Bu sanatçının çizimi NASA’nın Voyager uzay aracını gösteriyor. Sağdaki bomda, Kozmik Işın Bilimi aleti, Düşük Enerji Yüklü Parçacık dedektörü, Kızılötesi Spektrometre ve Radyometre, Ultraviyole Spektrometre, Fotopolarimetre ve Geniş ve Dar Açılı Kameralar görülüyor. Parlak gri kare, aletler için optik bir kalibrasyon plakasıdır. Dünya’dan görüntüleri ve sesleri içeren Altın Kayıt, ana uzay aracı gövdesindeki sarı dairedir. Çanak, uzay aracının Dünya ile iletişim için yüksek kazançlı antenidir. Manyetometre bomu sol üst tarafa doğru uzanır. Voyager’ın güç kaynağı olan radyo izotop termoelektrik jeneratörleri sol altta görülüyor. Sola doğru uzanan iki uzun ince çubuk, Plazma Dalgası aleti tarafından kullanılan antenlerdir. Planetary Radio cihazı da açıldığında bu antenleri kullandı. Kredi: NASA/JPL-Caltech
1977’de başlatılan ikiz Voyager sondaları[{” attribute=””>NASA’s longest-operating mission and the only spacecraft ever to explore interstellar space.
Launched in 1977, NASA’s twin Voyager spacecraft inspired the world with pioneering visits to Jupiter, Saturn, Uranus, and Neptune. Their journey continues 45 years later as both probes explore interstellar space, the region outside the protective heliosphere created by our Sun. Researchers – some younger than the spacecraft – are now using Voyager data to solve mysteries of our solar system and beyond.
NASA’s twin Voyager probes have become, in many ways, time capsules of their era: They each carry an eight-track tape player for recording data, they transmit data about 38,000 times slower than a 5G internet connection, and they have about 3 million times less memory than modern cellphones.
Despite this, the Voyagers remain on the cutting edge of space exploration. Managed and operated by NASA’s Jet Propulsion Laboratory (JPL) in Southern California, they are the only probes to ever explore interstellar space – the galactic ocean that our Sun and its planets travel through.
This archival image taken at NASA’s Jet Propulsion Laboratory on March 23, 1977, shows engineers preparing the Voyager 2 spacecraft ahead of its launch later that year. Credit: NASA/JPL-Caltech
The Sun and the planets reside in the heliosphere, a protective bubble created by the Sun’s magnetic field and the outward flow of solar wind (charged particles from the Sun). Scientists – some of them younger than the two distant spacecraft – are combining Voyager’s observations with data from newer missions to get a more complete picture of our Sun and how the heliosphere interacts with interstellar space.
This archival photo shows engineers working on vibration acoustics and pyro shock testing of NASA’s Voyager on November 18, 1976. Credit: NASA/JPL-Caltech
“The heliophysics mission fleet provides invaluable insights into our Sun, from understanding the corona or the outermost part of the Sun’s atmosphere, to examining the Sun’s impacts throughout the solar system, including here on Earth, in our atmosphere, and on into interstellar space,” said Nicola Fox, director of the Heliophysics Division at NASA Headquarters in Washington. “Over the last 45 years, the Voyager missions have been integral in providing this knowledge and have helped change our understanding of the Sun and its influence in ways no other spacecraft can.”
This image highlights the special cargo onboard NASA’s Voyager spacecraft: the Golden Record. Each of the two Voyager spacecraft launched in 1977 carry a 12-inch gold-plated phonograph record with images and sounds from Earth. Credit: NASA/JPL-Caltech
The Voyagers are also ambassadors for humanity, each carrying a golden record containing images of life on Earth, diagrams of basic scientific principles, and audio that includes sounds from nature, greetings in multiple languages, and music. The gold-coated records serve as a cosmic “message in a bottle” for anyone who might encounter the space probes. At the rate gold decays in space and is eroded by cosmic radiation, the records will last more than a billion years.
This processed color image of Jupiter was produced in 1990 by the U.S. Geological Survey from a Voyager image captured in 1979. Zones of light-colored, ascending clouds alternate with bands of dark, descending clouds. Credit: NASA/JPL/USGS
Beyond Expectations
Voyager 2 launched on August 20, 1977, quickly followed by Voyager 1 on September 5. Both probes traveled to Jupiter and Saturn, with Voyager 1 moving faster and reaching them first. Together, the probes unveiled much about the solar system’s two largest planets and their moons. Voyager 2 also became the first and only spacecraft to fly close to Uranus (in 1986) and Neptune (in 1989), offering humanity remarkable views of – and insights into – these distant worlds.
This photo of Jupiter was taken by NASA’s Voyager 1 on the evening of March 1, 1979, from a distance of 2.7 million miles (4.3 million kilometers). The photo shows Jupiter’s Great Red Spot (top) and one of the white ovals. Credit: NASA/JPL
While Voyager 2 was conducting these flybys, Voyager 1 headed toward the boundary of the heliosphere. Upon exiting it in 2012, Voyager 1 discovered that the heliosphere blocks 70% of cosmic rays, or energetic particles created by exploding stars. Voyager 2, after completing its planetary explorations, continued to the heliosphere boundary, exiting in 2018. The twin spacecraft’s combined data from this region has challenged previous theories about the exact shape of the heliosphere.
NASA’s Voyager 1 acquired this image of a volcanic explosion on Io on March 4, 1979, about 11 hours before the spacecraft’s closest approach to the moon of Jupiter. Credit: NASA/JPL
“Today, as both Voyagers explore interstellar space, they are providing humanity with observations of uncharted territory,” said Linda Spilker, Voyager’s deputy project scientist at JPL. “This is the first time we’ve been able to directly study how a star, our Sun, interacts with the particles and magnetic fields outside our heliosphere, helping scientists understand the local neighborhood between the stars, upending some of the theories about this region, and providing key information for future missions.”
This approximate natural-color image from NASA’s Voyager 2 shows Saturn, its rings, and four of its icy satellites. Three satellites Tethys, Dione, and Rhea are visible against the darkness of space. Credit: NASA/JPL/USGS
The Long Journey
Over the years, the Voyager team has grown accustomed to surmounting challenges that come with operating such mature spacecraft, sometimes calling upon retired colleagues for their expertise or digging through documents written decades ago.
Neptune’s green-blue atmosphere was shown in greater detail than ever before in this image from NASA’s Voyager 2 as the spacecraft rapidly approached its encounter with the giant planet in August 1989. Credit: NASA/JPL
This is an image of the planet Uranus taken by the spacecraft Voyager 2 in 1986. Credit: NASA/JPL-Caltech
This image, taken by NASA’s Voyager 2 early in the morning of August 23, 1989, is a false color image of Triton, Neptune’s largest satellite; mottling in the bright southern hemisphere is present. Credit: NASA/JPL
This updated version of the iconic “Pale Blue Dot” image taken by the Voyager 1 spacecraft uses modern image-processing software and techniques to revisit the well-known Voyager view while attempting to respect the original data and intent of those who planned the images. Credit: NASA/JPL-Caltech
Each Voyager is powered by a radioisotope thermoelectric generator containing plutonium, which gives off heat that is converted to electricity. As the plutonium decays, the heat output decreases and the Voyagers lose electricity. To compensate, the team turned off all nonessential systems and some once considered essential, including heaters that protect the still-operating instruments from the frigid temperatures of space. All five of the instruments that have had their heaters turned off since 2019 are still working, despite being well below the lowest temperatures they were ever tested at.
This illustrated graphic was made to mark Voyager 1’s entry into interstellar space in 2012. It puts solar system distances in perspective, with the scale bar in astronomical units and each set distance beyond 1 AU (the average distance between the Sun and Earth) representing 10 times the previous distance. Credit: NASA/JPL-Caltech
Recently, Voyager 1 began experiencing an issue that caused status information about one of its onboard systems to become garbled. Despite this, the system and spacecraft otherwise continue to operate normally, suggesting the problem is with the production of the status data, not the system itself. The probe is still sending back science observations while the engineering team tries to fix the problem or find a way to work around it.
This graphic highlights some of the Voyager mission’s key accomplishments. Credit: NASA/JPL-Caltech
“The Voyagers have continued to make amazing discoveries, inspiring a new generation of scientists and engineers,” said Suzanne Dodd, project manager for Voyager at JPL. “We don’t know how long the mission will continue, but we can be sure that the spacecraft will provide even more scientific surprises as they travel farther away from the Earth.”
This graphic provides some of the mission’s key statistics from 2018, when NASA’s Voyager 2 probe exited the heliosphere. Credit: NASA/JPL-Caltech
More About the Mission
A division of Caltech in Pasadena, JPL built and operates the Voyager spacecraft. The Voyager missions are a part of the NASA Heliophysics System Observatory, sponsored by the Heliophysics Division of the Science Mission Directorate in Washington.
Voyager 2 20 Ağustos 1977’de fırlatıldı, ardından 5 Eylül’de Voyager 1 geldi. Her iki sonda da Jüpiter ve Satürn’e gitti, Voyager 1 daha hızlı hareket etti ve onlara önce ulaştı. Birlikte, sondalar güneş sisteminin en büyük iki gezegeni ve uyduları hakkında çok şey ortaya çıkardı. Voyager 2 ayrıca Uranüs’e (1986’da) ve Neptün’e (1989’da) yakın uçan ilk ve tek uzay aracı oldu ve insanlığa bu uzak dünyaların olağanüstü görüşlerini ve içgörülerini sundu.