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2012 transit of Venus

The 2012 transit of Venus was a rare astronomical alignment in which passed directly between and , appearing as a small, dark traversing the Sun's disk over a period of approximately 6 hours and 40 minutes. The event began at 22:09 UTC on , 2012 (June 6 in some time zones), with Venus reaching its closest point to the Sun's center at 01:29 UTC, and concluded at 04:49 UTC on June 6. This transit marked the second and final occurrence in a pair separated by eight years from the 2004 event, with the next pair not visible until 2117 and 2125, making it the last Venus transit observable in the . Visibility of the full transit was limited to regions in the western , eastern , eastern , and parts of the above 67° north , such as northern , , and , where the entire passage could be seen from start to finish. Partial views were available across much of North and (sunset phase on June 5), and western (sunrise phase on June 6), eastern , and western , though safe observation required filters, glasses, or telescopes to avoid eye damage from direct sunlight. Venus's path crossed the from northeast to southwest, with a minimum separation of 554 arcseconds from the solar center, exhibiting the optical "black drop effect" near the midpoints of ingress and egress due to atmospheric . Historically, transits of like the one in echoed 18th- and 19th-century expeditions that used measurements from multiple global sites to refine the Earth-Sun distance, establishing the (AU) with unprecedented accuracy for the era. Although modern radar and spacecraft have surpassed these methods for solar system measurements, the 2012 event held renewed scientific value in calibrating transit light curves and studying Venus's atmosphere through high-resolution imaging, including from 's (SDO), which captured ultra-high-definition footage of the silhouette's passage. It also served as a terrestrial analog for detection techniques, demonstrating how repeated transits reveal planetary sizes, orbits, and potential atmospheres via the dimming of stellar light. The transit sparked global interest, with millions participating in public viewings, educational programs, and live webcasts organized by institutions like and the Smithsonian National Air and Space Museum, which hosted events in Washington, D.C., and streamed observations from , . Amateur astronomers worldwide contributed timing data on Venus's contacts with the Sun's limb, aiding refinements in models, while professional observatories documented the event to advance outreach and international collaboration.

Historical Context

Transits of Venus overview

A occurs when the planet passes directly between and , appearing as a small, dark silhouette traversing the face of the solar disk. This rare alignment requires Venus to cross the plane near inferior , where its orbit intersects 's , due to Venus's of approximately 3.4 degrees relative to the . The governing these events stem from Venus's sidereal period of 224.7 days and its synodic period with of 583.92 days, which dictate the timing of conjunctions. As predicted by Kepler's laws, transits occur in pairs separated by about 8 years, reflecting the near-repeat of Venus's orbital position relative to and ; subsequent pairs then recur after intervals of either 105.5 or 121.5 years, resulting in an overall cycle of roughly 243 years. This pattern arises because the nodes where Venus's orbit crosses the precess slowly, altering the alignment opportunities over centuries. The first recorded observation of a Venus transit took place on December 4, 1639 (Julian calendar), by English astronomers Jeremiah Horrocks and William Crabtree, who independently viewed the event from locations in Lancashire using rudimentary telescopes. Horrocks had predicted the transit based on Kepler's Rudolphine Tables, marking a pivotal moment in applying heliocentric models to forecast planetary alignments. Subsequent transits in 1761 and 1769 spurred international expeditions, including efforts by astronomers like James Cook to Tahiti and Guillaume Le Gentil to India, aimed at measuring the Sun's parallax through the differing timings of Venus's ingress and egress from global observation sites. These observations refined estimates of the Earth-Sun distance, advancing solar system scale measurements despite challenges like cloudy weather and the "black drop effect." Transits of Venus are exceptionally infrequent, with only twelve predicted between 1600 and 2400, underscoring their status as one of the rarest predictable astronomical phenomena observable from . The 2012 event concluded the most recent pair in this sequence, visible from much of the inhabited world.

The 2004–2012 pair

The prediction of Venus transits for solar parallax measurement traces back to , who in 1716 outlined a to determine the Sun-Earth distance by observing the timing differences of a from multiple earthly locations, emphasizing the value of paired events eight years apart. Modern astronomical computations, refined through ephemerides and , confirmed the dates of the contemporary pair as June 8, 2004, and June 5–6, 2012, aligning with the predictable recurrence of such alignments. The 2004 transit occurred on June 8, lasting approximately 6 hours and 12 minutes from at 05:13 UT to at 11:26 UT, during which Venus appeared as a small dark silhouette traversing the Sun's disk. It was widely visible across , , and , where the full event could be observed under clear skies, while partial phases were seen in eastern , the , and parts of at sunrise, and in and the Pacific at sunset. Key observations included ground-based imaging from numerous sites worldwide and pioneering space-based views, such as high-resolution optical images captured by the Transition Region and Coronal Explorer () satellite, which provided detailed views of Venus's silhouette against the solar surface. In contrast to the transit, which crossed the Sun's , the event followed a through the , resulting in a slightly different apparent trajectory relative to features. Public anticipation for the transit was notable but comparatively subdued, with significant media coverage yet less widespread global outreach than the feverish buildup to , partly due to the latter being the final observable event in the pair within a lifetime. This 2004–2012 pair exemplifies the characteristic eight-year interval between transits, arising from the near-resonance between Venus's of 224.7 days and Earth's 365.3 days, which aligns their inferior conjunctions every 583.9 days but only produces transits in such close pairs due to orbital inclinations. Following this duo, the next pair will not occur until December 10–11, 2117, and December 8, 2125, marking over a century's gap in visibility.

Astronomical Details

Timing and geometry

The 2012 transit of Venus commenced on June 5 at 22:09:38 UTC with (Contact I), when the leading edge of Venus began to overlap the solar disk. Second contact occurred at 22:27:34 UTC, marking the start of the full as Venus was entirely within the Sun's disk. The event concluded on June 6 with third contact at 04:31:39 UTC and fourth contact at 04:49:35 UTC, yielding a total duration of approximately 6 hours and 40 minutes from first to fourth contact, or about 6 hours and 4 minutes for the fully internal phase from second to third contact. Geometrically, Venus traversed the Sun's disk from east to west across its northern hemisphere, beginning near the northeast solar limb and ending near the northwest limb. At the time of transit, Venus's angular diameter measured nearly 1 arcminute (approximately 58 arcseconds), appearing as a small dark silhouette against the Sun's much larger disk of about 32 arcminutes in diameter. The path's position angle was approximately 38° to 41° at ingress and 290° to 293° at egress, indicating a transit centered in the Sun's northern region relative to the celestial equator. Venus moved at a relative angular speed of about 4 arcminutes per hour across the solar face. During ingress and egress, the black drop effect—a temporary elongation or "teardrop" appearance linking Venus's disk to the solar limb—could have been observed, primarily due to the Sun's and optical limitations, though modern equipment minimized its impact on timing precision. The timing of the 2012 transit was determined by Venus reaching inferior conjunction on , when its position aligned such that the geocentric was near zero degrees, adjusted for the 3.4° inclination of Venus's orbit relative to the to confirm the disk-crossing path; this follows the basic predictive form T ≈ n × S, where S is Venus's synodic period of 583.92 days and n is an integer multiple selected to match nodal alignments. This event formed the second of the 2004–2012 pair of transits.

Visibility from Earth

The 2012 transit of Venus was fully visible from locations where the entire duration of the event could be observed above the horizon, primarily in the , eastern , , eastern , northern , and regions above approximately 67° N latitude, such as northern and . In these areas, observers could witness all four contacts—from Venus's initial ingress to its final egress across the solar disk—under clear skies. Partial visibility occurred in the , where the transit's beginning phases were observable as the Sun set on June 5, and in , western and , eastern , and western , where the ending phases appeared at sunrise on June 6. The path of visibility traced an umbral track across the globe, with the greatest transit—when reached the center of the solar disk at 01:29:36 UTC on June 6—best seen from the northern Pacific, including . Safe observation required solar filters to protect against the Sun's intense brightness, as direct viewing without protection could cause permanent eye damage; telescopes and needed certified solar filters over their apertures. In mid-latitude regions experiencing partial visibility, challenges arose from the Sun's low position near the horizon, potentially limiting clear views due to or obstructions. Visibility maps, such as those produced by , illustrated the global zones with shaded regions indicating full, partial, and annular paths, highlighting the umbral track's concentration over the Pacific for optimal viewing.

Observations

Ground-based observations

Ground-based observations of the 2012 transit of Venus involved extensive public engagement across multiple continents, particularly in regions of optimal visibility such as the Pacific and Australia. Major viewing events drew large crowds, with thousands attending free public sessions at Griffith Observatory in Los Angeles, where telescopes equipped for safe solar viewing were set up on the grounds. In Hawaii, NASA partnered with the University of Hawaii Institute for Astronomy to broadcast live from the summit of Mauna Kea, allowing remote participation while local events at lower elevations, such as those organized by the Hawaii Space Grant Consortium, attracted dozens of attendees for direct viewing during the early stages of the transit. Sydney Observatory in Australia hosted a sell-out public event that saw over 1,500 participants, contributing to widespread enthusiasm amid generally favorable weather along the east coast. These gatherings highlighted the event's rarity, as the next transit would not occur until 2117. Observers employed specialized equipment to safely capture the transit, including solar telescopes fitted with (H-alpha) filters to highlight chromospheric details and methods to avoid direct eye to the sun's intense . Baader solar film filters were commonly used on and professional setups for white-light projections, enabling group viewings at public sites. networks coordinated efforts to record precise timings of the transit's contacts, with organizations like the Association of Lunar and Planetary Observers (ALPO) encouraging members to contribute observational data through standardized protocols, though the focus remained on solar-safe practices rather than monitoring. Weather posed significant challenges, particularly in Pacific viewing zones where cloud cover intermittently obscured the event; in , scattered clouds affected ground-level observations despite the summits' clearer skies, with reports noting frustration among attendees as partial blockages occurred during key phases. The black drop effect, a historical where appears connected to the solar limb by a dark filament, was successfully observed at multiple sites, including the Mees Solar Observatory on , confirming earlier accounts and demonstrating the impact of atmospheric seeing and . Citizen science initiatives built on the legacy of the 2009 International Year of Astronomy (IYA2009) by mobilizing global participants to collect timestamped images and contact timings from diverse locations, aiding measurements to refine solar system scale estimates. Projects like those from Astronomers Without Borders integrated mobile mapping tools to log observations, fostering public involvement in scientific data gathering without requiring advanced expertise. These efforts emphasized safe viewing and precise documentation, contributing valuable datasets to astronomical archives.

Space-based observations

Space-based observations of the 2012 transit of Venus provided unprecedented clarity and detail, free from Earth's atmospheric distortion, enabling high-resolution imaging across multiple wavelengths. NASA's (SDO), launched in 2010, captured the event in (EUV) and visible light wavelengths, producing ultra-high-definition footage at resolutions up to . The SDO's Atmospheric Imaging Assembly (AIA) instrument recorded the full transit sequence, including the ingress and egress phases on June 5-6, 2012, revealing fine details of Venus's against the Sun's without any from terrestrial weather or turbulence. These observations, spanning multiple solar filters, highlighted the transit's geometry and Venus's atmospheric edge effects in exquisite detail. From the (ISS), astronaut Don Pettit documented the transit using a Nikon D2XS equipped with an 800 mm and a full-aperture white-light solar filter, marking the first such photographs taken from human-occupied orbit. On June 5, 2012, Pettit captured a series of images showing Venus's disk crossing , with the ISS's orbital motion providing dynamic perspectives over several hours. Real-time video streams from the ISS, integrated with NASA's coverage, allowed global audiences to follow the event live from space. The European Space Agency's (ESA) orbiter, in operation around since 2006, marked the first transit observed by a in Venusian . Although direct imaging of the transit was constrained by the spacecraft's orientation and instrumentation focused on Venus itself, the mission conducted special atmospheric observations during on June 6, 2012, using instruments like the Venus Monitoring Camera (VMC) and SPICAV/SOIR for limb profiling and studies. These efforts complemented Earth-based data by providing in-situ measurements of 's upper atmosphere during the alignment, including insights into refractive effects near the planet's limb. Japan Aerospace Exploration Agency's () Hinode satellite, a joint mission with and ESA, used its Solar Optical Telescope (SOT) to image the transit in visible light, capturing Venus's passage across the solar disk on June 6, 2012. The high-resolution images distinctly showed the brightening of Venus's rim, resembling a ring, caused by refracted through the planet's dense atmosphere—a phenomenon invisible from ground level due to . Hinode's observations emphasized the transit's optical intricacies, contributing to a global dataset of solar-planetary interactions. NASA TV's live streams of the transit, incorporating feeds from SDO, Hinode, and ISS, garnered nearly 2 million total views worldwide by midway through the event on June 5, 2012, with peak concurrent audiences exceeding 90,000 viewers.

Scientific Research

Atmospheric studies

During the 2012 transit of Venus, observations revealed the planet's atmosphere causing a luminous halo, or aureole, around the disk edges, particularly evident as an apparent "smearing" effect during ingress and egress phases. This phenomenon arises from sunlight refracting through the dense CO₂-dominated layers, bending rays and extending the visible limb by up to several arcseconds perpendicular to the solar disk. Ground-based and space-based imaging, such as from the (SDO), captured this refraction, allowing models to quantify the deflection angles, which reached approximately 1° at altitudes around 55 km above the surface. The aureole's brightness and shape provided insights into within the CO₂-rich upper atmosphere, where molecular scattering contributes to the continuum opacity, though haze extinction dominates above 85 km. Theoretical transmission spectra predicted deeper molecular absorption bands at mid-transit due to this scattering, with CO₂ as the primary contributor, enabling validation against transit models. Observations confirmed minimal Rayleigh influence compared to , with the halo confined to 1–2 aerosol scale heights (~4–8 km), highlighting the transition from hazy lower layers to clearer . The () contributed by observing reflected sunlight from the , serving as a cosmic mirror to analyze light filtered through Venus's atmosphere without direct solar pointing. This setup, spanning seven hours around the , aimed to spectroscopically probe and as a benchmark for studies, capturing and visible wavelengths to trace atmospheric opacity variations. Although specific elemental detections like sodium or were not reported from these 2012 data, the method refined techniques for identifying upper atmospheric layers at 110–130 km altitudes in future analogs. Venus Express spacecraft data, including in-situ measurements from the SOIR instrument during the transit, confirmed atmospheric density profiles in the polar upper regions (130–190 km), revealing higher neutral densities than spherical models predicted at 150–170 km. These profiles, derived from solar occultations, indicated tangential column densities elevated by factors of up to 20 in extreme ultraviolet bands, improving simulations of exospheric escape processes driven by interactions. The integration of transit aureole photometry with Venus Express results yielded an updated scale height of 4.8 km, while the overall atmospheric remained consistent at 15.9 ± 0.3 km, enhancing models for transiting exoplanets with thick atmospheres.

Parallax and diameter measurements

During the 2012 transit of Venus, astronomers employed the parallax method by conducting multi-site observations to determine Venus's horizontal parallax relative to , thereby refining estimates of the solar parallax. For instance, simultaneous imaging from , and Haleakala, , , separated by approximately 7,835 km, captured the apparent shift in Venus's position across the solar disk due to the observers' baseline on Earth. This geometric displacement, when measured precisely, allowed calculation of the Earth-Sun distance. The π is given by π = (baseline / distance) in arcseconds, with 2012 observations utilizing baselines up to 10,000 km to verify the method's application. These efforts contributed to confirming the modern solar parallax value of 8.794143 ± 0.000010 arcseconds, corresponding to an of about 149.59787 million km. Measurements of Venus's apparent angular diameter during the transit provided valuable data for calibrating exoplanet transit observations, where similar silhouetting techniques estimate planetary radii. High-resolution images from ground-based telescopes recorded Venus's disk at an angular size of 58.64 ± 0.03 arcseconds, consistent with its physical diameter of 12,104 km at the transit's inferior conjunction distance of roughly 0.272 AU from Earth. This precision aids in refining models for transit light curves used in exoplanet detection surveys like Kepler, ensuring accurate scaling of inferred planetary sizes from stellar flux dips. To validate historical claims, researchers conducted reconstruction experiments using 18th-century refractors during the event, replicating Mikhail Lomonosov's 1761 observation of Venus's atmosphere via the aureole effect at ingress. These antique telescopes, with apertures around 50-100 mm, successfully detected the atmospheric "arc" as Venus's limb refracted sunlight, confirming Lomonosov's detection was feasible with period and aligning with 2012 high-fidelity data on the planet's . The experiments underscored the transit's utility for geometric measurements, bridging 18th-century techniques with modern verification.

Legacy and Impact

Public engagement and education

The 2012 transit of Venus spurred numerous educational programs worldwide, leveraging the event to teach concepts in astronomy and . One prominent initiative, the Hetu'u , engaged 19 school groups across six continents and 10 countries in observing the transit to measure the Earth-Sun distance using , a method that demonstrates planetary alignments and relative motion. Similarly, NASA's Education Flight Projects collaborated with the Science Mission Directorate to offer transit-related activities, enabling thousands of students to participate in simulations and observations that highlighted solar system dynamics. Citizen science efforts amplified public involvement, allowing amateur observers to contribute meaningful data. A collaboration between and Astronomers Without Borders launched the ToV2012 web map and iPhone app, enabling 25,000 participants globally to record Venus's ingress and egress timings in near real-time, which were aggregated to visualize worldwide observation sites and recreate historical distance measurements. encouraged users to submit images and timings via , integrating public contributions with professional data to estimate the . Complementary tools like NASA's Eyes on the Solar System app provided interactive 3D simulations of the transit, helping users explore orbital paths and visibility from . The event drew global participation, with viewing parties and educational outreach in over 100 countries where the transit was visible, from and to the . In Pacific islands like , observations connected to indigenous traditions, where ancient wayfinders used celestial events—including Venus's positions—for transoceanic voyages, echoing historical ties to European expeditions like Captain Cook's transit journey. The transit's legacy included heightened interest in among youth, as evidenced by NASA's post-event evaluations. These initiatives not only democratized astronomy but also sustained long-term engagement, with many educators reporting increased classroom focus on in subsequent years.

Cultural and media coverage

The 2012 transit of Venus garnered extensive media attention worldwide, with major outlets providing live coverage and special programming to highlight its rarity as the last such event until 2117. offered comprehensive live blogs, videos, and articles tracking the event's progress, including reactions from global observers and cultural commentary on its . published opinion pieces framing the transit as a moment of "wondrous ," emphasizing its role in inspiring astronomical among the public. In the UK, BBC's Horizon special drew millions of viewers, blending scientific explanation with the event's once-in-a-lifetime appeal. Andrea Wulf's book Chasing Venus: The Race to Measure the Heavens, released in conjunction with the event, tied the 2012 transit to 18th-century expeditions, underscoring themes of global collaboration in astronomy. Culturally, the transit symbolized the close of a 105-year cycle of paired events, evoking reflections on human exploration and the cosmos as an "end of an era" before the next occurrence in 2117. Artist Wolfgang Tillmans captured this through his 2012 inkjet print Transit of Venus, a multimedia work exploring celestial themes amid contemporary culture. Post-event literature and art referenced the transit in speculative fiction, linking its visual drama to broader narratives of planetary alignment and human insignificance. Global celebrations amplified its cultural reach, with festivals organized at key viewing sites. In Hawaii, the Bishop Museum hosted a dedicated Transit of Venus festival on June 5, featuring educational displays and public telescope viewings. Australia saw widespread events, including programs at the Australian Museum and astronomy society gatherings, where clear skies allowed thousands to witness the full passage. Social media buzz peaked with hashtags like #TransitOfVenus and #TOV2012, fostering real-time sharing of photos and experiences across platforms such as Twitter. In the years following, cultural reflections connected the transit to advances in exoplanet detection, noting how its observation method paralleled NASA's Kepler mission in identifying distant worlds via similar transits. Archives have preserved the event's visual legacy, with institutions like the Smithsonian Libraries collecting photos and historical comparisons, and compiling galleries of global images to document public fascination.

References

  1. [1]
    2012 Transit of Venus - NASA Eclipse
    Feb 28, 2012 · During the 2012 transit, Venus's minimum separation from the Sun is 554 arc-seconds (During the 2004 transit, the minimum separation was 627 arc ...
  2. [2]
    Transit of Venus on June 5th, 2012 | National Air and Space Museum
    May 11, 2012 · On June 5, 2012, solar telescopes around the world and in space will point to the Sun, marking another beat in the centuries-long dance of the planets.
  3. [3]
    2004 and 2012 Transits of Venus - NASA Eclipse
    Oct 12, 2011 · ... transits of Venus gave astronomers their first good value for the Sun's distance. The planet Mercury can also transit the Sun. Since Mercury ...Missing: significance | Show results with:significance
  4. [4]
    SDO's Ultra-high Definition View of 2012 Venus Transit - NASA SVS
    Jun 5, 2012 · On June 5 2012, SDO collected images of the rarest predictable solar event—the transit of Venus across the face of the sun. This event lasted ...
  5. [5]
    The June 2012 transit of Venus - Astronomy & Astrophysics
    On 5–6 June 2012 ground-based observers have the last opportunity of the century to watch the passage of Venus across the solar disk from Earth. Venus transits ...Missing: global | Show results with:global
  6. [6]
    Some Details About Transits of Venus | The Planetary Society
    May 22, 2012 · Transits of Venus follow a peculiar pattern -- two transits 8 years apart, then 105.5 years with no transits, then two transits 8 years apart, ...
  7. [7]
    ND Expert: The science behind the Transit of Venus | News
    May 29, 2012 · Only when Earth and Venus are both near the line where their orbital planes meet can a transit occur. “Kepler's math defined the relative orbits ...
  8. [8]
    First recorded transit of Venus - Physics Today
    Dec 4, 2015 · On this day in 1639, Jeremiah Horrocks and William Crabtree made the first known observations and recording of a transit of Venus.
  9. [9]
    William Crabtree and Jeremiah Horrocks - Linda Hall Library
    Dec 4, 2014 · William Crabtree and Jeremiah Horrocks were the only two people to observe the 1639 transit of Venus, one from Lancashire and the other from ...
  10. [10]
    TRACEvenus - Space Math @ NASA
    ... 1761 and 1769 transits of Venus from many parts of the world. From the parallax shifts they would measure, they would be able to measure this distance from ...
  11. [11]
    How The Transit Of Venus Helped Unlock The Universe - NPR
    Jun 5, 2012 · ... 1761 and 1769 transits of Venus. He noted that if Venus was observed ... parallax method and some trigonometry to get the much sought sun-Earth ...<|separator|>
  12. [12]
    Six Millennium Catalog of Venus Transits: 2000 BCE to 4000 CE
    Feb 24, 2012 · A Venus transit is when Venus passes between Earth and Sun. This catalog predicts 81 transits from 2000 BCE to 4000 CE, with 44 in June and 37 ...
  13. [13]
    2004 Transit of Venus - NASA Eclipse
    Oct 12, 2011 · Venus will transit the Sun on Tuesday, 2004 June 08. The entire event will be widely visible from the Europe, Africa and Asia as shown in the map in Figure 1.
  14. [14]
    TRANSIT OF VENUS 2004
    Jun 8, 2004 · OBSERVATION DESCRIPTION​​ SPATIAL SCALE AND RESOLUTION: During the transit, Venus's angular diameter was app. 58.2 arcseconds (12,104 km at 0.289 ...
  15. [15]
    The Venus Transit 2004 - ESO
    Still, there should be plenty of opportunities to make observations and it is very likely that the public interest will then equal, and quite possibly surpass, ...
  16. [16]
    The 2012 Transit of Venus - NASA ADS
    Public interest in the event reached a fever pitch, particularly in the U.S. On transit day, telescopes proliferated on sidewalks, crowds formed, and some ...
  17. [17]
    The Transit of Venus, 5th-6th June 2012 - Naked Eye Planets
    Venus had an apparent diameter of 58".2 (58.2 arcseconds) during the transit. The Sun's apparent diameter at this time of year is 31'.5 arcminutes (i.e. ...
  18. [18]
    2004 and 2012 Transits of Venus - EclipseWise
    During the next several hours, Venus gradually traverses the solar disk at a relative angular rate of approximately 4 arc-min/hr. ... arc-seconds in diameter. By ...Missing: arcminutes | Show results with:arcminutes
  19. [19]
    [PDF] Global Visibility of the Transit of Venus of 2012 June 05/06
    Region X - Beginning and end of Transit are visible, but the Sun sets for a short period around maximum transit. Region Y*. * Region Y - Beginning and end ...
  20. [20]
    Public Viewing of the Transit of Venus, June 5, 2012
    Jun 5, 2012 · On Tuesday, June 5, Griffith Observatory welcomed thousands of people for a once-in-a-lifetime free viewing of the transit of Venus.
  21. [21]
    Web Cast : Transit of Venus, Sun-Earth Day 2012 - NASA
    On June 5, 2012, we aired a live 'remote' webcast from Mauna Kea, Hawaii, through our partnership with the University of Hawaii Institute for Astronomy. The ...
  22. [22]
    2012 Transit of Venus - HSGC
    Jun 5, 2012 · From noon to 1 p.m. folks gathered to see the start and early stages of the transit and enjoyed the special solar viewers. They also watched a ...Missing: events | Show results with:events
  23. [23]
    Rare transit of Venus draws sky-gazers worldwide
    Jun 6, 2012 · Although broken cloud hampered the view for some, Sydney Observatory held a sell-out event with 1,500 people buying tickets to witness the rare ...<|separator|>
  24. [24]
    https://www.abc.net.au/science/articles/2012/05/23/3508538.htm
  25. [25]
    Transit of Venus viewed around the world - CBS News
    Jun 6, 2012 · "It's always the challenge of being in Hawaii - are you going to be able to see through the clouds," said Greg Mansker, 49, of Pearl City, as ...
  26. [26]
    https://ui.adsabs.harvard.edu/abs/2014AAS...22324716R/abstract
  27. [27]
    The 2012 solar transit of Venus - British Astronomical Association
    Sep 21, 2018 · The 2012 Jun 5-6 transit of Venus, with the result that few observers succeeded in viewing both transits of the planet, eight years apart.
  28. [28]
    Citizen Scientists Map Venus Transit | ArcNews - Esri
    Astronomers Without Borders and Esri teamed up to create a mobile and web application for citizen scientists to map the transit of Venus.Missing: IYA2009 legacy science
  29. [29]
    2012 Venus Transit - NASA Scientific Visualization Studio
    May 18, 2012 · The transit of Venus begins tomorrow, June 5, at about 6pm Eastern Daylight Time, or about 10pm Universal Time. It will last approximately 6 ...
  30. [30]
    Venus Transit From the Space Station - NASA
    Jun 6, 2012 · This image of the 2012 Venus Transit was taken by NASA Astronaut Don Pettit from aboard the International Space Station on June 5, 2012.Missing: Nikon D2XS
  31. [31]
    Astronaut to Take 1st Transit of Venus Pictures From Space
    Jun 1, 2012 · "I'll be using a high-end Nikon D2Xs camera and an 800mm lens with a full-aperture white light solar filter," Pettit said. Click here for ...
  32. [32]
    Venus Transit 2012 - Venus Express - ESA Cosmos
    The Venus transit which occurred on 6 June 2012 is the first which occurred while a spacecraft was in orbit around Venus.
  33. [33]
    VENUS EXPRESS - PDS/PPI Missions
    the Venus Transit (June 6th 2012). Special observations due to Venus Transit: - VIRTIS off pericentre observations. - SOIR grazing occultation - Limb ...Missing: perspective | Show results with:perspective
  34. [34]
    Hinode Views the 2012 Venus Transit - NASA
    the last instance of this rare phenomenon until 2117. Hinode is a joint JAXA/ ...
  35. [35]
    HINODE captured the transit of Venus across the Sun / Topics
    Jun 6, 2012 · The acquired images show that the rim of Venus was brightened like a ring due to sunlight that underwent a refraction bend through Venus' ...
  36. [36]
    The June 2012 transit of Venus - Astronomy & Astrophysics (A&A)
    In our Solar System, only Mercury and Venus are observable from Earth while transit- ing the Sun. Since Mercury's atmosphere is tenuous, the Venus transits of ...<|separator|>
  37. [37]
    Transmission spectrum of Venus as a transiting exoplanet⋆⋆⋆
    Dec 1, 2011 · 2a. Scattering – Important additional absorption is caused by diffusion processes: Rayleigh scattering from atmospheric CO2 and, to a lesser ...
  38. [38]
    Hubble Shoots The Moon During Venus Transit - NASA Science
    May 4, 2012 · During the transit of Venus across the Sun's face on June 5-6, 2012, the Hubble Space Telescope will be looking in the opposite direction – at the Moon.
  39. [39]
    Using the transit of Venus to probe the upper planetary atmosphere
    Jun 23, 2015 · First ever in situ observations of Venus's polar upper atmosphere density using the tracking data of the Venus Express Atmospheric Drag ...
  40. [40]
    European Unified Research on Observations of Venus using co ...
    Jun 19, 2017 · The observed atmospheric transmittance spectra are subsequently inverted to obtain vertical density profiles ... With the 6 June 2012 transit of ...
  41. [41]
    [PDF] Venus Transit Parallax Measurement - Robert Vanderbei
    From this, we can convert the measured separation of the two Venus silhouettes to radians: measured parallax = 26.315 px × 0.009183 radians 2460 px = 9.823 × ...
  42. [42]
    Glossary - Astronomical Applications Department
    The value for the solar parallax is 8.794143 arcseconds. parallax in altitude: the angular difference between the topocentric and geocentric direction ...
  43. [43]
    Experimental Reconstruction of Lomonosov's Discovery of Venus's ...
    Aug 27, 2012 · In this paper we report on experimental reenactments of Lomonosov's discovery with antique refractors during the transit of Venus June 5-6, 2012.
  44. [44]
    Experimental reconstruction of Lomonosov's discovery of Venus's ...
    Nov 7, 2013 · In this paper we report on experimental reenactments of Lomonosov's discovery with antique refractors during the transit of Venus June 5–6, 2012.
  45. [45]
    Measuring the Distance to the Sun with the Transit of Venus - NASA ...
    In total, our group (stationed at Easter Island, Chile) recruited 19 school groups spread over 6 continents and 10 countries to participate in our Hetu'u Global ...
  46. [46]
    https://www.nasa.gov/wp-content/uploads/2015/03/731036main_2012_ese_efp.pdf
  47. [47]
    Launchpad: Transits - NASA Science
    May 29, 2012 · Discover how scientists used the last Venus transit and a geometric technique called parallax to verify the distance between sun and Earth ...
  48. [48]
    Transit of Venus, Hawaiian Natives and the Cosmos
    Native Hawaiians were instrumental in helping westerners observe the transit of Venus in the 1800s.
  49. [49]
    https://www.theguardian.com/science/2012/jun/05/transit-of-venus-live-coverage
  50. [50]
    Transit of Venus – as it happened | Science | theguardian.com
    Jun 5, 2012 · 8.08pm: We've just passed the two-hour mark of Venus' 2012 transit of the sun, the last such transit of our lifetimes. The planet is about 30 ...
  51. [51]
    Transit of Venus: highlights from the once-in-a lifetime event
    Jun 6, 2012 · Venus passed between the sun and Earth, and we collected reactions, science and culture from the once-in-a lifetime transit
  52. [52]
    A transit of Venus, an age of wondrous science - CNN
    Jun 6, 2012 · Astronomers around the world are training their telescopes on the skies to watch the transit of Venus as it passes between Earth and the sun.
  53. [53]
    Chasing Venus: the Race to Measure the Heavens – review | Books
    Jan 29, 2013 · Chasing Venus: the Race to Measure the Heavens – review. This article is more than 12 years old. Andrea Wulf's stirring history of Venus ...
  54. [54]
    https://www.hawaiinewsnow.com/story/18708522/transit-of-venus/
  55. [55]
    Transit of Venus - Hawaii News Now
    Jun 5, 2012 · The Bishop Museum is holding a Transit of Venus festival with a series of programs for June 5, 2012! Venus will move across the face of the sun ...
  56. [56]
    Transit of Venus - The Australian Museum Blog
    Jun 6, 2012 · On Wednesday 6 June, 2012, we marvel at an astronomical rarity – the transit of Venus across the face of the sun.
  57. [57]
    Astronomical Society of the Pacific on X: "Great photo gallery of the ...
    Astronomical Society of the Pacific · @AstroSocietyPac. Great photo gallery of the Transit of Venus http://ow.ly/bo15E #TOV2012 · 1:50 AM · Jun 6, 2012. 4.<|separator|>
  58. [58]
    Venus' Transit and the Search for Other Worlds
    Jun 5, 2012 · On Tuesday, June 5 or 6, 2012, depending on your location, Venus will make its presence in the solar system visible from Earth's day side.Missing: significance | Show results with:significance
  59. [59]
    Transit of Venus - Smithsonian Libraries and Archives / Unbound
    The “Transit of Venus” occurs when the planet passes between the Earth and the Sun, a rare occasion that has happened only seven times since the year 1600.
  60. [60]
    Venus Transit 2012 Pictures: Last Looks for a Century
    Jun 6, 2012 · See shots of the "planet of love" crossing the face of the sun during the last transit of Venus until 2117.