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Pierre Janssen
Pierre Janssen
Pierre Janssen
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Jules Janssen; photograph by Nadar (date unknown)
Photo taken by Janssen, from the Meudon observatory, of Renard and Krebs' La France dirigible (1885)

Pierre Jules César Janssen (22 February 1824 – 23 December 1907), usually known as Jules Janssen, was a French astronomer who, along with English scientist Joseph Norman Lockyer, is credited with discovering the gaseous nature of the solar chromosphere, and with some justification the element helium.

Life, work, and interests

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Janssen was born in Paris (During Bourbon Restoration in France) into a cultivated family. His father, César Antoine Janssen (born in Paris, 1780 – 1860) was a well known clarinettist from Dutch/Belgian descent (his father, Christianus Janssen, emigrated from Walloon Brabant to Paris). His mother Pauline Marie Le Moyne (1789 – 1871) was a daughter of the architect Paul Guillaume Le Moyne.[1]

Pierre Janssen studied mathematics and physics at the faculty of sciences. He taught at the Lycée Charlemagne in 1853, and in the school of architecture 1865 – 1871, but his energies were mainly devoted to various scientific missions entrusted to him. Thus in 1857 he went to Peru in order to determine the magnetic equator; in 1861–1862 and 1864, he studied telluric absorption in the solar spectrum in Italy and Switzerland; in 1867 he carried out optical and magnetic experiments at the Azores; he successfully observed both transits of Venus, that of 1874 in Japan, that of 1882 at Oran in Algeria; and he took part in a long series of solar eclipse-expeditions, e.g. to Trani, Italy (1867), Guntur, India (1868), Algiers (1870), Siam (1875), the Caroline Islands (1883), and to Alcossebre in Spain (1905). To see the eclipse of 1870, he escaped from the Siege of Paris in a balloon.[2] Unfortunately the eclipse was obscured from him by cloud.[3]

In the year 1874, Janssen invented the Revolver of Janssen or Photographic Revolver, instrument that originated the chronophotography. Later this invention was of great use for researchers like Etienne Jules Marey to carry out exhibitions and inventions.

Discovery of helium

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In 1868 Janssen discovered how to observe solar prominences without an eclipse. While observing the solar eclipse of 18 August 1868, at Guntur, Madras State (now in Andhra Pradesh), British India, he noticed bright lines in the spectrum of the chromosphere, showing that the chromosphere is gaseous. Present in the spectrum of the Sun, though not immediately noticed or commented upon, was a bright yellow line later measured to have a wavelength of 587.49 nm. This was the first observation of this particular spectral line, and one possible source for it was an element not yet discovered on the earth. From the brightness of the spectral lines, Janssen realized that the chromospheric spectrum could be observed even without an eclipse, and he proceeded to do so.[citation needed][4]

On 20 October, Joseph Norman Lockyer in England set up a new, relatively powerful spectroscope. He also observed the emission spectrum of the chromosphere, including the same yellow line. Within a few years, he worked with a chemist and they concluded that it could be caused by an unknown element, after unsuccessfully testing to see if it were some new type of hydrogen. This was the first time a chemical element was discovered on an extraterrestrial body before being found on the earth. Lockyer and the English chemist Edward Frankland named the element after the Greek word for the Sun, ἥλιος (helios).[5][6]

Observatories

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Passage de Venus (1874)

At the great Indian eclipse of 1868 that occurred in Guntur, Janssen also demonstrated the gaseous nature of the red prominences, and devised a method of observing them under ordinary daylight conditions.[2][7] One main purpose of his spectroscopic inquiries was to answer the question whether the Sun contains oxygen or not. An indispensable preliminary was the virtual elimination of oxygen-absorption in the Earth's atmosphere, and his bold project of establishing an observatory on the top of Mont Blanc was prompted by a perception of the advantages to be gained by reducing the thickness of air through which observations have to be made. This observatory, the foundations of which were fixed in the hard ice that appeared to cover the summit to a depth of over ten metres, was built in September 1893, and Janssen, in spite of his sixty-nine years, made the ascent and spent four days making observations.[2][8]

In 1875, Janssen was appointed director of the new astrophysical observatory established by the French government at Meudon, and set on foot there in 1876 the remarkable series of solar photographs collected in his great Atlas de photographies solaires (1904). The first volume of the Annales de l'observatoire de Meudon was published by him in 1896.[2] (see also Meudon Great Refractor)

Janssen was the President of the Société Astronomique de France (SAF), the French astronomical society, from 1895 to 1897.[9]

International Meridian Conference

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In 1884 he took part in the International Meridian Conference.[10]

Death, honors, and legacy

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Janssen's grave in Paris

Janssen died at Meudon on 23 December 1907 and was buried at Père Lachaise Cemetery in Paris, with the name "J. Janssen" inscribed on his tomb. During his life he was made a Knight of the Legion of Honor and a Foreign Member of the Royal Society of London.[citation needed]

Craters on both Mars[11] and the Moon are named in his honor. The public square in front of Meudon Observatory is named Place Jules Janssen after him. Two major prizes carry his name: the Prix Jules Janssen of the French Astronomical Society, and the Janssen Medal of the French Academy of Sciences.[citation needed]

Janssen named minor planet 225 Henrietta discovered by Johann Palisa, after his wife, Henrietta.[12]

Notes and references

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Further reading

[edit]
Revisions and contributorsEdit on WikipediaRead on Wikipedia

Pierre Janssen

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from Grokipedia
Pierre Jules César Janssen (1824–1907), commonly known as Jules Janssen, was a pioneering French astronomer best known for co-discovering the element helium through solar spectroscopy and for his foundational work in solar photography and high-altitude astronomical observations. Born on February 22, 1824, in Paris, Janssen suffered a childhood accident that left him unable to walk regularly, yet he pursued studies in mathematics and physical sciences at the Sorbonne, graduating in 1852 and earning a doctorate in 1860. Early in his career, he demonstrated the presence of water vapor in the solar atmosphere by analyzing dark lines in the solar spectrum in 1862, advancing the understanding of solar composition. His passion for astronomy led to global expeditions, including observations in Peru, Italy, Switzerland, and a daring trip to India for the total solar eclipse on August 18, 1868, where, using a spectroscope in Guntur, he identified a new yellow spectral line (D3) in the Sun's chromosphere at approximately 588 nanometers—distinct from known elements like sodium—indicating an unknown substance later confirmed as helium on Earth in 1895. Janssen's independent findings were published alongside those of English astronomer Joseph Norman Lockyer, who observed the same line on October 20, , in , with both papers reaching the on the same day, sharing credit for the breakthrough. He further innovated by developing methods to observe solar prominences and spectral lines without waiting for eclipses, such as during ascents, including a perilous 1870 flight in the hot-air balloon La Volta amid the Franco-Prussian War's siege of Paris, covering 225 miles to attempt eclipse observations in despite overcast skies. Elected to the Académie des Sciences in , Janssen became a professor of astronomy at the École Spéciale d'Architecture in 1865 and later directed the newly established Meudon Observatory from 1875 until his death, where he pioneered systematic solar photography, amassing over 6,000 images compiled in his 1904 publication Atlas de Photographies Solaires. Janssen's legacy extends to his role as a delegate at the 1884 and his enduring impact on , with his spectroscopic techniques and photographic atlas influencing subsequent generations of astronomers until his death on December 23, 1907, in .

Early Life and Education

Birth and Family Background

Pierre Jules César Janssen was born on 22 February 1824 in , , into a bourgeois middle-class family where played a central role in daily life. His father, Antoine-César Janssen (1781–1860), was a talented of Belgian descent, specializing in the ; he even invented mechanical improvements like key rollers for the instrument, providing Janssen with early immersion in musical traditions and creativity. Janssen's mother, Marie-Pauline Le Moine (1789–1871), contributed to the family's intellectual atmosphere through her lineage as the daughter of the acclaimed Paul-Guillaume Le Moine, a laureate who designed key Parisian landmarks such as the Bourse and the Église de la Madeleine, fostering an environment that encouraged curiosity and exploration of knowledge. No siblings are recorded in historical accounts, but the household dynamics emphasized artistic and cultural pursuits, offering Janssen exposure to , , and the sciences amid the family's modest means; a financial reversal around 1840 further shaped this setting by necessitating his early contributions to the household. An accident in early childhood left Janssen permanently lame, confining him to home life without formal schooling and allowing self-directed study in an era when Paris, during the Bourbon Restoration following the , buzzed with cultural revival and emerging scientific institutions that indirectly influenced his surroundings.

Academic Training and Influences

Pierre Janssen, born in on 22 1824, experienced a childhood accident that left him lame and limited his early formal schooling. Tutored at home initially, he was largely self-educated before pursuing higher education. Financial constraints led Janssen to work as a bank clerk starting at age 16, during which time he self-studied to prepare for university. He entered the (Sorbonne) and earned his licence ès sciences in and physical sciences in 1852. In 1860, Janssen completed his doctorate at the with a on the absorption of radiant heat by the eye, marking the culmination of his formal academic training. His studies fostered an early interest in , complemented by self-taught knowledge of , which would later prove instrumental in his astronomical pursuits. A key formative influence came from the spectroscopic advancements of and , whose 1859 work on solar radiation inspired Janssen's initial experiments with the solar spectrum around 1862. Following his degree, he served briefly as a at the Lycée Charlemagne in 1853, bridging his academic preparation to scientific application.

Scientific Career and Contributions

Early Astronomical Work

Janssen's mathematical training at the , where he graduated in 1852, equipped him with the computational expertise essential for early astronomical calculations, such as determining celestial positions. Janssen was among the pioneers in integrating into astronomical practice, producing some of the earliest astro-photographic plates to record celestial phenomena, which laid the groundwork for more accurate and objective observations.

Development of Solar Spectroscopy

Pierre Janssen's contributions to solar spectroscopy began with his early adoption of photography as a tool for capturing solar images, serving as a precursor to more advanced spectroscopic techniques. In 1862, at his private observatory in , , he initiated systematic solar observations using photographic methods to record direct images of the Sun's surface, laying groundwork for quantitative analysis of solar features. A key innovation came with Janssen's design of the photoheliograph in 1862, an instrument tailored for precise direct solar imaging without the distortions common in earlier setups. This device featured an achromatized telescope optimized for violet wavelengths and a specialized shutter mechanism, enabling high-resolution photographs that revealed detailed solar surface structures and atmospheric phenomena. The photoheliograph allowed for repeated exposures under varying conditions, facilitating the study of solar dynamics through visual records rather than transient visual observations alone. Janssen pioneered the application of to solar prominences, developing a method to observe them independently of s. During his 1868 expedition, he realized that by positioning the spectroscope's slit tangent to the solar limb—effectively excluding the bright photospheric continuum—the of the prominences could be isolated. This technique rendered the bright emission lines of the prominences visible against a dark background even in full daylight, transforming them from rare eclipse events into routine observables. The method relied on the contrast between the prominence's gaseous emissions, primarily lines like H-alpha, and the surrounding sky, allowing continuous monitoring of their form, motion, and composition. In a seminal 1868 publication, Janssen detailed his analysis of the solar atmosphere, reporting observations of spectral lines from the and prominences. He described a prominent line at approximately 587 nm, distinct from the sodium D lines, which appeared in the during daylight observations; this line was later confirmed as the signature of . The work emphasized the gaseous nature of the solar atmosphere, with dominating the prominences, and provided the first systematic evidence for elevated temperatures in these structures, reaching thousands of degrees . Janssen's findings, based on slit spectrography, underscored the potential of for probing solar chemistry without total obscuration. To support fieldwork, Janssen constructed portable spectroscopes optimized for rugged and high-altitude use. These instruments employed direct-vision designs inspired by Giovanni Amici's prisms, featuring a compact arrangement of multiple prisms—typically a central element flanked by crown glass ones—to achieve dispersion without inverting the image. Measuring around 20-30 cm in length and weighing under 5 kg, they included adjustable slits (0.1-1 mm width) and oculars for immediate spectral viewing, mounted on lightweight tripods compatible with 4-6 inch telescopes. Such portability enabled precise observations from balloons, mountains, and remote sites, minimizing atmospheric interference and enhancing resolution of faint solar lines at elevations up to 4,000 meters.

Key Expeditions and Discoveries

Eclipse Observations and Helium Identification

In 1868, Pierre Janssen led an expedition to , , to observe the total of , where he employed spectroscopic techniques to analyze the solar prominences during the brief period of totality. Using a spectroscope attached to a , Janssen identified a previously unknown bright yellow in the prominences at a of 587.49 nm, distinct from the sodium D-lines at 589 nm, suggesting the presence of an unidentified element in the Sun's atmosphere. This observation marked the first detection of , though its terrestrial confirmation would not occur until 1895. The expedition faced significant logistical challenges, including a arduous overland journey from Madras amid the season, the need to hastily assemble and calibrate delicate spectroscopic equipment on-site, and unfavorable weather that obscured the sky immediately after totality, preventing further immediate analysis. Janssen's report, dispatched via ship and overland mail, took nearly two months to reach the , nearly resulting in the loss of priority for the discovery. Independently, English astronomer observed the same 587.49 nm line in October 1868 from , using a modified spectroscope to isolate solar rim emissions during daylight without an , confirming Janssen's finding and co-establishing 's existence through their simultaneous publications to the . proposed the name "" from the Greek "" for sun, hypothesizing it as a new element absent on Earth.

Other Global Expeditions

Janssen participated in the French expedition to observe the 1874 , traveling by ship from to and then to , , a journey lasting several months during which he performed preliminary stellar and solar observations to calibrate instruments under varying sea conditions. In , he employed his innovative photographic revolver—a rotating cylinder with 24 plates—to capture sequential images of crossing the solar disk, overcoming challenges like potential and precise timing synchronization essential for measurements. The expedition fostered cultural encounters, including collaborations with Japanese officials and astronomers, highlighting Janssen's to local while advancing global solar research. For the 1882 transit of Venus, Janssen established an observation station in , , utilizing advanced photographic techniques to record the event and contribute to refined calculations of the solar parallax, which helped establish the Earth-Sun distance at approximately 149.5 million kilometers. The North African location offered favorable viewing geometry but presented logistical hurdles, such as transporting heavy equipment across the Mediterranean and managing dust interference in spectra. These efforts built on his prior helium-related discoveries, motivating sustained international pursuits in solar spectroscopy. In the 1870s, Janssen pioneered high-altitude balloon ascents to probe the upper atmosphere and obtain clearer solar spectra by minimizing ground-level water vapor absorption. Notable flights, including one aboard the Volta reaching 1,000 meters, allowed in-situ measurements of atmospheric composition and pressure variations, revealing reduced telluric lines in solar observations and informing early models of atmospheric layers. These daring ventures, often in collaboration with aeronauts like Eugène Godard, underscored the risks of extreme cold and navigation errors but yielded data crucial for distinguishing solar from terrestrial spectral features. Beyond transits, Janssen mounted expeditions for solar photography to regions including in 1871, in 1870 at , and in 1875 at Siam, targeting diverse latitudes to capture variations in solar activity and atmospheric effects. In , he documented solar prominences and faculae using portable spectrographs, navigating disruptions and supply shortages that tested equipment durability. African outings in focused on solar imaging, contending with arid heat warping plates, while Siamese travels involved river transport challenges for photographing chromospheric lines. These ventures to the and beyond emphasized mobile fieldwork's role in building a comprehensive solar atlas, despite cultural barriers and variable weather impacting exposure times.

Institutional Roles and Infrastructure

Founding of Observatories

In the mid-1860s, Pierre Janssen played a pivotal role in advancing solar research at the , where he directed the solar section starting in 1867, focusing on spectroscopic observations of the Sun to integrate physical methods into astronomy. Janssen's vision for dedicated solar facilities culminated in the establishment of the Meudon Observatory in 1875, with initial observations commencing in 1876 under his directorship; this institution was conceived as a specialized center for , emphasizing and to study the Sun's atmosphere and surface features. The observatory repurposed the historic , receiving substantial government funding after 1880, supplemented by private contributions from patrons such as the Bischoffsheim, Bonaparte, and families, coordinated through a society led by Léon Say, which enabled rapid development of infrastructure. Key design features included rotating cupolas for optimal solar tracking: a large 18.5-meter dome a double refractor (83 cm visual objective and 62 cm photographic objective, with a 16-meter ) constructed by the Henry brothers, and a smaller dome for the photoheliograph dedicated to high-resolution solar imaging. A 100 cm Newtonian reflector was installed in a 7.5-meter dome to support broader astronomical work, while outbuildings were adapted for laboratories spectroscopic tools, including early spectroheliographs for monochromatic solar imaging. These installations allowed continuous monitoring of , independent of eclipses, and fostered interdisciplinary approaches blending , photography, and physics. During the 1890s, under Janssen's ongoing leadership, underwent significant expansions to incorporate atmospheric physics, with laboratories established in the château's former stables for spectral analysis of terrestrial and solar gases, extending the observatory's scope to upper atmospheric composition and meteorological influences on solar observations. By 1893, the completion of major constructions solidified 's status as a leading European hub for solar and atmospheric research, with Janssen overseeing international exchanges of and instruments to enhance global solar monitoring efforts.

Participation in International Conferences

Pierre Janssen played a pivotal role in international efforts to standardize astronomical measurements and timekeeping during the late , representing in key diplomatic and scientific forums focused on meridian and issues. His involvement underscored the intersection of astronomy, , and global policy, emphasizing impartiality and scientific utility over national interests. In the , efforts at geodetic conferences laid groundwork for meridian standardization, building on earlier European geodetic initiatives from the , where French astronomers contributed to arc measurements and meridian alignments through work. The Seventh International Geodesic Conference in in highlighted the need for international consensus to resolve ongoing discrepancies in measurements. Janssen's most prominent diplomatic engagement came as France's delegate to the in , from October 1 to 22, 1884, where he served as one of three secretaries alongside representatives from Britain and . Representing the Physical Observatory of Paris, he led discussions on selecting a , proposing neutral locations such as the , , or the 168th meridian west in the Pacific to avoid favoring any nation's commercial or colonial interests. He argued that the choice should prioritize geographical neutrality and moral equity, using astronomy merely as a tool for precision rather than a basis for selection, and opposed the Greenwich meridian due to its perceived national bias despite Britain's hydrographic advancements. Janssen requested delays in voting to foster deeper debate on principles and submitted resolutions for further study, ultimately voting against the adoption of Greenwich. His observatories at and provided essential data for meridian observations during these talks. Throughout the conference, Janssen contributed significantly to deliberations on and standards, emphasizing a "universal day" reckoned from a fixed meridian to synchronize global and . He supported flexible voting procedures like "ad " to accommodate diverse national positions and proposed resuming studies on divisions for time and angular measurements, drawing on historical French work by Laplace and Delambre; this resolution passed overwhelmingly with 21 votes in favor. Although the conference ultimately adopted the Greenwich meridian and a universal day based on —resolutions that influenced the precursors to (UTC) by establishing international time zones—Janssen's advocacy for neutrality shaped the ethical framework of the debates and promoted collaborative standardization efforts. In the following decades, Janssen's influence extended to emerging astronomical collaborations, though his later roles were more national, such as presiding over the from 1895 to 1897, where he established the Prix Jules Janssen award to recognize outstanding astronomical work and fostered international exchanges on and timekeeping. His conference participations helped cement 's voice in global astronomical policy, prioritizing standardization for practical scientific advancement.

Later Years, Death, and Legacy

Final Contributions and Retirement

In the later stages of his career, following the 1890s, Pierre Janssen shifted his focus at the Observatory toward compiling comprehensive atlases and advancing research in . His studies emphasized distinguishing telluric absorption lines from solar origins in the spectrum, particularly investigating di-oxygen (O₂) features through high-altitude observations. These efforts built on earlier and expeditions but increasingly relied on instrumental advancements at , enabling systematic analysis of the solar envelope's composition without personal fieldwork. A major culmination of this work was the publication of Atlas de photographies solaires in 1904 (dated 1903 in some editions), which presented a curated selection of 30 high-quality images from over 6,000 photographic plates accumulated between 1876 and 1903. These photographs, typically capturing the Sun at a 30 cm diameter, showcased detailed views of the and established enduring standards for solar photography, remaining unmatched in quality for nearly five decades. The atlas not only documented solar surface features but also served as a foundational resource for subsequent astrophysical studies. As director of the Meudon Observatory until 1907, Janssen played a pivotal role in mentoring emerging astronomers, fostering the next generation of solar physicists. Notable protégés included Milan Stefanik, who collaborated on observations during a 13-day stay, and Aleksey Hansky, who conducted extended high-altitude research under Janssen's guidance for 12 days. Through these relationships and his oversight of the observatory's programs, Janssen ensured the continuity of spectroscopic and photographic techniques in French astrophysics. Although Janssen gradually withdrew from personal expeditions after his last Mont Blanc ascent in 1895—likely due to advancing age—he maintained active advisory roles, organizing approximately five annual missions to the site until its closure in 1907. This period marked a transition to supervisory contributions, supporting ongoing solar research at while concluding his directorial tenure upon his death that year.

Death and Posthumous Honors

Pierre Janssen died on December 23, 1907, in , near , , at the age of 83. He had spent his final years directing the Meudon Observatory, continuing his pioneering work in until health issues confined him. Janssen was buried in in , where his tomb bears the inscription "J. Janssen." Throughout his career, Janssen received numerous prestigious honors for his astronomical contributions. In 1868, he was awarded the Lalande Prize by the in recognition of his spectroscopic observations during the that year, which led to the identification of . He also received the from the Royal Society in 1876 for his advancements in solar spectroscopy and photography. Additionally, he was appointed a Knight of the in 1868 and elected a Foreign Member of the Royal Society. Posthumously, Janssen's legacy has been commemorated in several ways. In 1935, the named a prominent lunar crater Janssen in his honor, located on the southeastern limb of the . The element , first detected through his observations of solar prominences, was named after the Greek god , indirectly honoring Janssen's role in revealing the Sun's composition before its terrestrial discovery. His foundational techniques in solar spectroscopy continue to influence modern solar observatories, such as those studying the Sun's atmosphere from . In recent years, awards like the Prix Jules Janssen and the Janssen Medal, established in his name by the Société Astronomique de France and the , respectively, perpetuate his impact on .

References

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  10. https://webusers.imj-prg.fr/~david.aubin/publis/2002b.pdf
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  26. https://saf-astronomie.fr/en-janssen-prize/
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