startpac

https://startpac.com/blog/propulsion-system/

[1] Propulsion System: An Overview of Types of Propulsion Systems — These include internal combustion engines, gas turbine engines, electric propulsion systems, and rocket propulsion systems. Jet propulsion systems are commonly used in aircraft, utilizing air-breathing engines to generate thrust. This clean and efficient propulsion system offers a promising alternative to conventional internal combustion engines, particularly for vehicles like cars, buses, and trucks. Understanding “what is a propulsion system” and the various types of propulsion systems is key to appreciating how different engines and motors help power our world. From the everyday reliability of internal combustion engines to the innovative efficiency of electric propulsion systems, each propulsion system has its unique benefits and applications. Gas turbine engines and rocket propulsion systems provide the necessary high thrust and power requirements for aircraft and space travel, respectively.

nasa

https://www.grc.nasa.gov/WWW/k-12/airplane/bgp.html

[2] Beginner's Guide to Propulsion - NASA — Welcome to the Beginner's Guide to Propulsion: What is propulsion? The word is derived from two Latin words: pro meaning before or forwards and pellere meaning to drive.Propulsion means to push forward or drive an object forward. A propulsion system is a machine that produces thrust to push an object forward. On airplanes, thrust is usually generated through some application of Newton's third

nasa

https://www1.grc.nasa.gov/beginners-guide-to-aeronautics/propulsion-system/

[3] Propulsion System | Glenn Research Center | NASA — Propulsion System | Glenn Research Center | NASA The propulsion of a rocket includes all of the parts which make up the rocket engine, the tanks pumps, propellants, power head and rocket nozzle. Rocket Engine Turbine engines and propellers use air from the atmosphere as the working fluid, but rockets use the combustion exhaust gases. This explains why a rocket works in space but a turbine engine or a propeller does not work. With a liquid rocket, you can stop the thrust by turning off the flow of propellants; but with a solid rocket, you have to destroy the casing to stop the engine. Optional: Enter your name and email if you would like to be contacted about your feedback.

britannica

https://www.britannica.com/technology/rocket-jet-propulsion-device-and-vehicle/Development-of-rockets

[4] Rocket - Propulsion, Jet, Vehicle | Britannica — Rocket - Propulsion, Jet, Vehicle: The technology of rocket propulsion appears to have its origins in the period 1200-1300 in Asia, where the first "propellant" (a mixture of saltpetre, sulfur, and charcoal called black powder) had been in use for about 1,000 years for other purposes. As is so often the case with the development of technology, the early uses were primarily military.

sciencedirect

https://www.sciencedirect.com/science/article/pii/S0306261917302684

[5] Thermodynamic analysis of a gas turbine engine with a rotating ... — From the gas turbine engine perspective, the specific fuel consumption have been improved thanks to higher propulsive and thermal efficiency. ... Thermodynamic comparison between an ideal constant pressure cycle (Joule) and a pressure gain cycle (detonation). (a) ... The compressor efficiency was set at 0.85 in both engines and the sub-sonic

mit

http://web.mit.edu/16.unified/www/FALL/thermodynamics/notes/node85.html

[8] 11 . 6 Performance of Jet Engines - MIT — 11. 6 Performance of Jet Engines. In Chapter 3 we represented a gas turbine engine using a Brayton cycle and derived expressions for efficiency and work as functions of the temperature at various points in the cycle. In this section we will perform further ideal cycle analysis to express the thrust and fuel efficiency of engines in terms of

mechanictimes

https://mechanictimes.com/jet-engine-vs-rocket-engine-understanding-the-differences/

[11] Jet Engine vs. Rocket Engine: Understanding the Differences — The major difference between jet and rocket propulsion is the oxidizer. Jet propulsion uses atmospheric oxygen as the oxidizer, while rocket propulsion uses an in-built oxidizer. Which is faster, a rocket or a jet? A rocket is faster than a jet due to the extremely high velocity of the ejection of mass.

thisvsthat

https://thisvsthat.io/jet-engine-vs-rocket-engine

[12] Jet Engine vs. Rocket Engine - What's the Difference? | This vs. That — Jet engines and rocket engines are both types of propulsion systems used in aircraft and spacecraft. However, they differ in their working principles and applications. Jet engines rely on the intake of air, which is compressed and mixed with fuel before being ignited.

sciencedirect

https://www.sciencedirect.com/science/article/pii/S0376042123000167

[16] Recent innovations to advance space electric propulsion technologies — The innovations in the present space propulsion technologies include enhancing the plasma control in the electric propulsion (EP) thrusters, introduction of new control mechanisms, the utilization of alternative propellants to xenon, to address the requirements of the recently emerged missions. While many types of space EP systems are mature and active in space, significant progress is still required to address the new tasks and challenges that emerged recently, such as plans for Mars and Moon exploration , building huge satellite constellations such as Starlink and OneWeb [, , ], advanced astrophysical studies including space-based gravitational wave detection systems [, , , ], precise astrophysical and astronomical measurements in space [, , ], search for life on exoplanets , and others. To enhance the efficiency of the thrusters via innovative, not yet explored physical principles and technological approaches that were recently demonstrated in labs or conceptualised for the application in space propulsion systems;

orbitaltoday

https://orbitaltoday.com/2023/11/07/nasa-is-testing-aeps-the-worlds-most-powerful-electric-engine-for-gateway/

[19] NASA is testing AEPS, the world's most powerful electric engine for ... — Recently, qualification tests for the new experimental Advanced Electric Propulsion System were conducted at NASA's research centre in Cleveland. AEPS shows great potential in heralding a new era of lunar and Martian exploration. NASA's AEPS advantages and testing. Advanced Electric Propulsion System (AEPS) is expected to be nearly three times more powerful than Hall's present cutting

researchgate

https://www.researchgate.net/publication/389568521_Challenges_and_Innovations_in_Electric_Propulsion_Systems_for_Space_Transportation_A_Comprehensive_Review

[34] (PDF) Challenges and Innovations in Electric Propulsion Systems for ... — Traditional electric propulsion systems fac e efficiency issues, uneven current distribution in RF plasma thrusters, and challenges with magnetic field variability affecting thruster stability. [ 94 ]

cosmoscience

https://cosmoscience.in/evolution-of-rocket-propulsion-systems/

[47] Evolution of rocket propulsion systems - Cosmo Science — Evolution of rocket propulsion systems - Cosmo Science | Explore the Universe | Space Exploration Although the V-2 was a weapon of destruction, its technological advancements in rocket propulsion, guidance, and control systems were instrumental in later space exploration efforts. While green propulsion is still in the early stages of widespread adoption, its development is a critical step toward making space exploration more sustainable and reducing the long-term environmental impact of rocket launches, both on Earth and in orbit. As technology continues to advance, the future of rocket propulsion holds the promise of even greater achievements, including the potential for human settlement on other planets, interstellar exploration, and the realization of the dream of space-faring civilizations.

spacemesmerise

https://spacemesmerise.com/en-us/blogs/space-exploration/the-evolution-of-rocket-technology-from-gunpowder-to-modern-propulsion-systems

[49] The Evolution of Rocket Technology: From Gunpowder to Modern Propulsion ... — The Evolution of Rocket Technology: From Gunpowder to Modern Propulsion Systems Over time, rocket technology developed and expanded, leading to the development of larger and more powerful rockets that would be used for space exploration and military purposes. Development of Rocket Propulsion Systems These missiles were used as weapons but also had significant implications for space exploration because they relied on rocket technology. In this section we will explore some areas where rocket technology is likely to develop: As rocket technology continues to evolve, scientists and engineers are exploring new ways to improve propulsion systems. In the 20th century, rocket technology was used for space exploration.

twz

https://www.twz.com/the-v-2-rocket-rise-to-the-space-race-and-cold-war-missiles

[51] The V-2 Rocket: Rise Of The Space Race And Cold War Missiles - The War Zone — The impact of this post-war exploitation was felt most directly throughout the fifteen or so years following the end of the war. It was during this period that the missile truly came of age, eclipsing the large aerial bomber as the principal method of delivery for both high explosive conventional payloads and atomic warheads.

orbitshub

https://orbitshub.com/v-2-rocket-pioneering-space-exploration-in-the-post-war-era/

[52] V-2 Rocket: Pioneering Space Exploration in the Post-War Era — A Race to the Stars: The V-2's Influence on the Space Race. The aftermath of World War II saw a scramble for captured V-2 technology. The Americans and the Soviets recognized the V-2's potential as a launch vehicle for scientific exploration. This newfound focus on space exploration marked the beginning of the Space Race.

questionai

https://www.questionai.com/essays-ecIV0Rmw8Q5/v2-rocket-dawn-space-age-technological-turning-point

[53] The V2 Rocket and the Dawn of the Space Age: A Technological Turning ... — Finally, the V2's legacy is intertwined with the history of the space race, as many of the engineers and scientists who worked on the V2 program later played key roles in the development of American space exploration.The V2 rocket, despite its dark origins and destructive purpose, played a pivotal role in shaping the future of science and space

space

https://www.space.com/v2-rocket

[54] V2 rocket: Origin, history and spaceflight legacy | Space — The V2 rocket was the world's first large-scale liquid-propellant rocket, developed between 1936 and 1942 in Nazi Germany. It is regarded as a revolutionary breakthrough in rocket technology, with

techwebtrends

https://techwebtrends.com/space-technology/advancements-in-propulsion-systems-for-deep-space-exploration-20391/

[55] Advancements in Propulsion Systems for Deep Space Exploration — Advancements in Propulsion Systems for Deep Space Exploration - TechWeb Trends Recent advancements, particularly in electric propulsion, nuclear thermal propulsion, and novel concepts like pulsed plasma rockets, are pushing the boundaries of what’s possible in space travel. Electric propulsion (EP) systems have emerged as a key technology for deep space missions, offering a significant leap in efficiency over traditional chemical rockets. Electric propulsion systems, while efficient, are still limited by the availability of power in deep space, where solar energy is scarce. | viewed_cookie_policy | 11 months | The cookie is set by the GDPR Cookie Consent plugin and is used to store whether or not user has consented to the use of cookies.

tsijournals

https://www.tsijournals.com/articles/advancements-in-space-propulsion-technologies-from-chemical-to-nuclear-and-beyond.pdf

[56] PDF — Electric propulsion: The future of deep space exploration While nuclear propulsion offers significant advancements in efficiency and power, electric propulsion is emerging as a leading candidate for long-duration deep space missions. Electric propulsion, which includes ion and Hall Effect thrusters, uses electricity

sciencedirect

https://www.sciencedirect.com/science/article/pii/S0376042123000167

[57] Recent innovations to advance space electric propulsion technologies — The innovations in the present space propulsion technologies include enhancing the plasma control in the electric propulsion (EP) thrusters, introduction of new control mechanisms, the utilization of alternative propellants to xenon, to address the requirements of the recently emerged missions. While many types of space EP systems are mature and active in space, significant progress is still required to address the new tasks and challenges that emerged recently, such as plans for Mars and Moon exploration , building huge satellite constellations such as Starlink and OneWeb [, , ], advanced astrophysical studies including space-based gravitational wave detection systems [, , , ], precise astrophysical and astronomical measurements in space [, , ], search for life on exoplanets , and others. To enhance the efficiency of the thrusters via innovative, not yet explored physical principles and technological approaches that were recently demonstrated in labs or conceptualised for the application in space propulsion systems;

newspaceeconomy

https://newspaceeconomy.ca/2023/11/14/global-collaboration-in-space-benefits-and-challenges/

[58] Global Collaboration in Space: Benefits and Challenges — Global Collaboration in Space: Benefits and Challenges | New Space Economy HomePolicy, Law, and RegulationGlobal Collaboration in Space: Benefits and Challenges Global Collaboration in Space: Benefits and Challenges This collaboration, encompassing a myriad of activities from manned space missions to scientific research and satellite deployments, offers significant benefits while also posing unique challenges. Benefits of Global Collaboration in Space Cost Sharing and Financial Efficiency: Space missions, especially those involving human spaceflight or deep space exploration, entail substantial costs. Challenges of Global Collaboration in Space Despite these challenges, the future of space exploration is increasingly collaborative. Global collaboration in space presents a complex mix of benefits and challenges. Space Economy Space Exploration About New Space Economy

thermal-engineering

https://www.thermal-engineering.org/thermodynamic-modeling-of-gas-turbines/

[109] Thermodynamic modeling of gas turbines - Thermal Engineering — The waste heat from the gas turbine is utilized to generate steam, which in turn drives the steam turbine, enhancing overall efficiency. Modeling the Thermodynamics of Gas Turbines The thermodynamic performance of a gas turbine can be modeled using several approaches that help predict its efficiency and output.

asme

https://asmedigitalcollection.asme.org/gasturbinespower/article/147/2/021013/1203039/A-Comprehensive-Thermodynamic-Analysis-of-Gas

[110] A Comprehensive Thermodynamic Analysis of Gas Turbine Combined Cycles ... — Abstract. The paper describes a comprehensive thermodynamic analysis of the gas turbine combined cycle (CC) equipped with pressure gain combustion (PGC) based on the Humphrey cycle. PGC is represented by a steady-state zero-dimensional constant volume combustion (CVC) model with practical loss models for a realistic interpretation. Simulations were performed in WTEMP (web-based thermo-economic

mdpi

https://www.mdpi.com/2411-5134/3/2/33

[111] The Thermodynamics of Internal Combustion Engines: Examples of ... - MDPI — A major goal of the development of internal combustion (IC) engines continues to be higher performance and efficiencies. A major aspect of achieving higher performance and efficiencies is based on fundamental thermodynamics. Both the first and second laws of thermodynamics provide strategies for and limits to the thermal efficiencies of engines. The current work provides three examples of the

modern-physics

https://modern-physics.org/otto-cycle/

[112] Otto Cycle | Efficiency, Stages & Thermodynamic Principles — Its efficiency and operational principles are fundamental to the design and functionality of modern internal combustion engines. Despite its maturity, the Otto cycle continues to evolve, with ongoing research and development focusing on improving efficiency and reducing environmental impact.

sciencedirect

https://www.sciencedirect.com/science/article/pii/S0196890412000210

[113] The thermodynamic characteristics of high efficiency, internal ... — The thermodynamics of an automotive engine are determined using a cycle simulation. The net indicated thermal efficiency increased from 37.0% to 53.9%. High compression ratio, lean mixtures and high EGR were the important features. Efficiency increased due to lower heat losses, and increased work conversion. The nitric oxides were essentially zero due to the low combustion temperatures.

aviationweek

https://aviationweek.com/special-topics/sustainability/what-are-electric-propulsion-challenges-commercial-aviation

[120] What Are The Electric-Propulsion Challenges In Commercial Aviation? — The first all-electric aircraft are using voltages of up to about 500; however, designers who are looking at megawatt-class electrified-propulsion systems for single-aisle airliners are talking

princeton

https://mae.princeton.edu/sites/default/files/ChoueiriHistJPC04.pdf

[122] PDF — Indeed, the history of elec-tric propulsion (EP), which now spans almost a full century, particularly lends itself to a subdivision that epitomizes the progress of the field from its start as the dream realm of a few visionaries, to its transfor-mation into the concern of large corporations.

techwebtrends

https://techwebtrends.com/space-technology/advancements-in-propulsion-systems-for-deep-space-exploration-20391/

[125] Advancements in Propulsion Systems for Deep Space Exploration — Advancements in Propulsion Systems for Deep Space Exploration - TechWeb Trends Recent advancements, particularly in electric propulsion, nuclear thermal propulsion, and novel concepts like pulsed plasma rockets, are pushing the boundaries of what’s possible in space travel. Electric propulsion (EP) systems have emerged as a key technology for deep space missions, offering a significant leap in efficiency over traditional chemical rockets. Electric propulsion systems, while efficient, are still limited by the availability of power in deep space, where solar energy is scarce. | viewed_cookie_policy | 11 months | The cookie is set by the GDPR Cookie Consent plugin and is used to store whether or not user has consented to the use of cookies.

researchgate

https://www.researchgate.net/publication/384019582_Review_on_Past_Present_and_Future_Rocket_Propulsion_Technologies

[126] Review on Past, Present and Future Rocket Propulsion Technologies — higher efficiency, longer lifespan, and greate r speeds compared to traditional chemical rockets. For instance, ion propulsion systems, which use electric power to ionize and accelerate propellant

modern-physics

https://modern-physics.org/rocket-propulsion/

[127] Rocket Propulsion | Thrust, Dynamics & Efficiency - modern-physics.org — These rockets are designed to return to Earth, land vertically, and be prepared for subsequent launches, a stark contrast to traditional rockets that are discarded after a single use. Efficiency and Environmental Considerations. Efficiency in rocket propulsion not only pertains to fuel utilization but also encompasses environmental considerations.

jetir

https://www.jetir.org/papers/JETIR2411547.pdf

[128] PDF — Although electrical propulsion produces low thrust, it is highly © 2024 JETIR November 2024, Volume 11, Issue 11 www.jetir.org (ISSN-2349-5162) JETIR2411546 Journal of Emerging Technologies and Innovative Research (JETIR) www.jetir.org f431 efficient, allowing spacecraft to achieve high velocities over long periods, making it ideal for deep-space missions. Propulsion System Efficiency Thrust Typical Application Limitations Chemical Low High Launch, military, aviation High fuel mass, limited duration Electrical High Low Deep-space missions Low thrust, requires high power Nuclear High Moderate-High Long-duration, deep-space Safety concerns, complex technology Hybrid Moderate-High Variable Versatile mission profiles Complexity, system integration issues © 2024 JETIR November 2024, Volume 11, Issue 11 www.jetir.org (ISSN-2349-5162) JETIR2411546 Journal of Emerging Technologies and Innovative Research (JETIR) www.jetir.org f434 Comparative analysis of different propulsion systems with formula and their minimum and maximum range.

propulsiontechjournal

https://propulsiontechjournal.com/index.php/journal/article/view/8010

[129] Advancements in Propulsion Systems for Rocket Engines: A Review — Advancements in Propulsion Systems for Rocket Engines: A Review | Tuijin Jishu/Journal of Propulsion Technology Articles Advancements in Propulsion Systems for Rocket Engines: A Review Article Sidebar Main Article Content Propulsion systems for rocket engines utilize it, emphasizing significant breakthroughs and their impact on space missions. Recent advancements in propulsion systems encompass a wide range of factors, such as propulsion techniques, engine configurations, materials, and control mechanisms. Additionally, researchers have focused their efforts on advancing reusable rocket technologies to lower launching costs and increase space availability. Recent advancements in rocket engine propulsion technologies have expanded the limits of space exploration, providing unparalleled prospects for scientific inquiry, business ventures, and global cooperation. Articles

nasa

https://ntrs.nasa.gov/citations/20190031760

[132] Materials and Processes for New Propulsion Systems with Reduced ... — Materials and Processes for New Propulsion Systems with Reduced Environmental Impact - NASA Technical Reports Server (NTRS) Materials and Processes for New Propulsion Systems with Reduced Environmental ImpactAeronautics research at NASA Glenn Research Center includes development, characterization and modeling of high temperature, lightweight materials and fabrication processes for aircraft propulsion systems with increased efficiency and reduced emissions, fuel burn and noise. Ceramic Matrix Composites for Turbine Components: As part of NASA's Aeronautics research, Glenn Research Center has developed Ceramic Matrix Composites for 2700 degrees Fahrenheit turbine engine applications in the next generation of ultra-efficient aircraft. Grady, Joseph (NASA Glenn Research Center Cleveland, OH, United States) Robinson, Raymond (NASA Glenn Research Center Cleveland, OH, United States) Pereira, Joseph (NASA Glenn Research Center Cleveland, OH, United States)

cambridge

https://www.cambridge.org/core/journals/mrs-bulletin/article/materials-considerations-for-aerospace-applications/BAEA10F52C8681AB73737E9F8716BF3A

[133] Materials considerations for aerospace applications — Using an ICME approach (see the article in this issue by Xiong and Olson), QuesTek Innovations developed two new stainless-steel-type alloys: (1) Ferrium S53 (AMS 5992) has a minimum tensile strength of 1930 MPa, matching that of 300M, with better corrosion resistance than the latter alloy. The aft portion of the high-pressure compressor operates beyond the temperature capability of titanium alloys, and thus, nickel-based superalloys are employed, although higher-strength and higher-temperature-capable titanium alloys such as Ti-17 and Ti-6Al-2Mn-4Zr-2Sn (Ti-6-2-4-2) are used for the cooler early forward stages The temperatures in the rear stage of the high-pressure compressor in a modern engine with a high compression ratio can require cast superalloys for creep resistance and powder superalloy disks for high-temperature creep and fatigue resistance.

frontiersrj

https://frontiersrj.com/journals/ijfetr/sites/default/files/IJFETR-2024-0034.pdf

[134] PDF — International Journal of Frontiers in Engineering and Technology Research, 2024, 06(02), 035–044 Publication history: Received on 01 March 2024; revised on 10 April 2024; accepted on 13 April 2024 Article DOI: https://doi.org/10.53294/ijfetr.2024.6.2.0034 Abstract Electrical propulsion systems have revolutionized satellite technology by offering greater efficiency, longer mission durations, and increased maneuverability compared to traditional chemical propulsion systems. This efficiency advantage translates to reduced launch mass and cost, making electrical propulsion systems particularly attractive for small International Journal of Frontiers in Engineering and Technology Research, 2024, 06(02), 035–044 36 satellite missions and interplanetary exploration (Etukudoh et al., 2024). Exploring future prospects in electrical propulsion systems is essential for addressing the limitations of current technologies and unlocking new capabilities for satellite missions (Sahoo et al., 2020). Technical Challenges Electrical propulsion systems require efficient power generation and management solutions to supply the necessary energy for thruster operation (Ibekwe et al., 2024).

researchgate

https://www.researchgate.net/publication/380001482_Electrical_propulsion_systems_for_satellites_a_review_of_current_technologies_and_future_prospects

[137] Electrical propulsion systems for satellites: a review of current ... — As the demand for more capable and sustainable satellite missions grows, advancements in propulsion technology will be essential in meeting these evolving needs and pushing the boundaries of space

scitechdaily

https://scitechdaily.com/nasa-unveils-game-changing-electric-propulsion-technology-for-future-space-missions/

[138] NASA Unveils Game-Changing Electric Propulsion Technology for Future ... — NASA’s new propulsion technology enhances small spacecraft capabilities for future planetary missions and extends the operational life of existing satellites. Not only will this technology enable new types of planetary science missions, one of NASA’s commercial partners is already preparing to use it for another purpose—to extend the lifetimes of spacecraft that are already in orbit. By contrast, planetary science missions benefiting from the NASA-H71M electric propulsion system technology could operate for 15,000 hours and process over 30% of the small spacecraft’s initial mass in propellant. Collaborating with U.S. industry to find small spacecraft applications with propulsive requirements similar to future NASA planetary science missions not only supports U.S. industry in remaining a global leader in commercial space systems but creates new commercial opportunities for NASA to acquire these important technologies as planetary missions require them.

sciencedirect

https://www.sciencedirect.com/science/article/pii/S0376042123000167

[139] Recent innovations to advance space electric propulsion technologies — The innovations in the present space propulsion technologies include enhancing the plasma control in the electric propulsion (EP) thrusters, introduction of new control mechanisms, the utilization of alternative propellants to xenon, to address the requirements of the recently emerged missions. While many types of space EP systems are mature and active in space, significant progress is still required to address the new tasks and challenges that emerged recently, such as plans for Mars and Moon exploration , building huge satellite constellations such as Starlink and OneWeb [, , ], advanced astrophysical studies including space-based gravitational wave detection systems [, , , ], precise astrophysical and astronomical measurements in space [, , ], search for life on exoplanets , and others. To enhance the efficiency of the thrusters via innovative, not yet explored physical principles and technological approaches that were recently demonstrated in labs or conceptualised for the application in space propulsion systems;

spacevoyageventures

https://spacevoyageventures.com/the-future-of-international-cooperation-in-space-tourism/

[140] The Future of International Cooperation in Space Tourism: Strategies ... — With advancements in technology making space more accessible, the global community stands at the precipice of a new era where international collaboration can lead to unprecedented opportunities for scientific advancement, economic growth, and mutual understanding. ... Key to deep space exploration is the advancement in propulsion and life

sciencedirect

https://www.sciencedirect.com/science/article/pii/0094576592901242

[164] The effects of chemical propulsion on the environment — The environmental impacts of both solid and liquid rocket propulsion systems are evaluated. The exhaust species and launch profile of the Space Shuttle, which injects the greatest mass of exhaust products into the atmosphere of any current system, are discussed in some detail. Model calculations predict a global stratospheric ozone reduction of

airbus

https://www.airbus.com/en/innovation/future-aircraft/propulsion-systems

[166] Propulsion systems - Airbus — Main navigation Innovation Sustainability Safety Secondary navigation With a focus on sustainability, efficiency, and innovation, we are exploring a range of transformative engine options to reduce the environmental impact of air travel. These include open fan, hydrogen, electric and hybrid-electric propulsion systems, all of which hold the potential to reduce fuel consumption and carbon emissions compared to current propulsion technology. Airplane engines are critical to safety, operational and economic performance, and environmental efficiency. We also work closely with key stakeholders, including governments, industry partners, and research institutions, to accelerate the development of innovative propulsion technologies. Airbus is working with propulsion experts CFM on the Revolutionary Innovation for Sustainable Engines (RISE) open fan engine demonstrator. Legal navigation

techbriefs

https://www.techbriefs.com/component/content/article/45207-hybrid-electric-propulsion-systems-for-sustainable-flight

[171] Advancing Hybrid-Electric Propulsion Systems for Sustainable Flight — Advancing Hybrid-Electric Propulsion Systems for Sustainable Flight - Tech Briefs Hybrid-electric propulsion systems hold clear potential to reduce aircraft carbon dioxide emissions and support the goal of greater sustainability in aviation. Hybrid-electric propulsion systems, which combine fuel-burning engines with electric motors and batteries, create opportunities to significantly improve aircraft fuel efficiency and lower carbon-dioxide emissions, while also offering potential reductions in maintenance costs. Collins Aerospace  is working with sister business Pratt & Whitney Canada  to advance sustainable hybrid-electric propulsion technology for the aviation industry. Hybrid-electric propulsion systems hold clear potential to reduce aircraft carbon-dioxide emissions and support the industry’s drive toward greater sustainability in aviation. Aerospace Aircraft Aviation fuels Electric aircraft Electrical systems Emissions Energy Energy Storage Energy storage systems Hybrid electric vehicles On-board energy sources Propulsion Sustainable development Vehicles

advanceh2

https://www.advanceh2.com/news/infrastructure/certification/driving-sustainable-aviation-hydrogen-propulsions-role-in-achieving-net-zero-emissions-by-2050-xwb8tbjhe2

[172] Driving Sustainable Aviation: Hydrogen Propulsion's Role in Achieving ... — The aviation industry is steadfast in its commitment to achieving net-zero emissions by 2050, driving transformative advancements in propulsion technology. Hydrogen propulsion, hybrid-electric systems, and turbo-electric engines have emerged as key solutions in balancing sustainability goals with operational performance. These innovations are supported by progress in aerodynamics, digital

iata

https://www.iata.org/contentassets/dcd25da635cd4c3697b5d0d8ae32e159/iata-agm-resolution-on-net-zero-carbon-emissions.pdf

[173] PDF — Governments must implement constructive policy frameworks that focus on production incentives for sustainable aviation fuels (SAF) and helps to realize cost-effective new technologies that together will support the Paris Agreement objectives and secure a sustainable future for aviation. Aircraft and engine manufacturers, fuel-producing companies, airports, and air navigation services providers

nature

https://www.nature.com/articles/s43247-025-02222-3

[174] Sustainable aviation for a greener future | Communications Earth ... — The pathways include the adoption of sustainable aviation fuels, advancement of hydrogen and electric propulsion, optimization of air traffic management, and implementation of policies that incentivize sustainable practices. Advances in feedstock optimization through biotechnology, renewable energy integration in conversion processes, and cost-effective supply chain development are essential to scaling the deployment of sustainable aviation fuels, reducing production costs, and meeting the growing global demand for sustainable aviation solutions. Japan and the United Kingdom also target net-zero by 2050, with strategies emphasizing sustainable aviation fuels, hydrogen-powered aircraft, and optimized air traffic management. By fostering the development of cleaner propulsion systems, advanced materials, and digital solutions, aviation can contribute to a more sustainable and environmentally integrated transportation system, ensuring a cleaner and carbon-neutral future.

seaforce

https://seaforce.my/environmental-impact-of-naval-propulsion/

[198] Assessing the Environmental Impact of Naval Propulsion Systems — The environmental impact of naval propulsion has garnered increasing scrutiny in recent years, as the maritime sector plays a pivotal role in global commerce and security. Traditional ship propulsion systems, primarily reliant on fossil fuels, contribute significantly to greenhouse gas emissions and marine pollution.

sciencedirect

https://www.sciencedirect.com/science/article/pii/B9780323956543000067

[199] Environmental impact of propulsion systems and green alternatives — The environmental impact of space propulsion has been analyzed from a wide variety of viewpoints and by experts of different fields. Among all, this chapter contains a wide literature survey on the state and the perspectives of two specific topics: the interaction of combustion products with the atmosphere and the toxicity of propellants as well as of their reaction products.

mit

https://dspace.mit.edu/handle/1721.1/150129

[200] Environmental Impacts of Future Aviation Propulsion Systems — Specifically, this thesis addresses aspects of 1) aerosol formation from aviation-attributable NOx and SOx, 2) the technical extent to which the air quality and climate impacts of aviation can be minimized, and 3) how propulsion system design for supersonic commercial aircraft in the future would impact the environment.

nature

https://www.nature.com/articles/s43247-025-02222-3

[201] Sustainable aviation for a greener future - Communications Earth ... — The pathways include the adoption of sustainable aviation fuels, advancement of hydrogen and electric propulsion, optimization of air traffic management, and implementation of policies that incentivize sustainable practices. Advances in feedstock optimization through biotechnology, renewable energy integration in conversion processes, and cost-effective supply chain development are essential to scaling the deployment of sustainable aviation fuels, reducing production costs, and meeting the growing global demand for sustainable aviation solutions. Japan and the United Kingdom also target net-zero by 2050, with strategies emphasizing sustainable aviation fuels, hydrogen-powered aircraft, and optimized air traffic management. By fostering the development of cleaner propulsion systems, advanced materials, and digital solutions, aviation can contribute to a more sustainable and environmentally integrated transportation system, ensuring a cleaner and carbon-neutral future.

nih

https://pmc.ncbi.nlm.nih.gov/articles/PMC1241073/

[202] The origin, fate, and health effects of combustion by-products: a ... — Abstract. Incomplete combustion processes can emit organic pollutants, metals, and fine particles. Combustion by-products represent global human and environmental health challenges that are relevant not only in heavily industrialized nations, but also in developing nations where up to 90% of rural households rely on unprocessed biomass fuels for cooking, warmth, and light.

synapseforges

https://synapseforges.com/articles/electric-propulsion-systems-design-applications/

[210] Electric Propulsion Systems: Design and Applications — Electric propulsion systems represent a significant advancement in propulsion technology, particularly in a world increasingly focused on sustainability and efficiency. In summary, electric propulsion systems mark a transformative approach in aerospace technology, promising enhanced efficiency, reduced environmental footprints, and practical applications across a range of industries. "Electric propulsion systems have the potential not only to transform how we explore space but also to significantly alter our approach to sustainable transportation on Earth." High Efficiency: They utilize electricity effectively, often providing better performance than traditional propulsion systems. As the demand for sustainable and efficient technologies rises, electric propulsion systems will continue to play a central role in addressing global challenges such as climate change and resource depletion.

carstrucksroads

https://carstrucksroads.com/government-policies-on-electric-vehicles/

[213] How Government Policies on Electric Vehicles Are Driving the Future of ... — As the world shifts toward sustainable transportation, government policies on electric vehicles (EVs) play a crucial role in shaping the future of mobility. I've seen firsthand how these policies can accelerate EV adoption, drive innovation, and ultimately reduce greenhouse gas emissions. From tax incentives to infrastructure investments, governments are taking bold steps to encourage both

cepweb

https://www.cepweb.org/wp-content/uploads/2023/11/Benoit-Lenain-2023-Advancing-Electric-Mobility-1.pdf

[214] PDF — The scope of these policies varies across countries, and so does the actual adoption of EVs (Figure 2). In Australia, Japan, Mexico and most U.S. states, the number of electric cars put on the road remains very low. Conversely, there is a notable enthusiasm among car buyers in nations such as in Norway, where electric vehicles

nrel

https://www.nrel.gov/docs/fy22osti/80220.pdf

[215] PDF — This report provides an overview of the current state and potential future development of aviation electrification. To understand the types of research questions about current and future challenges for this emerging sector, we consider a case study of the potential deployment of small commercial electric aircraft for existing underserved markets and we consider operational requirements and technical challenges as well as the range of questions about charging infrastructure, grid integration, policy and regulatory requirements, and emissions impacts that will need to be addressed. The case study also outlines potential nearer-term solutions and research areas of interest that will need to be addressed in the longer term at much larger scales, and it highlights the National Renewable Energy Laboratory’s capabilities for addressing these challenges with a variety of stakeholders. This case study illustrates some of the challenges associated with electrifying aviation on a small scale by focusing on four regional markets with service to Denver International Airport (DEN).

esrgroups

https://journal.esrgroups.org/jes/article/view/6146

[216] Powering the Future: The Impact of Battery Technology on Electric ... — Battery technology is a critical factor influencing the performance and future of electric vehicles (EVs). Advances in battery systems have significantly enhanced key aspects such as range, charging speed, longevity, and overall efficiency, making EVs more attractive compared to traditional gasoline-powered vehicles. High energy density in modern batteries allows for longer distances on a

ieee

https://ieeexplore.ieee.org/document/10434178

[217] Innovations in Battery Technologies of Electric Vehicle: A Review — This paper explores the transformative impact of Electric Vehicles (EVs) on the automotive industry. It highlights the rapid expansion of the EV market worldwide, driven by increased options, reduced pricing, and advancements in battery technology. The significant progress made since the inception of EVs, this paper highlights the need for further research into optimizing battery designs for

sciencedirect

https://www.sciencedirect.com/science/article/pii/S2772424724000313

[218] Unveiling the determinants of battery electric vehicle performance: A ... — As electric vehicles reach the end of their designed lifespan, battery performance degradation and increased maintenance costs inevitably lead to their market exit. During this process, considerations such as how to handle batteries and other critical components to minimize environmental impact and ensure the maximum recovery and reuse of

northwestern

https://www.qrg.northwestern.edu/projects/vss/docs/Propulsion/3-how-is-rocket-propulsion-different-from-jet.html

[225] How is rocket propulsion different from jet propulsion? — The main difference between jet propulsion and rocket propulsion is that in rocket propulsion the oxidizer is carried with the vehicle, but jet propulsion the oxidizer is the oxygen in the air sucked into the engine of the plane. Because there is no oxidizer in space, rockets need to carry their own oxidizers with them.

thisvsthat

https://thisvsthat.io/jet-engine-vs-rocket-engine

[226] Jet Engine vs. Rocket Engine - What's the Difference? | This vs. That — Jet Engine vs. Rocket Engine What's the Difference? Jet engines and rocket engines are both types of propulsion systems used in aircraft and spacecraft. However, they differ in their working principles and applications. Jet engines rely on the intake of air, which is compressed and mixed with fuel before being ignited.

techbullion

https://techbullion.com/innovations-and-challenges-in-hybrid-electric-vehicles-design-control-systems-batteries-and-thermal-management/

[230] Innovations and Challenges in Hybrid Electric Vehicles: Design, Control ... — Innovations and Challenges in Hybrid Electric Vehicles: Design, Control Systems, Batteries, and Thermal Management - TechBullion Innovations and Challenges in Hybrid Electric Vehicles: Design, Control Systems, Batteries, and Thermal Management Hybrid electric vehicles (HEVs) are designed to integrate two primary types of propulsion systems: a conventional internal combustion engine (ICE) and one or more electric motors powered by batteries. Related Items:Advanced Cooling Systems, batteries, Battery Management Systems, Control Systems, Design, Electric Propulsion, Electric Vehicle Infrastructure, Electrification Trends, Emissions Reduction, Energy Efficiency, Energy Storage, Environmental Impact, Fuel Economy, HEVs, Hybrid Electric Vehicles, Hybrid System Design, Hybrid Vehicle Challenges, Internal Combustion Engine, Lithium-ion Batteries, Nickel-Metal Hydride Batteries, Optimization-Based Control, Power Electronics Controller, Refrigerant-Based Cooling, Regenerative Braking, Rule-Based Control, Thermal Management, Vehicle Sustainability

altonaviation

https://altonaviation.com/alton_insights/engineering-opportunities-and-challenges-for-evtols/

[231] Engineering Opportunities and Challenges for eVTOLs | Alton Aviation ... — eVTOL Design Complexities and Opportunities Electric Vertical Takeoff and Landing (eVTOL) aircraft represent a promising leap in urban air mobility, offering solutions to congestion and transportation inefficiencies. However, their development presents significant engineering challenges. These challenges include designing efficient propulsion systems, ensuring battery reliability and longevity

aeroplanetech

https://aeroplanetech.com/electric-vs-traditional-propulsion/

[232] Electric vs. Traditional Propulsion: A Comparative Analysis in Aircraft — Electric propulsion refers to the use of electric motors and associated systems to propel aircraft, providing an alternative to traditional propulsion methods that rely on internal combustion engines.

propulsiontechjournal

https://propulsiontechjournal.com/index.php/journal/article/download/320/262/572

[239] AI-Integrated Mechanical Engineering Solutions for Next-Gen Rocket ... — This abstract explores the transformative impact of AI in the development and optimization of rocket propulsion technologies, highlighting its potential to revolutionize the aerospace industry. AI-powered mechanical engineering solutions have emerged as a game-changer in the design and manufacturing of rocket propulsion systems.

sagepub

https://journals.sagepub.com/doi/abs/10.1177/09544100231182268

[240] Multi-objective multidisciplinary design optimization of liquid ... — The design of liquid-propellant engines (LPEs) has several challenges in setting the performance parameters. Accordingly, optimizing the design of a thrust chamber is of considerable importance that has been considered in several research projects. Previous research has focused on multidisciplinary design optimization (MDO).

nasa

https://ntrs.nasa.gov/api/citations/20230006037/downloads/SETS+2023+-+Rocket+Engine+Successes+and+Failures_Gradl_4-24-23.pdf

[241] PDF — Metal Additive Manufacturing (AM) can provide significant advantages for lead time and cost over traditional manufacturing for rocket engines. Lead times reduced by 2-10x Cost reduced by more than 50% Complexity is inherent in liquid rocket engines and AM provides new design and performance opportunities.

wiley

https://onlinelibrary.wiley.com/doi/10.1002/9781119415077.ch5

[249] Promising Technologies in Propulsion and Power - Future Propulsion ... — The promising propulsion technologies include advanced core ultra-high bypass-turbofan engine, multi-combustor, multifuel propulsion systems (using kerosene and cryogenic fuel), wave rotor topping cycle, intercooled and recuperated turbofan engines, pulse detonation engine, i.e. tapping into the unsteadiness as a means of harvesting energy.

sciencedirect

https://www.sciencedirect.com/science/article/pii/S0360319924043295

[250] Hydrogen propulsion systems for aircraft, a review on recent advances ... — A comprehensive overview of the hydrogen propulsion systems in aviation is presented with an emphasis on the technical aspects crucial for creating a more sustainable and efficient air transportation sector. ... The challenges for H 2 application in aviation and the future perspective are discussed in section four where on-board H 2 storage

springer

https://link.springer.com/article/10.1007/s44205-022-00011-0

[251] Perspectives on the success of electric propulsion — Electric propulsion is now in both widespread use and active flight-implementation across a broad spectrum of commercial and government applications ranging from cubesats, LEO constellations, GEO comsats, deep space science missions, and even the human-tended Lunar Gateway. It has been my good fortune to witness, and even participate in, to some small extent, the transition of electric

nasa

https://www.nasa.gov/hemm-3/

[252] High-Efficiency Megawatt Motor (HEMM) - NASA — Overview. The 1.4-megawatt (MW) High-Efficiency Megawatt Motor (HEMM) is being designed to meet the needs of electrified aircraft propulsion. ... (HEMM) components for future electrified aircraft propulsion. Motor Comparisons. The HEMM motor is extremely powerful and efficient for its given size (16 inches by 42 inches). Though smaller than an

sciencedirect

https://www.sciencedirect.com/science/article/pii/S2590116823000322

[254] Infrastructure planning for airport microgrid integrated with electric ... — It is becoming increasingly evident that electric propulsion systems are the future of aviation, with further electrification of aircraft anticipated . In this context, previous studies have focused on designing efficient charging systems as a crucial aspect of integrating EA into commercial airports.

nrel

https://www.nrel.gov/docs/fy22osti/80220.pdf

[255] PDF — This report provides an overview of the current state and potential future development of aviation electrification. To understand the types of research questions about current and future challenges for this emerging sector, we consider a case study of the potential deployment of small commercial electric aircraft for existing underserved markets and we consider operational requirements and technical challenges as well as the range of questions about charging infrastructure, grid integration, policy and regulatory requirements, and emissions impacts that will need to be addressed. The case study also outlines potential nearer-term solutions and research areas of interest that will need to be addressed in the longer term at much larger scales, and it highlights the National Renewable Energy Laboratory’s capabilities for addressing these challenges with a variety of stakeholders. This case study illustrates some of the challenges associated with electrifying aviation on a small scale by focusing on four regional markets with service to Denver International Airport (DEN).

aviacionaldia

https://aviacionaldia.com/en/2025/01/ecopulse-a-glimpse-into-the-future-of-hybrid-electric-aviation.html

[266] EcoPulse: A Glimpse into the Future of Hybrid-Electric Aviation — The aviation industry is constantly evolving, and the EcoPulse project is a clear example of how technological innovation is driving a more sustainable and efficient future.This demonstrator, a distributed hybrid propulsion aircraft, was jointly developed by Airbus, Daher, and Safran—three giants in the aerospace industry.

airbus

https://www.airbus.com/en/innovation/energy-transition/hybrid-and-electric-flight

[268] Hybrid and electric flight - Airbus — Hybrid and electric flight Electric and hybrid-electric propulsion is rapidly revolutionising mobility technologies across industries, from automotive and aerospace to rail and marine. Promising propulsion concepts are being further developed, such as hybrid powered aircraft or hydrogen fuel cells. In June 2023, Airbus and STMicroelectronics signed an agreement to advance research on the next generation of semiconductors, which are a key enabler of the aerospace industry’s transition to hybrid and fully electric aircraft like the ZEROe demonstrator or the CityAirbus NextGen. Hybrid-electric aircraft propulsion Hybrid-electric propulsion leads to better energy management, reducing fuel consumption by up to 5% compared to a standard flight. Hybrid-electric propulsion is an incremental step that can improve the energy efficiency of every aircraft class.