Reference terms from Wikipedia, the free encyclopedia
 

Solid-propellant rocket

A solid-propellant rocket or solid rocket is a rocket with a rocket engine that uses solid propellants (fuel/oxidizer). The earliest rockets were solid-fuel rockets powered by gunpowder; they were used in warfare by the Chinese, Indians, Mongols and Persians, as early as the 13th century.

All rockets used some form of solid or powdered propellant up until the 20th century, when liquid-propellant rockets offered more efficient and controllable alternatives. Solid rockets are still used today in military armaments worldwide, model rockets, solid rocket boosters and on larger applications for their simplicity and reliability.

Since solid-fuel rockets can remain in storage for a long time without much propellant degradation and because they almost always launch reliably, they have been frequently used in military applications such as missiles. The lower performance of solid propellants (as compared to liquids) does not favor their use as primary propulsion in modern medium-to-large launch vehicles customarily used to orbit commercial satellites and launch major space probes. Solids are, however, frequently used as strap-on boosters to increase payload capacity or as spin-stabilized add-on upper stages when higher-than-normal velocities are required. Solid rockets are used as light launch vehicles for low Earth orbit (LEO) payloads under 2 tons or escape payloads up to 500 kilograms (1,100 lb).

 
Note:   The above text is excerpted from the Wikipedia article Solid-propellant rocket, which has been released under the GNU Free Documentation License.
 

Check out these latest Nanowerk News:

 

One‑step process generates high entropy alloy nanoparticles in milliseconds

A rapid synthesis method could speed discovery of cheaper, multi-metal catalysts for fuel cells, batteries, and other clean energy uses.

Nanotubes and nanosheets boost fast energy storage

Hybrid nanotube–nanosheet electrodes speed ion flow, boost charge storage, and keep supercapacitors stable through 10,000 cycles.

New review explores perovskite solar cells for space, underwater, and other extreme environments

Advances in perovskite solar cell design may enable reliable power generation in some of the world's harshest environments.

AI platform turns catalyst data into a discovery engine

A new AI-ready data framework could accelerate catalyst discovery, supporting cleaner energy and more sustainable chemical processes.

Machine learning points scientists to new superconductors- and possibly thousands more

Machine learning helped identify new superconductors and a process that could speed the discovery of thousands more energy-saving materials.

Lithium-doped carbon nanorings promise better optical devices

Simulations show that adding lithium to carbon nanorings greatly boosts nonlinear optical response, guiding designs for future photonic and optical devices.

Roll-to-roll lithography boosts flexible electronics production

A roll-to-roll digital lithography system compensates for substrate distortion in real time, enabling faster mass production of flexible electronics.

Identifying proteins, molecule by molecule

A nanopore detection method can rapidly identify individual proteins, aiding disease research, drug development, and biomarker discovery.

Switching spin states in manganese ions with light

Scientists developed a manganese-based molecular data storage material that works at about -132 C, warmer than earlier iron-based versions.

Shape-shifting surface adds touch to displays

A soft magnetic metasurface can morph into thousands of shapes, sense deformation, and show LED feedback, pointing to tactile interfaces, wearables, soft robotics, and AR/VR.