China’s 500-Meter FAST Radio Telescope is Now Operational

The Five-hundred-metre Aperture Spherical Telescope (FAST) has just finished construction in the southwestern province of Guizhou. Credit: FAST

The world’s largest and most sensitive radio telescope is officially open for business according to Xinhua, China’s official state-run media. The FAST Radio Telescope saw fist light in 2016 but has been undergoing testing and commissioning since then. FAST stands for Five-hundred meter Aperture Spherical Telescope.

Continue reading “China’s 500-Meter FAST Radio Telescope is Now Operational”

Chang’e-4 Wraps Up a Year Roving on the Far Side of the Moon

Image of the Yutu-2 rover moving away from the Chang'e-4 mission's landing zone. Credit: CNSA

China greeted the New Year with some impressive lunar milestones. For starters, last Friday (Jan. 3rd) was the first anniversary of the Chang’e-4 mission becoming the first robotic mission to make a landing on the far side of the Moon. A day prior, the Yutu-2 rover also celebrated the end of its 13th lunar day of science operations and the fact that it was the first rover to travel a record 357.695 meters (1,173.5 ft) on the far side of the Moon.

Continue reading “Chang’e-4 Wraps Up a Year Roving on the Far Side of the Moon”

A Private Company in China Plans to Launch Reusable Rockets by 2021

Hyperbola-2 is Chinese company i-Space's second rocket design, and China's first reusable rocket. Image Credit: i-Space.

A Chinese company is planning to launch a rocket with a reusable booster in 2021. The company is called i-Space, and the rocket is called Hyperbola-2. They’ve already developed and launched another rocket, called Hyperbola.

Continue reading “A Private Company in China Plans to Launch Reusable Rockets by 2021”

China’s Lander Successfully Grew Some Cotton Plants on the Moon. Fruit Flies and Potatoes Didn’t Fare So Well

A 3D reconstruction based on image processing and data analysis shows two cotton leaves grown in the Chang’e-4 lander on the far side of the moon. Image Credit: Chongqing University.

When China’s Chang’e-4 spacecraft landed on the lunar far side on January 3rd 2019, it made history. It was the first spacecraft to visit that part of the Moon, and among its payload was a 2.6 kg (5.7 lb) mini-biosphere called the Lunar Micro Ecosystem (LME).

The sealed, cylindrical biosphere is only 18 cm (7.1 in) long and 16 cm (6.3 in) in diameter. The LME carried six lifeforms, kept in mostly Earth-like conditions except for micro-gravity and lunar radiation.

Continue reading “China’s Lander Successfully Grew Some Cotton Plants on the Moon. Fruit Flies and Potatoes Didn’t Fare So Well”

China’s FAST Telescope, the World’s Largest Single Radio Dish Telescope, is Now Fully Operational

The Five-hundred-metre Aperture Spherical Telescope (FAST) has just finished construction in the southwestern province of Guizhou. Credit: FAST

After years of construction, China’s new radio telescope is in action. The telescope, called FAST (Five-hundred-meter Aperture Spherical Radio Telescope) has double the collecting power of the Arecibo Observatory in Puerto Rico, which has a 305 meter dish. Until now, Arecibo was the world’s largest radio dish of its type.

Continue reading “China’s FAST Telescope, the World’s Largest Single Radio Dish Telescope, is Now Fully Operational”

China’s Lunar Rover Wakes Up and Gets to Work for its 3rd Lunar Day

China's Yutu-2 rover captured this image of the lunar surface during its third lunar day. Image Credit: CLEP/CNSA
China's Yutu-2 rover captured this image of the lunar surface during its third lunar day. Image Credit: CLEP/CNSA

The China National Space Administration (CNSA) has released some new photos and updated the world on their lunar rover mission. The Yutu-2 rover is working its way into the history books on the lunar far side, exploring the Von Karman crater. It’s third lunar day is now in the record books.

Continue reading “China’s Lunar Rover Wakes Up and Gets to Work for its 3rd Lunar Day”

Incredible Descent Video of the Chinese Lander to the Lunar Far Side

China's Chang'e-4 lander on the lunar surface. Image Credit: CNSA/CLEP
China's Chang'e-4 lander on the lunar surface. Image Credit: CNSA/CLEP

On January 2nd, 2019, China’s Chang’e-4 lander made a successful landing on the far side of the Moon. The China National Space Administration (CNSA) and the Chinese Lunar Exploration Program (CLEP) report that after 9 days on the surface, the mission is in good shape. The Yutu-2 rover has been deployed and has begun exploring the Von Karman crater.

CNSA has released some video of the mission, including a video of Chang’e-4’s historic descent. Thanks to the hard-working people at the Planetary Society, and to Andrew Jones who reports on the Chinese Space Program, we have a handful of new videos and images of the Chang’e-4’s mission to enjoy.

Continue reading “Incredible Descent Video of the Chinese Lander to the Lunar Far Side”

China’s Chang’e-4 Lands on the Far Side of the Moon

Image of the lunar surface taken by the Chang'e-4 spacecraft. Credit: Xinhua

Since the turn of the century, China has worked hard to become one of the fastest-rising powers in space. In 2003, the Chinese National Space Administration (CNSA) began sending their first taikonauts to space with the Shenzou program. This was followed by the deployment of the Tiangong-1 space station in 2011 and the launch of Tiangong-2 in 2016. And in the coming years, China also has its sights set on the Moon.

But before China can conduct crewed lunar missions, they must first explore the surface to locate safe landing spots and resources. This is the purpose behind the Chinese Lunar Exploration Program (aka. the Chang’e program). Named after the Chinese goddess of the moon, this program made history yesterday (Thursday, Jan. 3rd) when the fourth vehicle to bear the name (Chang’e-4) landed on the far side of the Moon.

Continue reading “China’s Chang’e-4 Lands on the Far Side of the Moon”

China is Working on a Rocket as Powerful as the Saturn V, Could Launch by 2030

The first Long March 5 rocket being rolled out for launch at Wenchang in late October 2016. Credit: Su Dong/China Daily

In the past decade, China’s space program has advanced by leaps and bounds. In recent years, the Chinese National Space Agency (CNSA) has overseen the development of a modern rocket family (the Long March series), the deployment of a space station (Tiangong-1) and the development of the Chinese Lunar Exploration Program (CLEP) –  otherwise known as the Chang’e Program.

Looking to the future, China plans to create new classes of heavy rockets in order to conduct more ambitious missions. These include the Long March 9 rocket (aka. the Changzheng 9), a three-stage, super-heavy rocket that would allow for crewed missions to the Moon. According to a recent story from Aviation Weekly, China hopes to conduct an engine demonstration of this rocket, and could do so as early as later this year.

This demonstration is part of a research effort intended to create engines for the first stage of the Long March 9. According to statements made by the Academy of Aerospace Propulsion Technology (AAPT) – part of the China Aerospace and Technology Corporation (CASC) and the one’s responsible for developing the hardware – these engines would be capable of delivering 3,500 to 4,000 metric tons (3,858 to 4,409 US tons) of thrust.

Launch of the modified Saturn V rocket carrying the Skylab space station. Credit: NASA

AAPT also indicated that work on a second-stage and third-stage engine – which would be capable of generating about 200 metric tons (440,000 lbs) and 25 metric tons (55,000 lbs) thrust, respectively – is also in progress. All told, this is roughly six times the thrust that China’s heaviest rocket (the Long March 5) can generate and would make it comparable to the Saturn V – the Apollo-era rocket that took the NASA astronauts to the Moon.

For starters, the Saturn V‘s engines delivered roughly 3,400 metric tons of thrust, and the rocket was capable of delivering 140 metric tons (310,000 lbs) to Low Earth Orbit (LEO) and about 48 metric tons (107,100 lbs) to a Lunar Transfer Orbit (LTO). By comparison, the Long March 9 will reportedly have the ability to 140 metric tons to LEO and at least 50 metric tons (110,000 lbs) to LTO.

According to Li Hong, the head of the China Academy of Launch Vehicle Technology (the CASC unit responsible for overall development and production of most Chinese space launchers), a massive turbopump has also been built for the main engine. A pump of this size is necessary, since the engine will generate four time the thrust of the largest Chinese rocket engine to date – AAPT’s YF-100, which generates 120 metric tons (265,000 lbs) of thrust.

While the full specifications of the rocket are not yet available, the China News Service has indicated that the rocket will measure 10 meters (33 ft.) in diameter. According to statements made by both Li and Lui, the first-stage engine will burn kerosene and achieve a thrust of 480 metric tons (529 US tons) – comparable to the Saturn V F-1 engine’s 680 metric tons (750 US tons) of thrust – while the second and third stage engines will likely burn hydrogen fuel.

At their current rate of progress, an engine demonstration could be taking place later this year. As AAPT President Liu Zhirang stated in an interview with Science and Technology Daily (part of the state-owned China News Service):

“A complete prototype for the engine in the 500-metric-ton class can be built and assembled this year… Because of the great parameter changes that come with rises in thrust, the current test and verification equipment cannot satisfy requirements [of the Moon rocket propulsion program]. We cannot always do 1:1 scale tests. As a result, only simulations and scaled-down tests can be done for some technology and hardware. This increases the degree of difficulty for the program.”

If successful, the Long March 9 will join the ranks of super heavy-lift launch vehicles, such as the SpaceX Falcon Heavy, the KRK rocket (currently under development in Russia), and the Space Launch System being developed by NASA. These and other rockets are being built for the purpose of bringing astronauts to the Moon, Mars, and even beyond in the coming decades.

Beyond a possible demonstration of the Long March 9′s engine technology, the CNSA has many other ambitious plans for 2018. These include a planned 35 launches involving the Long March series, fourteen of which will be carried out by the Long March-3A and six by the Long March-3C rockets. Most of these missions will involve the deployment of Beidou satellites, but will also include the launch of the Chang’e-4 lunar probe later this year.

Old Glory
Buzz Aldrin salutes the first American flag erected on the Moon, July 21, 1969. Credit: NASA/Neil A. Armstrong

This year is also when China hopes to conduct mission using its newest rocket – the Long March 5 –  in preparation for China’s lunar probe and Mars probe missions. This year is also expected to see a lot of developments in the Long March 7 series, which is likely to become the main carrier when China begins construction of its new space station (Tiangong-2, which is scheduled for completion in 2022).

Between all of these developments, it is clear that the age of renewed space exploration is upon us. Whereas the Space Race was characterized by two superpowers competing for dominance and “getting their first”, the current one is defined by both competition and cooperation between multiple space agencies and lucrative partnerships between the public sector and private industry.

And while the specter of renewed competition by space powers has a tendency to make many people nervous (especially those who are concerned about military applications), it is a testament to how humanity is growing as a space-faring species. By the time 2050 rolls around, we may just see many flags being planted on the Moon and Mars, and not just Old Glory.

Further Reading: Aviation Week, Popular Mechanics, Chinese Academy of Sciences

Russia and China Are Working on Space and Counterspace Weapons

The first Long March 5 rocket being rolled out for launch at Wenchang in late October 2016. Credit: Su Dong/China Daily

Every year, the Department of National Intelligence (DNI) releases its Worldwide Threat Assessment of the US Intelligence Community. This annual report contains the intelligence community’s assessment of potential threats to US national security and makes recommendations accordingly. In recent years, these threats have included the development and proliferation of weapons, regional wars, economic trends, terrorism, cyberterrorism, etc.

This year’s assessment, which was released on February 8th, 2018, was certainly a mixed bag of warnings. Among the many potential threats to national security, the authors emphasized the many recent developments taking place in space. According to their assessment, the expansion of the global space industry, growing cooperation between the private and public sector, and the growth of various states in space, could constitute a threat to US national security.

Naturally, the two chief actors that are singled out were China and Russia. As they indicate, these countries will be leading the pack in the coming years when it comes to expanding space-based reconnaissance, communications and navigation systems. This will not only enable their abilities (and those of their allies) when it comes to space-based research, but will have military applications as well.

The second flight of the Long March 5 lifting off from Wenchang on July 2nd, 2017. Credit: CNS

As they state in the section of the report titled “Space and Counhttps://www.dni.gov/files/documents/Newsroom/Testimonies/2018-ATA—Unclassified-SSCI.pdfterspace“:

“Continued global space industry expansion will further extend space-enabled capabilities and space situational awareness to nation-state, nonstate, and commercial space actors in the coming years, enabled by the increased availability of technology, private-sector investment, and growing international partnerships for shared production and operation… All actors will increasingly have access to space-derived information services, such as imagery, weather, communications, and positioning, navigation, and timing for intelligence, military, scientific, or business purposes.”

A key aspect of this development is outlined in the section titled “Emerging and Disruptive Technology,” which addresses everything from the development of AI and internet technologies to additive manufacturing and advanced materials. In short, it not just the development of new rockets and spacecraft that are at issue here, but the benefits brought about by cheaper and lighter materials, more rapid information sharing and production.

“Emerging technology and new applications of existing technology will also allow our adversaries to more readily develop weapon systems that can strike farther, faster, and harder and challenge the United States in all warfare domains, including space,” they write.

Artist’s illustration of China’s 8-ton Tiangong-1 space station, which is expected to fall to Earth in late 2017. Credit: CMSE

Specifically, anti-satellite (ASAT) weapons are addressed as the major threat. Such technologies, according to the report, have the potential to reduce US and allied military effectiveness by disrupting global communications, navigation and coordination between nations and armies. These technologies could be destructive, in the form of anti-satellite missiles, but also nondestructive – i.e. electromagnetic pulse (EMP) devices. As they indicate:

“We assess that, if a future conflict were to occur involving Russia or China, either country would justify attacks against US and allied satellites as necessary to offset any perceived US military advantage derived from military, civil, or commercial space systems. Military reforms in both countries in the past few years indicate an increased focus on establishing operational forces designed to integrate attacks against space systems and services with military operations in other domains.”

The authors further anticipate that Russian and Chinese destructive ASAT technology could reach operational capacity within a few years time. To this end, they cite recent changes in the People’s Liberation Army (PLA), which include the formation of military units that have training in counter-space operations and the development of ground-launched ASAT missiles.

While they are not certain about Russia’s capability to wage ASAT warfare, they venture that similar developments are taking place. Another area of focus is the development of directed-energy weapons for the purpose of blinding or damaging space-based optical sensors. This technology is similar to what the US investigated decades ago for the sake of strategic missile defense – aka. the Strategic Defense Initiative (SDI).

An artist’s concept of a Space Laser Satellite Defense System. Credit: USAF

While these weapons would not be used to blow up satellites in the conventional sense, they would be capable of blinding or damaging sensitive space-based optical sensors. On top of that, the report cites how Russia and China continue to conduct on-orbit activities and launching satellites that are deemed “experimental”. A good example of this was a recent proposal made by researchers from the Information and Navigation College at China’s Air Force Engineering University.

The study which detailed their findings called for the deployment of a high-powered pulsed ablative laser that could be used to break up space junk. While the authors admit that such technology can have peaceful applications – ranging from satellite inspection, refueling and repair – they could also be used against other spacecraft. While the United States has been researching the technology for decades, China and Russia’s growing presence in space threatens to tilt this balance of power.

Moreover, there are the loopholes in the existing legal framework – as outlined in the Outer Space Treaty – which the authors believe China and Russia are intent on exploiting:

“Russia and China continue to publicly and diplomatically promote international agreements on the nonweaponization of space and “no first placement” of weapons in space. However, many classes of weapons would not be addressed by such proposals, allowing them to continue their pursuit of space warfare capabilities while publicly maintaining that space must be a peaceful domain.”

Artist’s impression of a laser removing orbital debris, based on NASA pictures. Credit: Fulvio314/NASA/Wikipedia Commons

For example, the Outer Space Treaty bars signatories from placing weapons of mass destruction in orbit of Earth, on the Moon, on any other celestial body, or in outer space in general. By definition, this referred to nuclear devices, but does not extend to conventional weapons in orbit. This leaves room for antisatellite platforms or other conventional space-based weapons that could constitute a major threat.

Beyond China and Russia, the report also indicates that Iran’s growing capabilities in rocketry and missile technology could pose a threat down the road. As with the American and Russian space programs, developments in space rocketry and ICBMs are seen as being complimentary to each other:

“Iran’s ballistic missile programs give it the potential to hold targets at risk across the region, and Tehran already has the largest inventory of ballistic missiles in the Middle East. Tehran’s desire to deter the United States might drive it to field an ICBM. Progress on Iran’s space program, such as the launch of the Simorgh SLV in July 2017, could shorten a pathway to an ICBM because space launch vehicles use similar technologies.”

All told, the report makes some rather predictable assessments. Given China and Russia’s growing power in space, it is only natural that the DNI would see this as a potential threat. However, that does not mean that one should assume an alarmist attitude. When it comes to assessing threats, points are awarded for considering every contingency. But if history has taught us anything, it’s that assessment and realization are two very different things.

Remember Sputnik? The lesson there was clear. Don’t panic!

Further Reading: DNI