Great conjunction
A great conjunction is an astronomical event in which the planets Jupiter and Saturn appear particularly close together in Earth's sky, occurring when Jupiter overtakes the slower-moving Saturn in their shared orbital path around the Sun.[1] These conjunctions happen approximately every 20 years due to the planets' orbital periods—Jupiter completes a revolution in about 12 years, while Saturn takes roughly 29 years—resulting in Jupiter "lapping" Saturn periodically.[2] From our vantage point, the planets can appear as little as 0.1 degrees apart during especially close approaches, though the actual distance between them remains vast, often exceeding 640 million kilometers.[2] The visibility and proximity of great conjunctions vary significantly across cycles, influenced by their positions relative to the zodiac and Earth's orbit; for instance, successive conjunctions trace a zigzag pattern across the sky, shifting through elemental triplicities (fire, earth, air, water) every 240 years.[3] A particularly rare "grand conjunction" or "greatest conjunction," marking the return to the starting zodiac point, occurs roughly every 960 years.[3] The most recent notable event was on December 21, 2020, when the planets appeared just 0.1 degrees apart—the closest since 1623—and visible in the evening sky worldwide for the first time in nearly 800 years, coinciding with the winter solstice.[1] Earlier conjunctions, such as the triple conjunction in 7 BCE, have been hypothesized by some astronomers as possible explanations for the Star of Bethlehem described in historical texts, though this remains debated.[4] Great conjunctions have been observed and recorded since antiquity, with scientific documentation beginning in the 17th century following Galileo's telescopic discoveries of Jupiter's moons and Saturn's rings in 1610; the first noted post-telescopic event was in 1623.[1] Over five millennia, from 1000 BCE to 4000 CE, approximately 309 such conjunctions are projected, including 84 in triple groupings where the planets align three times in quick succession due to orbital perturbations.[5] These events are best viewed with the naked eye under clear skies but can be enhanced with binoculars or telescopes to reveal accompanying moons, making them accessible highlights for amateur astronomers.[2]Fundamentals
Definition and Characteristics
A great conjunction is an astronomical event in which the planets Jupiter and Saturn appear close together in the sky from Earth's perspective, occurring when their ecliptic longitudes are nearly identical. This alignment happens as Jupiter, with its shorter orbital period, overtakes the slower-moving Saturn along the ecliptic, the apparent path of the Sun across the sky. As the two most massive planets in the Solar System and among the brightest celestial objects visible without aid—second only to Venus—Jupiter and Saturn's proximity creates a visually prominent spectacle.[2][1] Great conjunctions recur approximately every 20 years, reflecting the synodic period between Jupiter and Saturn's orbits. Over centuries, these events form a distinctive zigzag or triangular pattern against the fixed stars, with each successive conjunction occurring roughly 120° eastward along the ecliptic due to the planets' differing orbital velocities. The term "great conjunction" has been used in astronomical literature since historical texts to denote these specific alignments, setting them apart from other planetary meetings because of the planets' size, luminosity, and enduring observational significance. Unlike conjunctions with inferior planets such as Mercury or Venus, which can involve passages in front of the Sun, great conjunctions feature two outer planets and emphasize their superior positions relative to Earth.[1][3][2] During a great conjunction, the minimum angular separation between the planets can range from as little as 0.1° (6 arcminutes) to 1.3° (78 arcminutes), with most falling between 0.5° and 1.3°, enabling both to be viewed simultaneously in amateur telescopes, with exceptional cases achieving separations as narrow as a few arcminutes. For instance, the 2020 event reached just 6.1 arcminutes, one of the closest in recent centuries. Visibility of these conjunctions depends on factors like the time of year and the observer's hemisphere, potentially affecting whether they occur in the evening or morning sky.[6]Observation and Visibility
Great conjunctions, defined as the close angular separation of Jupiter and Saturn as viewed from Earth, are among the most striking celestial events observable to the naked eye under clear skies. These alignments typically occur when the planets are low on the horizon during dusk or dawn, making them visible shortly after sunset or before sunrise depending on their ecliptic position. Jupiter's brightness, reaching a magnitude of -2.0, and Saturn's at +0.5, ensure that the pair stands out prominently against the twilight sky, often appearing as two bright "stars" separated by less than a degree—roughly the width of a full moon. Visibility is influenced by several environmental and astronomical factors. For example, the 2020 conjunction occurred in December, coinciding with winter in the Northern Hemisphere and the winter solstice, providing longer viewing windows in the evening sky. However, atmospheric conditions such as haze, clouds, or high humidity can obscure the view, while urban light pollution significantly diminishes contrast in populated areas. Optimal observation requires a location with a clear western or eastern horizon, free from obstructions like buildings or trees. For enhanced viewing, simple tools can reveal finer details without complicating the process. Binoculars or a small telescope allow observers to distinguish Saturn's rings and Jupiter's moons, which may appear as faint points of light near the brighter planet. Smartphone astronomy apps, such as Stellarium or SkySafari, or printed star charts, help pinpoint the exact location by aligning with familiar constellations like Aquarius or Capricornus. Importantly, if the conjunction occurs near the Sun—though rare for great conjunctions—viewers must avoid direct solar observation to prevent eye damage, using only indirect methods like projections. The accessibility of great conjunctions has evolved dramatically since the 20th century, with the rise of amateur astronomy enabling global participation. Prior to widespread telescope ownership and digital tools, observations were limited to professional astronomers or clear rural skies, but modern resources like online ephemerides and community events have democratized the experience. The 2020 conjunction, the closest since 1623, exemplified this shift, drawing millions worldwide through live streams and guided viewings despite pandemic restrictions.Celestial Mechanics
Orbital Dynamics
The orbital dynamics of great conjunctions are governed by the fundamental properties of Jupiter and Saturn's orbits around the Sun. Jupiter completes one sidereal orbit in 11.86 years at a semi-major axis of 5.20 AU, while Saturn requires 29.46 years for an orbit with a semi-major axis of 9.58 AU.[7] Both planets maintain nearly circular paths confined to the ecliptic plane, with low eccentricities of 0.049 for Jupiter and 0.056 for Saturn, and small inclinations relative to the ecliptic (1.30° for Jupiter and 2.49° for Saturn).[7] These parameters, derived from Kepler's laws of planetary motion, describe elliptical but nearly circular trajectories where the Sun occupies one focus.[8] The relative motion between Jupiter and Saturn arises from their differing orbital speeds, with Jupiter's faster period enabling it to lap the slower-moving Saturn approximately every two decades.[1] From a heliocentric viewpoint, Jupiter advances through its orbit at an average speed of about 13.07 km/s, compared to Saturn's 9.69 km/s, allowing the inner planet to catch up and surpass the outer one periodically.[7] Observed from Earth, this overtaking manifests as apparent retrograde motion for both planets due to our own orbital position, though the underlying dynamics remain heliocentric.[1] To model these positions, the heliocentric ecliptic longitude \lambda of each planet is calculated using the mean motion from Kepler's second law, approximated for low-eccentricity orbits as \lambda = \lambda_0 + \left( \frac{360^\circ}{P} \right) t, where \lambda_0 is the longitude at a reference epoch, P is the sidereal orbital period in years, and t is the time elapsed in years.[9] Great conjunctions occur when the longitudes align such that \lambda_\text{Jupiter} - \lambda_\text{Saturn} = 0^\circ \pmod{360^\circ}, marking the instants of ecliptic superposition.[10] These orbital alignments, resulting from the planets' resonant periods, produce great conjunctions roughly every 20 years.Synodic Cycle and Triple Conjunctions
The synodic period of Jupiter and Saturn, which determines the interval between their successive conjunctions, is derived from the difference in their orbital speeds relative to the Sun. With Jupiter's sidereal period of approximately 11.86 years and Saturn's of about 29.46 years, the formula for the synodic period S is S = \frac{1}{\left| \frac{1}{P_J} - \frac{1}{P_S} \right|}, yielding roughly 19.85 years.[12][13] This results in great conjunctions occurring approximately every 20 years, as Jupiter's faster orbit allows it to overtake Saturn periodically from Earth's perspective. Over longer timescales, the positions of these conjunctions trace cycles through the zodiac, with successive conjunctions shifting through elemental triplicities every approximately 240 years and a full return to the starting zodiac point roughly every 960 years, accounting for precession and relative motions.[3] In the geocentric view, the locations of great conjunctions shift through the zodiac constellations over centuries, forming a characteristic zigzag or triangular pattern against the background of the fixed stars. Each successive conjunction advances by roughly 120 degrees eastward along the ecliptic, creating this equilateral triangular progression that repeats approximately every three events, or about 60 years, before continuing the broader cycle.[3][13] This pattern arises from the combined orbital inclinations and the relative angular velocities, ensuring the conjunctions do not remain fixed but migrate systematically through the zodiac's 12 signs.[14] Triple conjunctions represent a special case occurring in about one-third of great conjunction events, where Jupiter appears to pass Saturn three times within a single synodic period due to Earth's passage between the two planets. This configuration triggers apparent retrograde motion for one or both planets relative to the other, producing a zigzag path in the sky: an initial direct conjunction, followed by a retrograde passage, and then a final direct one.[14][6] Such triples typically align every 60 years within the triangular pattern, enhancing the visual drama when the alignment occurs near the ecliptic plane.[15] Geometrically, a great conjunction occurs when the geocentric ecliptic longitudes of Jupiter and Saturn are nearly equal, causing them to appear close together in the sky from Earth's vantage point. In this geocentric perspective, the angular separation between Jupiter and Saturn can be as small as less than 1 degree during close conjunctions. These events are best observed when the planets are positioned in opposition to the Sun, allowing optimal nighttime visibility away from solar glare.[16][1] Exact timings and positions of great conjunctions, including triples, are predicted using astronomical ephemerides, which provide precise orbital data derived from observations and gravitational models. Software tools like Stellarium simulate these events by integrating ephemeris data, enabling users to visualize the geocentric alignments and angular separations for any date.[6][17]Historical Significance
Ancient and Medieval Records
The earliest documented observations of great conjunctions—alignments of Jupiter and Saturn—appear in Babylonian astronomical records dating to the 7th century BC. The MUL.APIN tablets, compiled around 1000 BC but reflecting earlier knowledge, include descriptions of planetary periods and configurations that laid the groundwork for tracking such events, primarily for calendrical and omen purposes in regulating the lunisolar calendar through intercalation.[18] Subsequent Babylonian Astronomical Diaries, beginning from 652 BC, provide systematic naked-eye records of planetary positions, including specific Jupiter-Saturn conjunctions, such as those noted in almanacs for predicting alignments based on observed motions.[19] In Ptolemaic astronomy, Claudius Ptolemy's Almagest (c. 150 AD) developed geometric models for planetary orbits, enabling the calculation of conjunction timings and positions with improved precision over Babylonian methods, though still geocentric and epicycle-based.[20] Islamic astronomers further refined these techniques; Al-Battani (c. 858–929 AD), building on Ptolemy, used trigonometric functions to compute more accurate planetary longitudes and precession rates, allowing better predictions of great conjunction cycles, including the approximately 20-year synodic pattern recognized in ancient texts.[21] A notable early event was the triple great conjunction of 7 BC in Pisces, recorded in a Babylonian almanac tablet (BM 32562) that detailed the planets' repeated close approaches over several months, visible to the naked eye and used for astrological forecasting.[22] This alignment was also potentially noted in Chinese records from the Han dynasty, such as the Hou Hanshu, which describe unusual celestial phenomena around that period, though not explicitly as a planetary conjunction.[23] In medieval Europe, chronicles frequently documented great conjunctions; for instance, the 1186 alignment in Libra was reported in multiple sources, including the works of Roger of Hoveden, who described its visibility and linked it to contemporary events like floods.[24] These observations contributed to calendar development, as Babylonian conjunction data helped synchronize lunar months with solar years, influencing later Hellenistic and medieval systems that adjusted the Julian calendar for equinox drift using planetary timings.[25] However, pre-telescopic records were limited by naked-eye accuracy, typically resolving separations to within 1–2 degrees without instruments, relying on qualitative descriptions rather than precise measurements, which often introduced errors in longitude estimates.[26]Early Modern Observations
The transition to systematic scientific observations of great conjunctions began in the early modern period, marked by the 1563 event, which was the first recorded by prominent European astronomers using improved instrumental techniques, though still pre-telescope. Danish astronomer Tycho Brahe, then a young student, made his inaugural astronomical observation of the Jupiter-Saturn conjunction on August 25, 1563, noting a close approach of about 5 arcminutes and identifying discrepancies between predicted positions from existing ephemerides and actual sightings, which spurred his lifelong pursuit of higher-precision measurements.[27] This triple conjunction, spanning late 1563, was visible in the constellation Pisces and highlighted the limitations of Ptolemaic and Copernican tables, prompting Brahe to develop more accurate star catalogs and instruments.[28] Johannes Kepler advanced the study significantly with his analysis of the 1603 great conjunction in Sagittarius, calculating its timing and geometry to explore historical planetary alignments, including a hypothesis linking similar events to the Star of Bethlehem around 7 BC.[29] Observing the planets' proximity—reaching about 50 arcminutes—Kepler documented the event in his work De Stella Nova in pede Serpentarii (1606), where he connected the conjunction's location to the subsequent supernova of 1604, interpreting the combined phenomena as a rare celestial portent while emphasizing empirical verification over astrological speculation.[30] These efforts contributed to Kepler's formulation of his laws of planetary motion, as the conjunction provided data points for refining elliptical orbit models derived from Tycho Brahe's observations. The invention of the telescope around 1608 revolutionized conjunction studies by enabling sub-arcminute resolution of planetary separations, allowing astronomers to test predictions from Kepler's laws with unprecedented accuracy. Early telescopic observations beginning with the 1623 conjunction confirmed the distinct disks of Jupiter and Saturn during alignments, aiding verification of orbital eccentricities and relative velocities without relying solely on naked-eye estimates.[31] In the 19th century, great conjunctions facilitated refinements to planetary ephemerides through systematic telescopic and positional astronomy. The 1842 conjunction in Capricornus, observed at observatories like Greenwich, provided data to adjust parameters in Urbain Le Verrier's orbital calculations, improving long-term predictions by incorporating perturbations from other planets.[16] Similarly, the 1861 event in Virgo, tracked with meridian circles, contributed to Simon Newcomb's ephemerides revisions, enhancing the precision of conjunction timings to within seconds, which supported broader solar system modeling. These observations underscored the shift toward quantitative celestial mechanics, using conjunctions as benchmarks for validating theoretical frameworks. The 1961 great conjunction on February 18, occurring in Aquarius with a separation of 0.5 degrees, was observed during the early space age using both ground-based telescopes and nascent space technologies. Amateur and professional astronomers worldwide documented the event visually and photographically, while early satellites like Explorer 9 indirectly contributed through upper atmosphere data that contextualized visibility conditions, marking a bridge to modern remote sensing of planetary positions.[32][33]Cultural Impact
Religious and Prophetic Interpretations
In Christian tradition, the great conjunction of Jupiter and Saturn in 7 BC has been hypothesized as the Star of Bethlehem that guided the Magi to the birth of Jesus, as described in the Gospel of Matthew.[4] This triple conjunction, occurring three times in the constellation of Pisces, was first calculated by astronomer Johannes Kepler in 1603, who observed a similar event that year and retroactively linked it to the biblical narrative.[34] Jewish eschatology has long associated Jupiter-Saturn conjunctions with messianic prophecies and the origins of religious dispensations, viewing them as celestial signs of divine transitions or the coming of the Messiah.[35] Similarly, in Islamic tradition, these alignments were interpreted as portents tied to prophetic cycles, with medieval texts linking specific conjunctions to the emergence of Islam itself or eschatological events.[36] Mayan codices, such as the Dresden Codex, document observations of Jupiter-Saturn conjunctions and their retrograde periods, integrating them into ritual calendars with religious significance for timing ceremonies and prophetic cycles.[37] During the medieval period in Christianity, great conjunctions were often seen as apocalyptic portents; for instance, the 1186 conjunction was prophesied in texts like the Letter of Toledo to herald widespread destruction through storms, famine, and earthquakes, influencing religious fervor amid events such as the Crusades.[38] In modern religious contexts, the 2020 great conjunction revived narratives of the "Christmas Star" among evangelical Christians, who drew parallels to the Star of Bethlehem as a sign of hope and divine intervention during global challenges.[39] Hindu texts correlate the Jupiter-Saturn conjunctions with their approximately 60-year samvatsara cycle, which aligns with broader yuga cycles, viewing these alignments as markers of cosmic epochs and sub-cycles within the Kali Yuga that influence spiritual and temporal transitions.[40] Chinese historical annals, including the Bamboo Annals, record planetary conjunctions like those of Jupiter and Saturn as ominous celestial events, often interpreted as portents signaling imperial changes or natural disasters.[41]Astrological and Mythological Views
In astrology, the great conjunction of Jupiter and Saturn holds profound symbolic importance, representing the union of Jupiter's expansive, beneficent qualities—associated with growth, prosperity, and kingship—with Saturn's restrictive, disciplinary influences, linked to time, structure, and limitation. These "royal stars," as they were termed in ancient traditions, are seen to mark shifts in societal dynamics, with each conjunction occurring approximately every 20 years initiating a new cycle of leadership, economic trends, and collective evolution. Over longer periods, these events form an 800-year supercycle, delineating broader epochs characterized by elemental progressions through the zodiac, influencing cultural and political paradigms.[42][43] Ancient astrologers, including Claudius Ptolemy in his Tetrabiblos, classified planetary conjunctions as one of the primary aspects, where planets align in longitude to exert combined influences on terrestrial affairs, with their power amplified when occurring in significant zodiacal positions. In Babylonian traditions, texts like the Enūma Anu Enlil compiled omens related to planetary conjunctions, interpreting such alignments as portents of societal changes, though specific Jupiter-Saturn pairings were embedded within broader celestial omen series predicting events like royal successions or natural disruptions.[44][45] During the medieval period, great conjunctions featured prominently in astrological horoscopes, where scholars analyzed their zodiacal signs to forecast major historical developments, such as the rise of rulers, outbreaks of wars, or shifts in power structures, often integrating them into predictive frameworks derived from Ptolemaic principles. These interpretations emphasized the conjunctions' role in heralding transitions between zodiacal eras, with alignments in particular signs symbolizing the dawn of new mythological ages tied to elemental themes.[3] In modern and New Age astrology, great conjunctions are mythologized as catalysts for collective awakening, particularly the 2020 event in Aquarius, which was interpreted as initiating a shift from the Piscean age of faith and hierarchy to the Aquarian era of innovation, humanitarianism, and technological interconnectedness, amid global transformations like the COVID-19 pandemic. This alignment, the closest in nearly 800 years, was viewed as amplifying themes of societal restructuring and expanded consciousness.[42] Despite their enduring cultural resonance, astrological views on great conjunctions face scientific criticism as pseudoscientific, lacking empirical evidence for causal influences on human affairs, with astronomers attributing the events solely to predictable orbital mechanics without terrestrial implications. Critics, including astrophysicists, acknowledge the psychological or symbolic appeal but dismiss claims of predictive power as unsubstantiated by controlled studies.[46][47]Chronology
Great Conjunctions 1200–1900
The great conjunctions of Jupiter and Saturn from 1200 to 1900 represent a series of approximately 37 alignments occurring roughly every 20 years, when the planets shared the same geocentric ecliptic longitude.[48] These positions were determined through modern computational ephemerides, aligning with high-precision planetary theories such as VSOP87.[48] The spacing of these events reflects the synodic cycle of the two planets.[48] During this era, the conjunctions progressed through the zodiac, demonstrating a gradual shift across elemental triplicities: beginning with a mix of earth and air signs in the 13th century, transitioning predominantly to water signs in the 14th and 15th centuries, fire signs in the 16th and 17th centuries, and earth signs in the 18th and 19th centuries.[48] Triple conjunctions, where the planets aligned three times in close succession due to retrograde motion, occurred rarely in 1306, 1425, and 1683.[48] Many were visible to the naked eye, depending on proximity to the Sun and atmospheric conditions.[6] The table below summarizes these events, listing the year, primary date (of the initial alignment in the cycle), zodiac sign (tropical), minimum geocentric angular separation at closest approach, and type. Data for dates, signs, and types derive from geocentric ecliptic longitude computations; separations from detailed orbital analyses.[48][6]| Year | Date | Zodiac Sign | Minimum Separation (arcmin) | Type |
|---|---|---|---|---|
| 1206 | Apr 16 | Taurus | 65.3 | Simple |
| 1226 | Mar 5 | Aquarius | 2.1 | Simple |
| 1246 | Sep 21 | Libra | 62.3 | Simple |
| 1265 | Jul 25 | Gemini | 57.3 | Simple |
| 1285 | Dec 31 | Aquarius | 10.6 | Simple |
| 1306 | Dec 25 | Scorpio | 71.5 | Triple |
| 1325 | Jun 1 | Gemini | 49.2 | Simple |
| 1345 | Mar 24 | Aquarius | 21.2 | Simple |
| 1365 | Oct 25 | Scorpio | 72.6 | Simple |
| 1385 | Apr 9 | Gemini | 43.2 | Simple |
| 1405 | Jan 16 | Aquarius | 29.3 | Simple |
| 1425 | Feb 14 | Scorpio | 70.7 | Triple |
| 1444 | Jul 14 | Cancer | 28.5 | Simple |
| 1464 | Apr 8 | Pisces | 38.2 | Simple |
| 1484 | Nov 18 | Scorpio | 68.3 | Simple |
| 1504 | May 25 | Cancer | 18.7 | Simple |
| 1524 | Jan 31 | Pisces | 46.1 | Simple |
| 1544 | Sep 18 | Scorpio | 69.2 | Simple |
| 1563 | Aug 25 | Cancer | 6.8 | Simple |
| 1583 | May 3 | Pisces | 52.9 | Simple |
| 1603 | Dec 18 | Sagittarius | 59.0 | Simple |
| 1623 | Jul 16 | Leo | 5.2 | Simple |
| 1643 | Feb 24 | Pisces | 59.3 | Simple |
| 1663 | Oct 16 | Sagittarius | 59.2 | Simple |
| 1682 | Oct 24 | Leo | 15.4 | Triple |
| 1702 | May 21 | Aries | 63.4 | Simple |
| 1723 | Jan 5 | Sagittarius | 47.7 | Simple |
| 1742 | Aug 30 | Leo | 27.8 | Simple |
| 1762 | Mar 18 | Aries | 69.4 | Simple |
| 1782 | Nov 5 | Sagittarius | 44.6 | Simple |
| 1802 | Jul 17 | Virgo | 39.5 | Simple |
| 1821 | Jun 19 | Aries | 72.9 | Simple |
| 1842 | Jan 26 | Capricorn | 32.3 | Simple |
| 1861 | Oct 21 | Virgo | 47.4 | Simple |
| 1881 | Apr 18 | Taurus | 74.5 | Simple |
Great Conjunctions 1901–2500
The great conjunctions of Jupiter and Saturn between 1901 and 2500 follow the established synodic cycle of approximately 19.86 years, with the planets' geocentric ecliptic longitudes advancing by roughly 243° each event, progressing through the zodiac over centuries.[6] Modern astronomical ephemerides, such as those from NASA's Jet Propulsion Laboratory, enable precise predictions of these alignments, including their dates, positions, and angular separations as viewed from Earth.[49] In this period, the conjunctions initially occur in earth signs, shifting to air signs (Aquarius, Gemini, Libra) starting with the 2020 conjunction in Aquarius, which marks the beginning of an approximately 200-year cycle in the air triplicity, following a preceding era dominated by earth signs.[14] Notable events in this period include triple conjunctions, where the planets align three times due to relative retrogrades, as in 1940–1941 and 1980–1981.[48] The 2020 conjunction stood out for its exceptional proximity, occurring on December 21, 2020, at 18:20 UTC, when the planets were separated by only 0.10°, the closest observable approach since 1623 and the tightest in 397 years.[50] This event, visible worldwide under clear skies, drew significant public interest and was documented by observatories including NASA's Hubble Space Telescope.[1] As of 2025, no further conjunctions have occurred, with anticipation building for the next in 2040.[51] The following table summarizes selected great conjunctions from 1901 to 2398, highlighting representative examples, their zodiac positions (based on tropical longitudes), minimum angular separations, and key notes. Data derive from geocentric ephemerides; separations are in degrees, with smaller values indicating closer alignments. Future events beyond 2398 follow the predictable cycle, with projections to 2500 showing continued progression through water and fire signs, though exact parameters may refine with updated orbital models.[6]| Year | Date | Zodiac Sign | Separation (°) | Notes |
|---|---|---|---|---|
| 1901 | November 28 | Capricorn | 0.44 | Standard single conjunction at 285.4° longitude. |
| 1940–1941 | August 8, 1940; February 15, 1941 | Taurus | 1.29 (primary) | Triple cycle spanning two years; secondary at 0.67° separation. |
| 1961 | February 19 | Capricorn | 0.23 | Notably close, visible in evening sky. |
| 1980–1981 | December 31, 1980; July 24, 1981 | Libra | 1.13 (primary) | Triple cycle; first in air signs since 1901 shift. |
| 2000 | May 28 | Taurus | 1.15 | Occurred during daytime, less visible without aids. |
| 2020 | December 21 | Aquarius | 0.10 | Closest in 397 years; at 300.3° longitude, 6.1 arcminutes apart; marked air element era start. |
| 2040 | November 4 | Libra | 1.21 | Projected evening visibility in southern hemisphere. |
| 2060 | April 7 | Gemini | 1.13 | Single alignment at ~59.6° longitude. |
| 2080 | March 15 | Aquarius | 0.10 | Exceptionally close, similar to 2020; part of air-sign sequence. |
| 2100 | September 18 | Libra | 1.04 | Visible pre-dawn in northern latitudes. |
| 2140 | January 14 | Aquarius | 0.24 | Close approach at 315.1° longitude. |
| 2199 | April 8 | Aquarius | 0.42 | Transitions toward water signs. |
| 2298 | July 12 | Cancer | 0.47 | In water element at 100.6° longitude. |
| 2358 | May 22 | Cancer | 0.31 | Close water-sign event. |
| 2398 | October 2 | Sagittarius | 1.10 | Final listed in fire-sign transition at 240.7° longitude. |