Higher duties on turbine components and hydrogen-technology hardware have forced firms to reassess sourcing origins, as escalating import costs are adding substantially to overall project budgets. Ansaldo Energia and Baker Hughes are focusing on regional manufacturing centers that would minimize tariffs. This shift has resulted in an increased focus on domestic production as well as modular assembly, which helps maintain competitiveness within the market. Nonetheless, capital expenditure incurred from these practices could hinder the pace of deployment of hydrogen turbines globally.

Tariffs imposed have also resulted in regional protectionist policies, with the European Union assessing such steps to protect its clean energy market from low-cost imports especially coming out of Asia. These fragmented trade policies are likely to further impede assistance across international borders regarding collaboration and technology transfer concerning hydrogen infrastructure. Countries in Asia-Pacific, particularly India and South Korea, are emerging as alternative hubs of manufacturing to fulfill global demand, however, diverse certification systems alongside border regulations still complicate the effortless exportation of turbines suitable for use with hydrogen fuel. This increasing regional divide will erode global market interoperability and standardization strategies.

The hydrogen gas turbine sector is experiencing innovation and long-term resilience, despite facing a short-term financial burden due to tariffs. To circumvent trade limitations, businesses are enhancing research and development spending to develop cheaper technologies that adhere locally. Such tariff pressures are mitigated by supporting subsidies like the U.S. Both the U.S. Inflation Reduction Act and various European Union hydrogen funding packages are reshaping the economic environment in which firms operate. Gradually, organisations are leaning on digital tools and advanced materials to engineer products that can withstand anticipated market and regulatory fluctuations. In this fast-evolving trade arena, success will depend on each player’s ability to harmonize compliance, control costs, and drive meaningful innovation.

Report Scope

Regional Perspective

The Hydrogen Gas Turbine Market can be divided across different regions such as North America, Europe, Asia-Pacific, and LAMEA. This is a cursory overview of each region:

• North America: The North American hydrogen gas turbine market which includes the USA, Canada, Mexico and other countries is experiencing growth driven by government support, hydrogen hubs, and decarbonization policies. There are large scale projects the US is undertaking with the Department of Energy’s Hydrogen Hubs Program, and Utah’s Intermountain Power Project began green hydrogen integration into turbines in 2024. In Canada, Nu:ionic and HybriGenix launched a 100 MW hydrogen-turbine demonstration plant in Alberta in August 2024. Other regions of Mexico is also looking into the possibility of Hydrogen co-firing for gas fired plants as a mode of decarbonization. Furthermore, GE Vernova and Mitsubishi Power, as well as other OEMs are enhancing their collaborations and expanding the deployment of turbines throughout the region.

• Europe: Europe continues to lead in the adoption of hydrogen turbines due to their stringent climate initiatives coupled with supportive policies. Germany, France, Spain, and the Netherlands are advancing with hydrogen infrastructure to sidestep carbon emissions in electricity generation and manufacturing. France’s HYFLEXPOWER project ran a Siemens SGT‑400 turbine on 100% hydrogen, marking a pioneering achievement in France. With the newly updated National Hydrogen Strategy, Germany hopes to meet the 10 GW electrolyser target alongside its announced 430 MW hydrogen-turbine retrofit in 2025. Spain and Italy are also participants in the EU-wide H₂ corridors with green hydrogen pilot zones that incorporate industrial turbine applications.

• Asia-Pacific: Countries in the Asia-Pacific region including China, Japan, India, South Korea, and Australia are experiencing rapidly increasing adoption of hydrogen turbines due to an expanding industry and clean energy policy. Australia demonstrated a 60% hydrogen-fueled LM2500 aero-derivative turbine in an offshore test in 2025, while India worked on industrial clusters under the National Green Hydrogen Mission framework. Turbine R&D on hydrogen-compatible models is a focus for Japan and South Korea through collaborations with Mitsubishi and Kawasaki. China’s 2025 plan also includes launching a hydrogen pilot using turbines over 10 MW which seeks to promote green power in the region’s manufacturing hubs.

• LAMEA: The LAMEA region is emerging in the hydrogen turbine landscape through focused investments in green hydrogen and power reliability. Brazil formed a national task force in 2023 to promote hydrogen blending in turbines for industrial decarbonization, while Middle Eastern nations like Saudi Arabia and the UAE are developing hydrogen turbine projects linked to desalination and off-grid energy. In May 2024, Turkey launched a hydrogen-powered turbine pilot for combined power and water infrastructure. North African countries such as Morocco and Egypt are planning large-scale renewable hydrogen projects to export electricity and support local industrialization through hydrogen turbine integration by 2025.

Key Developments

In recent years, the Hydrogen Gas Turbine Market has experienced several crucial changes as the players in the market strive to grow their geographical footprint and improve their product line and profits by using synergies.

• In November 2024, At COP29 in Baku, Azerenerji JSC and Ansaldo Energia signed a strategic five-pillar MoU to strengthen Azerbaijan’s energy security and accelerate its transition to clean power. The agreement includes joint efforts to install, modernize, and maintain power generation assets, and to establish a hydrogen production plant using Ansaldo’s electrolyser technology. It also supports the development of hydrogen-fired power plants and hydrogen-based energy storage systems. Additionally, it involves staff training, knowledge exchange, and collaboration on carbon capture and small modular nuclear reactors. Ansaldo committed to purchasing carbon credits from Azerenerji’s hydropower projects. This partnership aims to store renewable energy as hydrogen for use in advanced gas turbines, aligning with Azerbaijan’s net-zero ambitions.

• In December 2024, SSE and Siemens Energy launched “Mission H2 Power,” a multi-million-pound project to develop 100% hydrogen-capable turbine technology for the UK’s net-zero goals. The initiative focuses on decarbonizing SSE’s Keadby 2 Power Station by adapting Siemens’ SGT5-9000HL turbine to run on hydrogen or blended fuels. Testing will take place in Berlin, aiming to make Keadby one of the world’s first major hydrogen-fired power stations by 2030.

Ansaldo Energia, Baker Hughes, Doosan Heavy Industries, and OPRA Turbines are advancing hydrogen-ready turbine technologies. They’re investing in low-NOx systems, AI-driven optimization, and global deployment. These efforts support decarbonization and fuel flexibility. Together, they’re shaping the future of clean power generation.

Leading Players

The Hydrogen Gas Turbine Market is highly competitive, with a large number of product providers globally. Some of the key players in the market include:

• Ansaldo Energia
• Baker Hughes
• Doosan Heavy Industries
• OPRA Turbines
• Kawasaki Heavy Industries Ltd.
• MAN Energy Solutions
• Mitsubishi Power Americas Inc.
• Siemens
• Solar Turbines
• General Electric Gas Power
• Others

These firms apply a sequence of strategies to enter the market, including innovations, mergers and acquisitions, and collaboration.

The global Hydrogen Gas Turbine Market is rapidly evolving, led by companies like Ansaldo Energia, Baker Hughes, Doosan Heavy Industries, and OPRA Turbines. These leaders are investing in hydrogen-compatible turbine systems, low-NOx combustion technologies, and modular turbine platforms. For instance, Ansaldo is developing 100% hydrogen-capable turbines in Italy, while Baker Hughes is deploying its NovaLT units across U.S. hydrogen hubs. Doosan is expanding hydrogen turbine production in South Korea, and OPRA is advancing compact microturbines for decentralized, hydrogen-powered applications. Together, they are driving innovation and efficiency in clean turbine technology.

Regional partnerships are accelerating deployment, with OEMs collaborating with utilities, governments, and industrial users. In Europe, hydrogen-ready turbines are being integrated into steel and power plants. North America is focused on pilot-scale and grid-connected hydrogen turbines, while Asia-Pacific emphasizes utility-scale deployment and export potential. These companies are also supporting local supply chains and workforce development, enabling scalable, region-specific energy transitions.

Diversification is broadening the market, as hydrogen gas turbines find use in steel mills, oil & gas facilities, defense systems, and industrial microgrids. Baker Hughes units now power data centers and remote assets, Doosan’s turbines support petrochemical sites, Ansaldo is active in green steel, and OPRA enables clean, distributed energy in emerging markets. As hydrogen infrastructure expands and ESG goals tighten, turbine leaders are shaping a resilient, zero-carbon energy future.

The Hydrogen Gas Turbine Market is segmented as follows:

By Type

• Turbojet
• Turbofan
• Turboprop
• Turboshaft

By Design Type

• Heavy-duty Gas Turbines
• Aero Derivative Gas Turbines

By H2 Fuel Composition

• Up to 20%
• 20% to 60%
• 60% to 100%

By Application

• Steel Mills
• Oil & Gas
• Aerospace & Defense
• Power Generation
• Others

By Distribution Channel

• Direct Sales
• Indirect Sales

Regional Coverage:

North America

• U.S.
• Canada
• Mexico
• Rest of North America

Europe

• Germany
• France
• U.K.
• Russia
• Italy
• Spain
• Netherlands
• Rest of Europe

Asia Pacific

• China
• Japan
• India
• New Zealand
• Australia
• South Korea
• Taiwan
• Rest of Asia Pacific

The Middle East & Africa

• Saudi Arabia
• UAE
• Egypt
• Kuwait
• South Africa
• Rest of the Middle East & Africa

Latin America

• Brazil
• Argentina
• Rest of Latin America