Satellite Electric Propulsion Market - A Global and Regional Analysis: Focus on Mass Class, Mission Type, Mission Application, Component, and Country - Analysis and Forecast, 2022-2032
Global Satellite Electric Propulsion Market Overview
The global satellite electric propulsion market is estimated to reach $1,027.3 million in 2032 from $522.3 million in 2021, at a growth rate of 4.10% during the forecast period. The satellite electric propulsion technology companies have witnessed the demand from the growing commercial industry. The ecosystem of the satellite propulsion system market comprises system manufacturers, original equipment manufacturers (OEMs), and end users.
Market Lifecycle Stage
Between 1957 and 2021, many governments and commercial organizations such as Ariane Space, Europe Space Agency (ESA), National Aeronautics and Space Administration (NASA), and Japan Aerospace Exploration Agency (JAXA), started demonstrations for the new propulsion system for different satellites in low Earth orbit (LEO). Since then, technology has evolved continually and transformed the entire space industry by developing unique products and systems.
Currently, many space agencies and commercial companies across the globe have been focusing on developing low Earth orbit (LEO) satellite constellations. This would drive the market for the propulsion system. Moreover, rising research and development activities to develop cost-efficient propulsion technologies and advancements in 3D printing technology for developing the components of satellite propulsion systems are other factors contributing to the growth of the LEO-focused satellite propulsion technology market. For instance, in June 2022, ThrustMe signed a contract with European Space Agency (ESA) to provide an NPT30-I2-1.5U electric propulsion system for the GOMX-5 mission under ESA general support technology programme (GSTP).
Impact
- The increasing number of smaller telecom satellites in low Earth orbit (LEO) with the upcoming mega-constellation has placed a high demand for the production of electric propulsion during the forecast period.
- Furthermore, rising research and development activities for building low-cost and efficient propulsion systems for satellites.
- Segmentation 1: by Mass Class
Segmentation 2: by Mission Type
- Earth Observation
- Communication
- Technology Development
- Others
Segmentation 3: by Mission Application
- Station Keeping
- Orbit Raising
Segmentation 4: by Component
- Power Control Units
- Power Distribution Units
- Pointing Mechanism
- Pressure Regulators
- Valves
- Flow Controllers
- Mass Flow Sensors
- Pressure Transducers
- Particle Filters
- Tanks
- Plumbing/Tuning
- Propulsion Chamber/Nozzle
- North America - U.S.
- Europe - France, Germany, Russia, U.K., and Rest-of-Europe
- Asia-Pacific - China, India, and Rest-of-Asia-Pacific
- Rest-of-the-World - Middle East and Africa and South America
Recent Developments in Global Satellite Electric Propulsion Market
- In July 2022, Thales Alenia Space received a contract of $2.4 million from European Space Agency (ESA) to develop Skimsat, a small satellite bus for very low Earth orbit (VLEO). The contract also includes developing electrical propulsion to air drag in VLEO.
- In June 2022, Safran signed a contract with Thales Alenia Space to supply its PPS 5000 plasma thruster for Thales's Galileo satellites.
- In August 2021, Neutron Star Systems (NSS) and Bradford Space signed a cooperative agreement to enhance the orbital transport and maneuver capability. In this agreement, Bradford would combine NSS electric propulsion technology with its green monopropellant technology for its space logistics services.
- In April 2021, ThrustMe was selected by Norwegian Space Agency to provide NPT30-I2 electric propulsion for the NorSat-TD mission. The company would provide collision avoidance maneuver capabilities to the NorSat-TD satellite with its iodine propulsion system.
Following are the drivers for the global satellite electric propulsion market:
- Increasing Demand for Large Constellations for Smaller Telecom Satellites in Low Earth Orbit (LEO)
- Rising Research and Development Activities for Building Low-Cost and Efficient Propulsion Systems for Satellites
- Relatively Low Thrust Nature of Electric Propulsion Systems Impose Longer Timelines for Orbit-Transfer Risking Satellite Exposure to Radiation and Delaying Mission Timelines
- Integration of Electric Propulsion Results in a Growing Power Budget (Imposing the Need for More Onboard Power and the Addition of More Associated Power Electronics)
- Satellite Manufacturers can Achieve Multiple Variants of the Satellite When Utilizing the All-Electric Option Owing to its Scalability Advantage
Product/Innovation Strategy: The product segment helps the reader understand the different types of satellite electric propulsion market available for deployment in the industries for space platforms and their potential globally. Moreover, the study provides the reader with a detailed understanding of the different satellite electric propulsion market by mass class (small satellite (0-500kg), medium satellite (501-2,200kg), and large satellite (2,200 kg and above)), by mission type (earth observation, communication, technology development, and others), by mission application (station keeping and orbit raising), and by component (power control units, power distribution units, pointing mechanism, pressure regulators, valves, flow controllers, mass flow sensors, pressure transducers, particle filters, tanks, plumbing/tuning, propulsion chamber/nozzle).
Growth/Marketing Strategy: The global satellite electric propulsion market has seen major development by key players operating in the market, such as business expansion activities, contracts, mergers, partnerships, collaborations, and joint ventures. The favored strategy for the companies has been contracted to strengthen their position in the global satellite electric propulsion market. For instance, in June 2022, Thales Alenia Space and Telespazio (joint venture of Thales and Leonardo) signed a contract with the Italian Ministry of Defense for the development of SICRAL 3 satellite communications and propulsion system.
Competitive Strategy: Key players in the global satellite electric propulsion market analyzed and profiled in the study involve satellite electric propulsion manufacturers. Moreover, a detailed competitive benchmarking of the players operating in the global satellite electric propulsion market has been done to help the reader understand how players stack against each other, presenting a clear market landscape. Additionally, comprehensive competitive strategies such as contracts, partnerships, agreements, acquisitions, and collaborations will aid the reader in understanding the untapped revenue pockets in the market.
Key Market Players and Competition Synopsis
The companies that are profiled have been selected based on inputs gathered from primary experts and analysis of the company's coverage, product portfolio, and market penetration.
The top segment players leading the market include established players of electric propulsion for satellites and constitute 80% of the presence in the market. Other players include start-up entities that account for approximately 20% of the presence in the market.
Some prominent names established in this market are:
- Accion Systems
- Airbus
- Aliena Pte Ltd.
- ArianeGroup
- Astra
- Busek, Co. Inc.
- CU Aerospace
- ENPULSION GmbH
- Moog Inc.
- Neutron Star Systems
- Northrop Grumman
- Orbion Space Technology
- Phase Four, Inc.
- Safran
- Sitael S.p.A
- Thales Alenia Space
- 1 Markets
- 1.1 Industry Outlook
- 1.1.1 Satellite Electric Propulsion Market: Overview
- 1.1.2 Increasing Deployment of Electric Propulsion in LEO Missions
- 1.1.3 All-Electric Satellite Scenario
- 1.1.4 Evolving Mission Requirements (Ongoing and Upcoming Programs)
- 1.1.4.1 OneWeb Satellite Constellation
- 1.1.4.2 Galileo Satellite Constellation
- 1.1.4.3 Psyche Mission
- 1.1.4.4 Mars Sample Return (MSR) Mission
- 1.1.4.5 Lunar Gateway (Artemis Program)
- 1.1.4.6 Spacety SAR Constellation
- 1.1.5 Emerging Electric Propulsion Technological Trends
- 1.1.5.1 Solar Electric Propulsion
- 1.1.5.2 Electric Iodine Thrusters
- 1.1.5.3 Multi-Modal Electric Propulsion Engine (MEPE)
- 1.1.5.4 Field-Emission Electric Propulsion (FEEP)
- 1.1.5.5 Air-Scooping Electric Propulsion (ASEP)
- 1.1.5.6 Lightweight Amplifiers
- 1.1.6 Startups and Investment Scenarios
- 1.1.7 Leveraging Demand from Serial Production of Satellites for Electric Propulsion System
- 1.2 Business Dynamics
- 1.2.1 Business Drivers
- 1.2.1.1 Increasing Demand for Large Constellations for Smaller Telecom Satellites in Low Earth Orbit (LEO)
- 1.2.1.2 Rising Research and Development Activities for Building Low-Cost and Efficient Propulsion Systems for Satellites
- 1.2.2 Business Challenges
- 1.2.2.1 Relatively Low Thrust Nature of Electric Propulsion Systems Impose Longer Timelines for Orbit-Transfer Risking Satellite Exposure to Radiation and Delaying Mission Timelines
- 1.2.2.2 Integration of Electric Propulsion Results in a Growing Power Budget (Imposing the Need for More Onboard Power and the Addition of More Associated Power Electronics)
- 1.2.3 Business Strategies
- 1.2.3.1 New Product Launches
- 1.2.4 Corporate Strategies
- 1.2.4.1 Partnerships, Collaborations, Agreements, and Contracts
- 1.2.4.2 Mergers and Acquisitions
- 1.2.5 Business Opportunities
- 1.2.5.1 Satellite Manufacturers can Achieve Multiple Variants of the Satellite When Utilizing the All-Electric Option Owing to its Scalability Advantage
- 2 Product
- 2.1 Global Satellite Electric Propulsion Market (by Mass Class)
- 2.1.1 Market Overview
- 2.1.1.1 Demand Analysis for Global Satellite Electric Propulsion Market (by Mass Class), Value and Volume
- 2.1.2 Small Satellite (0-500 Kg)
- 2.1.2.1 Demand Analysis for Global Satellite Electric Propulsion Market (by Small Satellite (0-500 Kg)), Value and Volume
- 2.1.3 Medium Satellite (501-2,200 Kg)
- 2.1.4 Large Satellite (Above 2,201 Kg)
- 2.2 Global Satellite Electric Propulsion Market (by Mission Type)
- 2.2.1 Market Overview
- 2.2.1.1 Demand Analysis for Global Satellite Electric Propulsion Market (by Mission Type), Value and Volume
- 2.2.2 Earth Observation
- 2.2.3 Communication
- 2.2.4 Technology Development
- 2.2.5 Others
- 2.3 Global Satellite Electric Propulsion Market (by Mission Application)
- 2.3.1 Market Overview
- 2.3.1.1 Demand Analysis for Global Satellite Electric Propulsion Market (by Mission Application), Value and Volume
- 2.3.2 Station Keeping
- 2.3.3 Orbit Raising
- 2.4 Global Satellite Electric Propulsion Market (by Component)
- 2.4.1 Market Overview
- 2.4.1.1 Demand Analysis for Global Satellite Electric Propulsion Market (by Component), Value and Volume
- 2.4.2 Power Control Units
- 2.4.3 Power Distribution Units
- 2.4.4 Pointing Mechanism
- 2.4.5 Pressure Regulators
- 2.4.6 Valves
- 2.4.7 Flow Controllers
- 2.4.8 Mass Flow Sensors
- 2.4.9 Pressure Transducers
- 2.4.10 Particle Filters
- 2.4.11 Tanks
- 2.4.12 Plumbing/Tubing
- 2.4.13 Propulsion Chamber/Nozzle
- 3 Region
- 3.1 Global Satellite Electric Propulsion Market (by Region)
- 3.2 North America
- 3.2.1 Market
- 3.2.1.1 Key Manufacturers and Service Providers in North America
- 3.2.1.2 Business Drivers
- 3.2.1.3 Business Challenges
- 3.2.2 Product
- 3.2.2.1 North America Satellite Electric Propulsion Market (by Mission Application)
- 3.2.3 North America (by Country)
- 3.2.3.1 U.S.
- 3.2.3.1.1 Market
- 3.2.3.1.1.1 Key Manufacturers and Service Providers in the U.S.
- 3.2.3.1.2 Product
- 3.2.3.1.2.1 U.S. Satellite Electric Propulsion Market (by Mission Application)
- 3.3 Europe
- 3.3.1 Market
- 3.3.1.1 Key Manufacturers and Service Providers in Europe
- 3.3.1.2 Business Drivers
- 3.3.1.3 Business Challenges
- 3.3.2 Product
- 3.3.2.1 Europe Satellite Electric Propulsion Market (by Mission Application)
- 3.3.3 Europe (by Country)
- 3.3.3.1 France
- 3.3.3.1.1 Market
- 3.3.3.1.1.1 Key Manufacturers and Service Providers in France
- 3.3.3.1.2 Product
- 3.3.3.1.2.1 France Satellite Electric Propulsion Market (by Mission Application)
- 3.3.3.2 Germany
- 3.3.3.2.1 Key Manufacturers and Service Providers in Germany
- 3.3.3.2.2 Product
- 3.3.3.2.2.1 Germany Satellite Electric Propulsion Market (by Mission Application)
- 3.3.3.3 Russia
- 3.3.3.3.1 Product
- 3.3.3.3.1.1 Russia Satellite Electric Propulsion Market (by Mission Application)
- 3.3.3.4 U.K.
- 3.3.3.4.1 Product
- 3.3.3.4.1.1 U.K. Satellite Electric Propulsion Market (by Mission Application)
- 3.3.3.5 Rest-of-Europe
- 3.3.3.5.1 Market
- 3.3.3.5.1.1 Key Manufacturers and Service Providers in the Rest-of-Europe
- 3.3.3.5.2 Product
- 3.3.3.5.2.1 Rest-of-Europe Satellite Electric Propulsion Market (by Mission Application)
- 3.4 Asia-Pacific
- 3.4.1 Market
- 3.4.1.1 Key Manufacturers and Service Providers in Asia-Pacific
- 3.4.1.2 Business Drivers
- 3.4.1.3 Business Challenges
- 3.4.1.3.1 Product
- 3.4.1.3.1.1 Asia-Pacific Satellite Electric Propulsion Market (by Mission Application)
- 3.4.2 Asia-Pacific (by Country)
- 3.4.2.1 China
- 3.4.2.1.1 Product
- 3.4.2.1.1.1 China Satellite Electric Propulsion Market (by Mission Application)
- 3.4.2.2 India
- 3.4.2.2.1 Product
- 3.4.2.2.1.1 India Satellite Electric Propulsion Market (by Mission Application)
- 3.4.2.3 Rest-of-Asia-Pacific
- 3.4.2.3.1 Product
- 3.4.2.3.1.1 Rest-of-Asia-Pacific Satellite Electric Propulsion Market (by Mission Application)
- 3.5 Rest-of-the-World
- 3.5.1 Market
- 3.5.1.1 Business Drivers
- 3.5.1.2 Business Challenges
- 3.5.1.2.1 Product
- 3.5.1.2.1.1 Rest-of-the-World Satellite Electric Propulsion Market (by Mission Application)
- 3.5.2 Rest-of-the-World (by Country)
- 3.5.2.1 Middle East and Africa
- 3.5.2.1.1 Product
- 3.5.2.1.1.1 Middle East and Africa Satellite Electric Propulsion Market (by Mission Application)
- 3.5.2.2 South America
- 3.5.2.2.1 Product
- 3.5.2.2.1.1 South America Satellite Electric Propulsion Market (by Mission Application)
- 4 Market – Competitve Benchmarking & Company Profiles
- 4.1 Competitive Benchmarking
- 4.2 Accion Systems
- 4.2.1 Company Overview
- 4.2.1.1 Role of Accion Systems in the Global Satellite Electric Propulsion Market
- 4.2.1.2 Product Portfolio
- 4.2.2 Corporate Strategies
- 4.2.2.1 Partnerships, Agreements, and Contracts
- 4.2.3 Analyst View
- 4.3 Airbus
- 4.3.1 Company Overview
- 4.3.1.1 Role of Airbus in the Global Satellite Electric Propulsion Market
- 4.3.1.2 Product Portfolio
- 4.3.2 Corporate Strategies
- 4.3.2.1 Contracts
- 4.3.3 R&D Analysis
- 4.3.4 Analyst View
- 4.4 Aliena Pte Ltd.
- 4.4.1 Company Overview
- 4.4.1.1 Role of Aliena Pte Ltd. in the Global Satellite Electric Propulsion Market
- 4.4.1.2 Product Portfolio
- 4.4.2 Corporate Strategies
- 4.4.2.1 Agreements, Collaborations, and Contracts
- 4.4.3 Analyst View
- 4.5 ArianeGroup
- 4.5.1 Company Overview
- 4.5.1.1 Role of ArianeGroup in the Global Satellite Electric Propulsion Market
- 4.5.1.2 Product Portfolio
- 4.5.2 Analyst View
- 4.6 Astra
- 4.6.1 Company Overview
- 4.6.1.1 Role of Astra in the Global Satellite Electric Propulsion Market
- 4.6.1.2 Product Portfolio
- 4.6.2 Corporate Strategies
- 4.6.2.1 Acquisitions and Contracts
- 4.6.3 R&D Analysis
- 4.6.4 Analyst View
- 4.7 Busek, Co. Inc.
- 4.7.1 Company Overview
- 4.7.1.1 Role of Busek, Co. Inc. in the Global Satellite Electric Propulsion Market
- 4.7.1.2 Product Portfolio
- 4.7.2 Corporate Strategies
- 4.7.2.1 Collaborations
- 4.7.3 Analyst View
- 4.8 CU Aerospace
- 4.8.1 Company Overview
- 4.8.1.1 Role of CU Aerospace in the Global Satellite Electric Propulsion Market
- 4.8.1.2 Product Portfolio
- 4.8.2 Corporate Strategies
- 4.8.2.1 Collaborations
- 4.8.3 Analyst View
- 4.9 ENPULSION GmbH
- 4.9.1 Company Overview
- 4.9.1.1 Role of ENPULSION GmbH in the Global Satellite Electric Propulsion Market
- 4.9.1.2 Product Portfolio
- 4.9.2 Corporate Strategies
- 4.9.2.1 Partnerships, Collaborations, Agreements, Investments, and Contracts
- 4.9.3 Analyst View
- 4.1 Moog Inc.
- 4.10.1 Company Overview
- 4.10.1.1 Role of Moog Inc. in the Global Satellite Electric Propulsion Market
- 4.10.1.2 Product Portfolio
- 4.10.2 R&D Analysis
- 4.10.3 Analyst View
- 4.11 Neutron Star Systems
- 4.11.1 Company Overview
- 4.11.1.1 Role of Neutron Star Systems in the Global Satellite Electric Propulsion Market
- 4.11.1.2 Product Portfolio
- 4.11.2 Corporate Strategies
- 4.11.2.1 Agreements
- 4.11.3 Analyst View
- 4.12 Northrop Grumman
- 4.12.1 Company Overview
- 4.12.1.1 Role of Northrop Grumman in the Global Satellite Electric Propulsion Market
- 4.12.1.2 Product Portfolio
- 4.12.2 Corporate Strategies
- 4.12.2.1 Agreements
- 4.12.3 R&D Analysis
- 4.12.4 Analyst View
- 4.13 Orbion Space Technology
- 4.13.1 Company Overview
- 4.13.1.1 Role of Orbion Space Technology in the Global Satellite Electric Propulsion Market
- 4.13.1.2 Product Portfolio
- 4.13.2 Corporate Strategies
- 4.13.2.1 Contracts
- 4.13.3 Analyst View
- 4.14 Phase Four, Inc.
- 4.14.1 Company Overview
- 4.14.1.1 Role of Phase Four, Inc. in the Global Satellite Electric Propulsion Market
- 4.14.1.2 Product Portfolio
- 4.14.2 Corporate Strategies
- 4.14.2.1 Contracts
- 4.14.3 Analyst View
- 4.15 Safran
- 4.15.1 Company Overview
- 4.15.1.1 Role of Safran in the Global Satellite Electric Propulsion Market
- 4.15.1.2 Product Portfolio
- 4.15.2 Corporate Strategies
- 4.15.2.1 Contracts
- 4.15.3 R&D Analysis
- 4.15.4 Analyst View
- 4.16 Sitael S.p.A
- 4.16.1 Company Overview
- 4.16.1.1 Role of Sitael S.p.A in the Global Satellite Electric Propulsion Market
- 4.16.1.2 Product Portfolio
- 4.16.2 Corporate Strategies
- 4.16.2.1 Partnerships and Collaborations
- 4.16.3 Analyst View
- 4.17 Thales Alenia Space
- 4.17.1 Company Overview
- 4.17.1.1 Role of Thales Alenia Space in the Global Satellite Electric Propulsion Market
- 4.17.1.2 Product Portfolio
- 4.17.2 Corporate Strategies
- 4.17.2.1 Contracts
- 4.17.3 Analyst View
- 4.18 Other Key Players
- 4.18.1 ThrustMe
- 4.18.1.1 Company Overview
- 4.18.2 Bellatrix Aerospace
- 4.18.2.1 Company Overview
- 5 Growth Opportunities and Recommendations
- 5.1 Growth Opportunities
- 5.1.1 Recommendations
- 5.1.2 Growth Opportunity: Demand for Scalable Solutions
- 5.1.2.1 Recommendations
- 5.1.3 Growth Opportunity: Benefit for Small Satellite Operators
- 5.1.3.1 Recommendations
- 6 Research Methodology
- 6.1 Factors for Data Prediction and Modeling
- List of Figures
- Figure 1: Global Satellite Electric Propulsion Market, Units, 2021-2032
- Figure 2: Global Satellite Electric Propulsion Market, $Million, 2021-2032
- Figure 3: Global Satellite Electric Propulsion Market (by Mass Class), Units, 2021 and 2032
- Figure 4: Global Satellite Electric Propulsion Market (by Mass Class), $Million, 2021 and 2032
- Figure 5: Global Satellite Electric Propulsion Market (by Mission Application), Units, 2021 and 2032
- Figure 6: Global Satellite Electric Propulsion Market (by Mission Application), $Million, 2021 and 2032
- Figure 7: Global Satellite Electric Propulsion Market (by Component), $Million, 2021 and 2032
- Figure 8: Global Satellite Electric Propulsion Market (by Mission Type), Value, 2021 and 2032
- Figure 9: Global Satellite Electric Propulsion Market (by Region), $Million, 2032
- Figure 10: Satellite Electric Propulsion Market Coverage
- Figure 11: LEO-Based Small Satellite Scenario (0-500 kg), Number of Launches, 2022-2032
- Figure 12: Global Satellite Electric Propulsion Market, Business Dynamics
- Figure 13: Share of Key Business Strategies and Developments, January 2020-August 2022
- Figure 14: Global Satellite Electric Propulsion Market, Competitive Benchmarking
- Figure 15: Airbus: R&D Analysis, $Million, 2019-2021
- Figure 16: Astra: R&D Analysis, $Million, 2020 and 2021
- Figure 17: Moog Inc.: R&D Analysis, $Million, 2019-2021
- Figure 18: Northrop Grumman: R&D Analysis, $Million, 2019-2021
- Figure 19: Safran: R&D Analysis, $Million, 2019-2021
- Figure 20: Research Methodology
- Figure 21: Top-Down and Bottom-Up Approach
- Figure 22: Assumptions and Limitations
- List of Tables
- Table 1: All-Electric Satellites’ List
- Table 2: Startups and Investment Scenarios
- Table 3: New Product Launches, January 2020-August 2022
- Table 4: Partnerships, Collaborations, Agreements, and Contracts, January 2020-August 2022
- Table 5: Mergers and Acquisitions, January 2020-August 2022
- Table 6: Global Satellite Electric Propulsion Market (by Mass Class), Value ($Million) and Volume (Unit), 2021-2032
- Table 7: Global Satellite Electric Propulsion Market (by Small Satellite (0-500 Kg)), Value ($Million) and Volume (Unit), 2021-2032
- Table 8: Global Satellite Electric Propulsion Market (by Mission Type), Value ($Million) and Volume (Unit), 2021-2032
- Table 9: Global Satellite Electric Propulsion Market (by Mission Application), Value ($Million) and Volume (Unit), 2021-2032
- Table 10: Global Satellite Electric Propulsion Market (by Components), Value ($Million) and Volume (Unit), 2021-2032
- Table 11: Satellite Electric Propulsion Market (by Region), $Million and Units, 2021-2032
- Table 12: North America Satellite Electric Propulsion Market (by Mission Application), $Million and Units, 2021-2032
- Table 13: U.S. Satellite Electric Propulsion Market (by Mission Application), $Million and Units, 2021-2032
- Table 14: Europe Satellite Electric Propulsion Market (by Mission Application), $Million and Units, 2021-2032
- Table 15: France Satellite Electric Propulsion Market (by Mission Application), $Million and Units, 2021-2032
- Table 16: Germany Satellite Electric Propulsion Market (by Mission Application), $Million and Units, 2021-2032
- Table 17: Russia Satellite Electric Propulsion Market (by Mission Application), $Million and Units, 2021-2032
- Table 18: U.K. Satellite Electric Propulsion Market (by Mission Application), $Million and Units, 2021-2032
- Table 19: Rest-of-Europe Satellite Electric Propulsion Market (by Mission Application), $Million and Units, 2021-2032
- Table 20: Asia-Pacific Satellite Electric Propulsion Market (by Mission Application), $Million and Units, 2021-2032
- Table 21: China Satellite Electric Propulsion Market (by Mission Application), $Million and Units, 2021-2032
- Table 22: India Satellite Electric Propulsion Market (by Mission Application), $Million and Units, 2021-2032
- Table 23: Rest-of-Asia-Pacific Satellite Electric Propulsion Market (by Mission Application), $Million and Units, 2021-2032
- Table 24: Rest-of-the-World Satellite Electric Propulsion Market (by Mission Application), $Million and Units, 2021-2032
- Table 25: Middle East and Africa Satellite Electric Propulsion Market (by Mission Application), $Million and Units, 2021-2032
- Table 26: South America Satellite Electric Propulsion Market (by Mission Application), $Million and Units, 2021-2032
- Table 27: Benchmarking and Weightage Parameters
- Table 28: Accion Systems: Product Portfolio
- Table 29: Accion Systems: Partnerships, Agreements, and Contracts
- Table 30: Airbus: Product Portfolio
- Table 31: Airbus: Contracts
- Table 32: Aliena Pte Ltd.: Product Portfolio
- Table 33: Aliena Pte Ltd.: Agreements, Collaboration, and Contracts
- Table 34: ArianeGroup: Product Portfolio
- Table 35: Astra: Product Portfolio
- Table 36: Astra: Acquisitions and Contracts
- Table 37: Busek, Co. Inc.: Product Portfolio
- Table 38: Busek, Co. Inc.: Collaborations
- Table 39: CU Aerospace: Product Portfolio
- Table 40: CU Aerospace: Collaborations
- Table 41: ENPULSION GmbH: Product Portfolio
- Table 42: ENPULSION GmbH: Partnerships, Collaborations, Agreements, Investments, and Contracts
- Table 43: Moog Inc.: Product Portfolio
- Table 44: Neutron Star Systems: Product Portfolio
- Table 45: Neutron Star Systems: Agreements
- Table 46: Northrop Grumman: Product Portfolio
- Table 47: Northrop Grumman: Agreements
- Table 48: Orbion Space Technology: Product Portfolio
- Table 49: Orbion Space Technology: Contracts
- Table 50: Phase Four, Inc.: Product Portfolio
- Table 51: Phase Four, Inc.: Contracts
- Table 52: Safran: Product Portfolio
- Table 53: Safran: Contracts
- Table 54: Sitael S.p.A: Product Portfolio
- Table 55: Sitael S.p.A: Partnerships and Collaborations
- Table 56: Thales Alenia Space: Product Portfolio
- Table 57: Thales Alenia Space: Contracts
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