China launches hydrogen-alpha solar telescope aboard Long March 2D

China has launched a small experimental solar observatory as part of a multi-satellite launch aboard… The post China launches hydrogen-alpha solar telescope aboard Long March 2D appeared first on

China launches hydrogen-alpha solar telescope aboard Long March 2D

China has launched a small experimental solar observatory as part of a multi-satellite launch aboard a Long March 2D rocket Thursday. The launch took place from the Taiyuan Satellite Launch Center at 10:51 UTC (18:51 Bejing time).

Thursday’s launch carried eleven satellites, with the primary payload being the Chinese Hydrogen-Alpha Solar Explorer (CHASE), which was delivered to a low Earth orbit at an altitude of about 517 kilometers, with an orbital period of around 94 minutes.

The 550-kilogram CHASE satellite is a precursor to a larger Chinese solar observation satellite, the Advanced Space-Based Solar Observatory (ASO-S), which is due to launch next year. CHASE is the first satellite to be equipped for full-disk hydrogen-alpha solar spectroscopy. The spacecraft has been built around a bus which is expected to provide excellent pointing accuracy and stability.

The CHASE satellite before launch

The hydrogen-alpha wavelength is deep red and is centered at 656.28 nanometers – for comparison, visible light runs from 400 to 700 nanometers. Observing the Sun at the hydrogen-alpha wavelength can reveal structures, evolution, and dynamic processes associated with solar flares and filaments. Hydrogen-alpha observations can also reveal solar wave phenomena, which are precursors to coronal mass ejections, and the dynamics of activity in the Sun’s lower atmosphere.

While it is possible to image the Sun at this wavelength from observatories on Earth, the light they receive may be absorbed or refracted by water molecules as it passes through the atmosphere, while a space-based observatory is not affected by this and can produce clearer data without this contamination. Observations can also be made without any hindrance from cloud cover.

Long March 2D Updates
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  • Scientists will be able to combine data from CHASE with that from other spacecraft in an international fleet that keep watch over the Sun – which include ASO-S, STEREO, the Solar Dynamics Observatory, IRIS, Parker Solar Probe, and Solar Orbiter – to provide a fuller picture of solar activity and dynamics. This is important as the Sun not only provides heat and light for Earth and the solar system but also can cause very negative effects on the technology we use in daily life through solar flares and CMEs.

    In 1859, a CME known as the Carrington event shorted out telegraphs and caused auroral displays in lower latitudes that would not normally see the Northern Lights. A similar event today could cause severe damage to many power grids and electronics.

    A lesser but still powerful mass ejection in March 1989 caused a major power outage in Quebec and interfered with radio broadcasts and weather satellites. During that event, the Northern Lights could be seen as far south as Texas and Florida.

    The Sun goes through 11-year cycles with periods of minimum and maximum activity. We are currently entering Solar Cycle 25, which is increasing in intensity and sunspot activity as it heads toward a solar maximum predicted for July 2025. CHASE is scheduled to observe the Sun through the spacecraft’s three-year lifetime, helping to study our nearest star during this period of increasing solar activity.

    CHASE and its co-passengers are prepared for launch – via CGTN

    Ten other satellites joined CHASE for its ride into orbit. These included the SSS-2A 3U CubeSat, a project led by students from Shanghai Jiaotong University’s Asia-Pacific Space Cooperation Organization (APSCO) in partnership with a team from Pakistan.  The CubeSat carries an optical camera, radiation monitor, ADS-B receiver, satellite navigation receiver, and is equipped to communicate with other satellites in orbit as part of a constellation of APSCO satellites.

    Another satellite, Tianyuan-1, was built as part of a project involving pupils at a primary school in Nanjing. It is the first Chinese satellite to be built with participation from primary school children (an equivalent age group to elementary schools in the United States).

    Other satellites aboard the launch included SSS-1, Orbital Atmospheric Density Detection Satellite, Commercial Meteorological Observation Satellite, Jinzijing-2, LEO Navigation Augmentation Test Satellite, Traffic Test Satellite, Hede II-E, and Hede II-F.

    Thursday’s launch took place from the Taiyuan Satellite Launch Center, an inland launch site in Shanxi province in east-central China.

    The Long March 2D, also known as Chang Zheng 2D (CZ-2D) is a two-stage rocket that is mainly used to place satellites into low Earth orbit, including sun-synchronous and polar orbital regimes. Like other older members of the Long March family, is fueled by unsymmetrical dimethylhydrazine (UDMH) and dinitrogen tetroxide, a hypergolic propellant combination that the family owes to its history as a derivative of the Dongfeng 5 missile. These propellants are being phased out on newer Chinese rockets due to their toxicity.

    Thursday’s launch targeted a near-polar sun-synchronous orbit, inclined 98 degrees to the equator and at an altitude of about 520 kilometers.

    For the first time, the Long March 2D flew with grid fins on its first stage, similar to those sported by SpaceX’s Falcon 9 rocket. The purpose of these is not to help recover the stage for reuse, but to help guide it as it falls back to Earth and ensure that it falls harmlessly into its planned drop zone.

    Because China’s older launch sites are located inland, its rockets have become infamous for dropping debris in populated areas, so recent launches of several Long March variants have tested the fins as a way of reducing the risk to people and property under the flight path.

    Thursday’s launch is the fourth of the Long March 2D in 2021, with China previously announcing that it planned to launch this type of rocket seven times before the end of the year. The launch also comes a little over a day before China’s next crewed launch, Shenzhou 13, is due to lift off from the Jiuquan Satellite Launch Center for a long-duration stay aboard the country’s space station. That mission is currently scheduled to lift off at 16:23 UTC on Friday (00:23 Bejing Time on Saturday).

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    OneWeb deployment reaches halfway point with Soyuz 2.1b launch

    The initial deployment of OneWeb’s satellite broadband constellation will reach its halfway stage on Thursday… The post OneWeb deployment reaches halfway point with Soyuz 2.1b launch appeared first on

    OneWeb deployment reaches halfway point with Soyuz 2.1b launch

    The initial deployment of OneWeb’s satellite broadband constellation will reach its halfway stage on Thursday with the launch of 36 more spacecraft aboard a Russian Soyuz 2.1b rocket. Liftoff from the Vostochny Cosmodrome in Eastern Russia is scheduled for 18:40 local time (09:40 UTC) on October 14.

    Thursday’s launch is the 11th in a series of flights to deploy OneWeb’s initial constellation of 648 satellites. With 322 satellites already in orbit and 36 more on the way with this launch, the completion of this mission will mean more than half of the initial constellation has been deployed.

    OneWeb satellite constellation

    Founded by American businessman Greg Wyler in 2012,  with a large fleet of small satellites in low Earth orbit similar to SpaceX’s Starlink constellation. Unlike Starlink, OneWeb sees its primary customer base as business and government users.

    Satellite internet services are seen as a way to bring high-speed connectivity to regions that cannot easily be served by terrestrial broadband – for example, remote rural locations where the infrastructure may not exist and would not be cost-effective to develop.

    Traditional communications satellites operate in geostationary orbits, high above the Earth’s equator; however, this presents a difficulty for internet providers as the travel time to and from the satellites results in latency, a delay in the round trip time to request and load data – such as a web page – across the network. Placing satellites in lower orbits reduces this problem as signals do not have as far to travel, but this comes at the cost of needing more spacecraft to ensure continuous global coverage.

    While the first 648 spacecraft will make up its initial constellation, OneWeb has committed to building at least 900 satellites. The additional units will serve as spares and replacements for any that might fail or reach the end of their operational lives.

    Each OneWeb satellite has a mass of 147 kilograms and an expected design life of at least seven years. The constellation occupies a near-polar orbit with an altitude of 1,200 kilometers at an inclination of 87.4 degrees. Once fully deployed, the constellation will consist of 18 planes, with 36 satellites in each plane.

    The  to allow time for on-orbit testing before operational launches commenced. Subsequent missions have carried groups of either 34 or 36 satellites, with the first operational launches taking place in February and March 2020.

    After failing to secure enough investment, OneWeb filed for bankruptcy in March 2020, halting launches. Three months later, the British government acquired the company in conjunction with Indian-based Bharti Enterprises Ltd.

    With funding secured, OneWeb exited the bankruptcy process in November and launches resumed the following month. 

    Visualization of a OneWeb satellite in orbit. (Credit: OneWeb)

    OneWeb is currently expecting to begin offering an initial commercial service in the Northern hemisphere by the end of the year.

    Soyuz Launch from Vostochny 

    OneWeb selected  to carry out its initial launches, using the workhorse Russian Soyuz rocket which Arianespace markets to fill the gap between its heavy-lifting Ariane 5 and lighter Vega rockets. The agreement between OneWeb and Arianespace includes launches from three different sites – the  in Kourou, French Guiana, the  in Kazakhstan, and the  in Russia’s far east.

    Soyuz/OneWeb #11 UPDATES
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  • Launches from Baikonur and Vostochny are subcontracted to Starsem, a partnership between Arianespace, the Russian space agency Roscosmos, and Soyuz manufacturer TsSKB Progress. Thursday’s launch is the 11th that Arianespace and Starsem have performed for OneWeb and will be the sixth from the Vostochny Cosmodrome. Of the other launches, four have flown from Baikonur and one from Kourou.

    With 36 spacecraft aboard, the total payload mass for Thursday’s launch is 5,797 kg, which includes the satellites themselves as well as their mounting and deployment mechanisms. Soyuz will use a Fregat upper stage to deploy the OneWeb spacecraft into an orbit about 450 kilometers above the Earth, with the satellites using their electric propulsion systems to raise themselves into their operational orbits.

    While Soyuz has been the launcher of choice for OneWeb’s early missions, the company is keeping its options open for future satellites after recently signing a letter of intent with the commercial arm of the Indian Space Research Organisation (ISRO) to place future satellites aboard India’s PSLV and GSLV Mk.III rockets. While the non-binding agreement does not commit OneWeb to launching their satellites with ISRO, it could pave the way for missions from India to begin as early as next year.

    OneWeb has previously explored other providers, signing launch contracts and options with Blue Origin and Virgin Orbit for future missions on their New Glenn and LauncherOne rockets, respectively. Most of the contracts with Virgin have since been canceled, leading to a legal dispute between the two companies. OneWeb also secured a deal with Arianespace to fly its satellites on the maiden flight of the Ariane 6 rocket; however, this was later canceled as OneWeb reviewed its deployment plans in preparation to emerge from bankruptcy.

    The Soyuz 2.1b/Fregat-M rocket for this mission is a four-stage version of the most powerful form of the Soyuz rocket. Soyuz is descended from a series of rockets that trace their lineage back to Sergei Korolev’s R-7 missile of the 1950s, although the current-generation Soyuz-2 rockets were introduced in 2004.

    The Soyuz-2 family consists of three variants. The Soyuz 2.1a is a modernized version of the previous-generation Soyuz-U, incorporating upgraded engines, digital flight control systems, and other enhancements. The Soyuz 2.1b offers increased performance through a redesign of the third stage, including a new RD-0124 engine. The third variant is the smaller Soyuz 2.1v, designed to carry lighter payloads.

    The three stages of the Soyuz 2.1b burn RG-1 kerosene propellant and liquid oxygen. The first stage consists of four boosters clustered around the core – or second – stage. The third stage is mounted atop the second stage, with the OneWeb satellites – as well as the Fregat upper stage – enclosed within the payload fairing at the nose of the vehicle.

    The restartable Fregat upper stage was developed from the propulsion system of the Fobos probes that the Soviet Union sent to the Martian moon Phobos in the late 1980s and is frequently used as an upper stage on Soyuz to enable the delivery of satellites into higher, more precise or more complex orbits than would be possible with just the Soyuz vehicle itself.

    Fregat burns hypergolic unsymmetrical dimethylhydrazine and dinitrogen tetroxide and can make up to 20 burns in the course of a single mission.

    The Soyuz for the OneWeb 11 mission is rolled to the launch pad. (Credit: Roscosmos)

    Thursday’s launch will use a Soyuz rocket with serial number X15000-009 on a flight designated ST36 by Arianespace and Starsem. The mission will last three hours 51 minutes 40 seconds from liftoff until the final satellite separates.

    The flight will begin from the Vostochny Cosmodrome, Russia’s newest launch site having supported its first launch in April 2016. Located in Russia’s eastern Amur Oblast, it was built on the site of the former Svobodny missile base which had previously hosted a small number of orbital launches with the solid-fueled Start rocket.

    Vostochny currently has launch facilities for Soyuz rockets, with an Angara launch complex under construction. The Soyuz complex at Vostochny is designated Pad 1S.

    Soyuz rolled to the launch pad on Monday in preparation for the OneWeb mission. The final countdown began about nine hours before liftoff with system checkouts on the rocket and ground infrastructure before operations proceeded into fueling four and a half hours ahead of launch.

    For Soyuz, the final startup sequence will see the first and second stage engines ignite at the T-16 second mark. Each of the four first stage boosters is powered by a single RD-107A engine while the second stage is powered by an RD-108A that incorporates four vernier nozzles for control of the rocket’s attitude.

    Once a good burn in all combustion chambers is confirmed, a signal will be sent to take the engines to full thrust at T-4 seconds, followed shortly thereafter by liftoff.

    For the first 117 seconds of the flight, the first and second stage engines will fire together to propel Soyuz through the dense lower regions of Earth’s atmosphere. Once the first stage has consumed its propellant, it will shut down and separate – with the four boosters being pushed away from the second stage by venting residual oxygen from their noses. On a clear day, the “cross of Korolev” – named after the rocket’s chief designer – can be seen as the boosters fall away from the still-burning second stage.

    Soyuz and OneWeb 11 stand on the launch pad. (Credit: Roscosmos)

    Once the rocket crosses out of the aerodynamically sensitive portion of the flight, the payload fairing is no longer needed and will separate at about T+3 minutes 35 seconds. The second stage will continue to fire until T+4 minutes 46 seconds when the next stage separation event will take place.

    For the second-third stage separation, Soyuz uses a “hot fire” approach, where the third stage’s RD-0124 engine ignites while the second stage is still burning. This “hot staging” ensures that the rocket remains under constant forward acceleration so propellants in the third stage tanks remain settled for ignition. A lattice interstage between the second and third stages allows exhaust gases to escape in the moments between third stage ignition and second stage separation.

    A few seconds after the second stage separates, the third stage’s aft skirt will also be jettisoned, splitting into three sections and falling away from the vehicle. The third stage will burn for about four and a half minutes and will deploy Fregat a few seconds after its burnout.

    The first burn of the Fregat upper stage’s S5.92 engine will begin at T+9 minutes 22 seconds and last for about five minutes. Just under an hour later, Fregat will fire again for another short burn that will circularize its orbit, setting up for the deployment of the OneWeb satellites.

    The satellites will separate in nine groups of four, with a gap of just over 19 minutes between each separation event. The first four satellites will separate one hour and 18 minutes after launch, with the final four separating at the three-hour 51-minute 40-second mark. After deploying its payloads, Fregat will make another short engine burn to deorbit itself, concluding the mission.

    Thursday’s launch is expected to be the last OneWeb mission of the year, ending a streak of seven launches over the last six and a half months. The next OneWeb mission had been expected in late December but has slipped to 2022.

    (Lead image: Soyuz rolls out for the OneWeb #11 mission. Credit: Roscosmos)

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