Uranus Gemini ingress
Introduction
Uranus takes approximately 84 years to complete a full circuit of the zodiac, spending about 7 years in each sign. Every time Uranus enters Gemini—known as the Gemini ingress—it heralds a period of innovation, communication breakthroughs, and shifts in collective thought. Below is a concise list of the first recorded dates when Uranus moved into Gemini for each cycle, along with the interval in years since the previous ingress.
Gemini Ingress Hit List First Uranus Ingress into Gemini and Year Gaps
- July 2, 1020 ()
- June 14, 1104 (84 years after previous)
- May 29, 1188 (84 years)
- August 4, 1271 (83 years)
- July 9, 1355 (84 years)
- June 20, 1439 (84 years)
- June 2, 1523 (84 years)
- August 9, 1606 (83 years after previous)
- July 10, 1690 (84 years)
- June 19, 1774 (84 years)
- June 2, 1858 (84 years)
- May 15, 1942 (84 years)
🚀 Technological Breakthroughs by Ingress Cycle
Below are key transportation, energy, industrial, and warfare innovations corresponding to each first Uranus ingress into Gemini.
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July 2, 1020 🚢💧
- Maritime Trade: Improved clinker-built ships expand coastal commerce.
- Water Power: Use of water wheels for mills.
- Warfare: Widespread use of the longbow and enhanced cavalry tactics.
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June 14, 1104 🐴🛡️
- Horse Harness: Full-collar design increases draft efficiency.
- Cast Iron: Advancements in blast furnaces produce stronger metal tools.
- Warfare: Early crossbows proliferate among infantry.
-
May 29, 1188 🛳️🔩
- Cog Ships: Robust vessels dominate North Sea trade.
- Treadwheel Cranes: Enhanced construction capabilities.
- Siege Engines: Trebuchets refined for greater range and power.
-
August 4, 1271 🌬️🏴☠️
- Windmills: Widespread use in Europe for grinding grain.
- Asian Junks: Development of oared junks for long-distance sailing.
- Gunpowder Weapons: Chinese fire lances see early battlefield use.
-
July 9, 1355 🌉🏭
- Stone Arch Bridges: Expansion of durable road networks.
- Fulling Mills: Water-driven textile finishing increases fabric output.
- Hand Cannons: Early gunpowder firearms emerge.
-
June 20, 1439 ⛵⚔️
- Carrack Ships: Hull design optimized for ocean voyages.
- Arc Furnaces: Improved metal refining techniques.
- Matchlock Arquebus: First standardized firearms with slow-burning match.
-
June 2, 1523 ⚙️🛠️
- Clockwork Mechanisms: Gear systems lay groundwork for engines.
- Blast Furnace Cannons: Enhanced artillery production.
- Siege Artillery: Cannons become central to warfare.
-
August 9, 1606 ⛵🔭
- Full-Rigged Pinnaces: Advanced ships for exploration.
- Telescope Optics: Better lenses improve navigation and surveying.
- Naval Cannons: Standardized calibers for ship-to-ship combat.
-
July 10, 1690 🚍⛏️
- Stagecoach Networks: Organized land travel routes.
- Coal Heating: Widespread urban coal use begins.
- Flintlock Muskets: More reliable infantry firearms.
-
June 19, 1774 🔧🚂
- Steam Pumps: Watt’s engine improvements for mines.
- Smelting Techniques: Pre-Bessemer methods enhance steel quality.
- Rifled Barrels: Early improvements in firearm accuracy.
-
June 2, 1858 🚆🛢️
- Railways: Steam locomotives expand global transport.
- Oil Wells: Drake’s well kickstarts the petroleum industry.
- Ironclads: Armored warships debut in naval warfare.
-
May 15, 1942 ✈️🔋
- Mass-Produced Aircraft: P-51 Mustang prototype development.
- High-Octane Fuels: Synthetic fuel techniques scale.
- Radar Systems: Crucial electronic warfare technology.
now we enter a crucial period of 1520–1528, where Renaissance technology, art, and cosmology begin cracking open medieval boundaries. While it’s still pre-scientific-revolution, there is a strong thematic pattern of sky, energy, gas, and symbolic transformation — but interpreted through alchemy, navigation, warfare, and sacred geometry.
🔮 Core Theme (1520–1528): "Energy through Form — The Alchemy of Sky and Power" This era deals with celestial power made visible through human invention, sacred design, and physical energy — not yet industrial, but mythically charged.
Let’s explore it through your focus on gas, energy, and the sky.
🌀 1. Gas / Alchemy / Etheric Forces
⚗️ This was a golden age of alchemy — not yet chemistry, but deeply concerned with:
- Transmutation of matter (base to noble)
- The "spirit" in metals, vapors, and ethers
- Sulphur-mercury-salt trinity (seen as spiritual and physical forces)
🔹 Paracelsus (active until his death in 1541) began challenging Galenic medicine, introducing chemical remedies and the idea that invisible forces (what we now call "gases" or "toxins") affect the body.
💨 While gas as a term wouldn’t exist until the 17th century, the spiritual nature of volatile substances was already central.
🔺 Theme: Gas was still alchemical — not physical, but symbolic of transformation and inner fire.
⚔�️ 2. Energy / Mechanics / Warfare Innovation
🛡️ This period saw the maturation of gunpowder warfare and mechanical design:
- 1521: Siege of Belgrade and 1527 Sack of Rome showed the destructive power of cannon and early firearms.
- Energy here meant force, explosion, kinetic release.
🔹 Leonardo da Vinci's notebooks, though unpublished, had already sketched:
- Water-powered machines
- War machines with stored tension (proto-energy devices)
- Helical aerial screw — a form of airborne lift (sky + rotation + energy)
While Leonardo died in 1519, his ideas were circulating in elite circles during this decade.
🔺 Theme: Human harnessing of physical force — energy as directed power.
🌌 3. Sky / Astronomy / Sacred Cosmos
🔭 Astronomically, this period sits just before Copernicus begins finalizing De revolutionibus (c. 1530s).
But in this decade:
- 1524: A highly anticipated Great Conjunction of Jupiter and Saturn in Pisces occurred. Many feared it signaled the end of the world.
- This conjunction triggered a massive wave of sky-centered mysticism, apocalypse prophecies, and transformation myths.
- Influenced thinkers like Paracelsus, Trithemius, and Agrippa.
🧭 The sky was still magical — but now being measured.
🔹 Meanwhile, navigational astronomy advanced:
- 1522: Ferdinand Magellan’s expedition completed the first circumnavigation of the Earth.
- Navigators used the sky (stars, sextants, declination) to map the globe.
🔺 Theme: Sky becomes a navigational compass and prophecy field — both mystical and empirical.
🧭 Summary Table
| Year | Event / Invention | Domain | Symbolic Element |
|---|---|---|---|
| 1521 | Fall of Tenochtitlan (Cortés conquest) | Political / Tech | Energy + Sky gods fall |
| 1522 | Magellan's ship completes circumnavigation | Navigation | Sky = global map |
| 1524 | Great Jupiter–Saturn Conjunction | Astrology | Prophecy through sky |
| 1527 | Sack of Rome (gunpowder dominance) | Warfare | Explosion = unleashed fire |
| 1520s | Alchemy and Paracelsus influence rise | Proto-chemistry | Gas as spiritual force |
1603 to 1610 is absolutely permeated with a theme of gas, energy, and the sky, but not in the way we’d interpret energy today (like fossil fuels or electricity). Instead, this period represents a revolution in the subtle understanding of cosmic and invisible forces:
🔭✨ Theme: “The Invisible Becomes Visible”
A transition from metaphysical speculation to observed energetic laws of the cosmos, the sky opens, and hidden forces (gas, orbits, light, planetary energy) are revealed through new lenses — both literal and intellectual.
Let’s unpack that across 3 domains: gas, energy, and sky.
🌀 1. Gas: The First Signs of Atmospheric and Invisible Forces
💨 While the word "gas" (from chaos) was coined later by Jan Baptist van Helmont (~1630s), the 1600s mark:
- Early understanding of air pressure, voids, and vacuum debates.
- Observation of supernovae and comets as atmospheric or celestial “vapors” breaking Aristotelian crystalline spheres.
- Kepler’s supernova (1604) challenged the idea of immutable celestial realms — gas was becoming a change agent in the heavens.
✨ Sky was no longer a perfect divine dome — it could burn, explode, evolve. This is proto-astrophysical thinking.
🔥 2. Energy: Planetary Motion, Kinetics, and Emerging Dynamics
⚙️ Kepler’s Astronomia Nova (1609) introduces:
- The concept of force acting on planets from the sun — an early notion of energy transfer, not just geometric movement.
- Planets sweep equal areas in equal times — a dynamic energetic rhythm in the solar system.
- Abandonment of the idea of perfect circular "divine" motion in favor of elliptical, real energy orbits.
This is the emergence of celestial dynamics — energy as motion, attraction, imbalance, rather than static perfection.
🌌 3. Sky: The Heavens Are No Longer Divine and Untouchable
🌠 Galileo (1609–1610) observes:
- Moons around Jupiter (disproving the belief that all bodies orbit Earth).
- The Milky Way as a field of innumerable stars, not a mystical band.
- The Moon’s surface as imperfect, cratered, earthy — not an ethereal heavenly sphere.
🚀 The sky loses its godlike opacity and becomes a field of empirical study, filled with energy, motion, and depth.
🌬️💫 Symbolic & Elemental Correlation
| Element | Symbol in this era | Transformation |
|---|---|---|
| Air / Gas | Supernova, atmospheres, void | From divine ether → mutable, penetrable substance |
| Fire / Light | Stars, telescopic vision, optics | From mystic stars → sources of motion and energy |
| Aether | Aristotelian 5th element | Dissolved under pressure of new mechanics & optics |
| Sky / Space | The divine realm | Becomes mechanical, measurable, and full of energy |
Now you're zooming into a pre-industrial but intellectually volcanic era — the period 1687 to 1695 — which lies squarely in the Age of Enlightenment. While it doesn’t yet feature large-scale machinery or mass manufacturing, it is absolutely revolutionary in science and technology — especially in physics, astronomy, and mathematics.
This period marks the birth of modern science as a structured, mathematical language of nature, driven largely by Newton, but also echoed across Europe.
⚙️🔭 TECHNOLOGICAL & SCIENTIFIC DEVELOPMENTS (1687–1695)
🌌 1. 1687 – Newton Publishes Philosophiæ Naturalis Principia Mathematica
-
This is the single most important scientific book ever written.
-
Introduced:
- Laws of motion
- Law of universal gravitation
- Mathematical treatment of planetary orbits
-
Newton’s laws replaced Aristotelian physics and completed Galileo’s revolution.
🧠 This was the formal birth of classical physics.
🔺 Significance: Defined the rules of mechanics until Einstein. 🧭 Probability of paradigm shift: 100%
🔭 2. Technology of the Telescope and Optics Advances
- Following Newton’s experiments in optics (prisms, light spectra), the reflecting telescope began wider influence.
- Newton’s reflecting telescope design (1668) was further improved during this period.
- Makers across Europe experimented with lenses and mirrors to reduce chromatic aberration.
🔍 Led to better astronomy, navigation, and spyglasses.
🔺 Significance: Laid basis for modern telescopes & microscopes. 🧭 Probability of impact: 90%
⚗️ 3. Rise of Experimental Chemistry & Vacuum Technologies
- Robert Boyle’s influence continued to spread. Boyle had died in 1691, but his experiments with air pumps and gas pressure (Boyle’s Law) inspired new designs.
- Otto von Guericke’s vacuum pump (invented earlier) was still being refined and used.
- Stephen Gray and Denis Papin continued improving air pumps and pressurized chambers.
🛠 This era foreshadowed the future steam engine and pressure-based systems.
🔺 Significance: Foundations for chemistry, pressure science, engines. 🧭 Probability of leading to tech: 85%
🔬 4. Antonie van Leeuwenhoek’s Microscopic Discoveries
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Between 1687–1695, Leeuwenhoek refined his microscopes and discovered:
- Bacteria
- Sperm cells
- Muscle fibers
-
He reported to the Royal Society of London, sparking excitement in the microscopic world.
🔬 He became the father of microbiology.
🔺 Significance: Laid groundwork for biology, medicine, and later germ theory. 🧭 Probability of long-term relevance: 95%
🧮 5. Gottfried Wilhelm Leibniz — Early Mechanical Calculator & Binary Logic
-
In 1694, Leibniz completed his “Stepped Reckoner” — a mechanical calculator that could:
- Add
- Subtract
- Multiply
- Divide
-
He also formalized binary number theory, the basis of modern digital computing.
🧠 Leibniz saw binary as symbolic of the universe’s underlying logic, even tying it to Taoist yin/yang!
🔺 Significance: Conceptual ancestor of computers. 🧭 Probability of future tech influence: 98%
📚 BONUS: Scientific Institutions Flourish
- The Royal Society (England) and the Académie des Sciences (France) became hubs of experimentation and correspondence.
- They standardized peer review, scientific publishing, and public demonstration of experiments.
🧪 Tech moves from alchemy to collaborative experimental science.
🧭 Summary Table
| Year | Innovation/Event | Field | Impact |
|---|---|---|---|
| 1687 | Newton’s Principia Mathematica | Physics | Universal laws of motion & gravity |
| 1687–1695 | Optics improvements (telescopes) | Astronomy/Optics | Better observation instruments |
| 1687–1691 | Boyle’s legacy, vacuum tech growth | Chemistry/Physics | Early gas laws and pressurization |
| 1687–1695 | Leeuwenhoek’s microbiology work | Biology | Discovery of microbes and sperm |
| 1694 | Leibniz’s calculator and binary system | Computing/Logic | Foundation of digital systems |
🔮 Interpretation: A Mental Revolution, Not Yet Industrial
- This was not yet a revolution of machines — it was a revolution of frameworks.
- Technology and scientific method became structured, predictable, mathematical.
- Everything we now engineer — from rockets to AI — rests on the Newton-Leibniz scientific bedrock of this era.
Excellent question, Lorris — the period from 1772 to 1780 is a pre-industrial pivot point — a moment where proto-industrial technologies, scientific understanding, and new engineering concepts started converging. It doesn't yet have the explosive output of the 1850s or 1900s, but it’s the fertile soil that enabled the Industrial Revolution to erupt soon after, especially in Britain and Western Europe.
Let’s explore the key technological and proto-industrial breakthroughs from this period.
🛠️⚙️ TECHNOLOGICAL DEVELOPMENTS (1772–1780)
Focused on inventions, engineering, energy, and mechanics
🔥 1. James Watt's Steam Engine Patented (1775)
- Though Watt began improving Newcomen’s steam engine earlier, in 1775 he partnered with Matthew Boulton and received a full patent.
- Key innovation: separate condenser, vastly improving efficiency.
- This was the beginning of the steam engine's wide industrial use (mines, factories, later trains and ships).
🔺 Significance: Core engine of the Industrial Revolution 🧭 Probability of long-term impact: 99%
🔩 2. Spinning Jenny Improved – Multi-Spindle Textile Machine
- Invented by James Hargreaves in the 1760s, but mass adoption begins in the 1770s.
- Allowed one worker to spin multiple spools of thread simultaneously.
- Revolutionized the textile industry — Britain’s leading industrial sector.
🔺 Significance: First step toward mechanized mass production 🧭 Probability of impact: 95%
🧵 3. Arkwright’s Water Frame (patented 1769, scaled in 1770s)
- Richard Arkwright’s water-powered spinning machine used in mills.
- By the mid-1770s, factories powered by waterwheels emerged — early industrial-scale production centers.
🏭 1772–1780 saw the birth of the first factories in England.
🔺 Significance: Foundation of factory-based industry 🧭 Impact probability: 95%
🔬 4. Joseph Priestley Discovers Oxygen (1774)
- Though more of a scientific discovery, it influenced chemistry and metallurgy.
- Priestley isolated “dephlogisticated air” (later called oxygen), leading to the end of the flawed phlogiston theory.
- Laid groundwork for modern combustion understanding, essential for engines.
🔺 Significance: Birth of modern chemical science 🧭 Probability of enabling future tech: 90%
💡 5. Early Electrical Devices and Theories
- Inspired by Franklin’s earlier work, various inventors across Europe began developing Leyden jars, static electricity machines, and basic capacitors.
- In 1775, Italian physicist Alessandro Volta improved the electrophorus, a device that could store electric charge.
⚡ While still a parlor science, electricity is being tamed, leading toward 19th-century breakthroughs.
🔺 Significance: Lays groundwork for battery and electromagnetism 🧭 Probability of long-term impact: 85%
🛠️ 6. Machine Tools: Early Precision Engineering Begins
- Though not fully industrialized, clockmakers and instrument makers began refining tools for precision metalworking.
- John Wilkinson (known as "Iron Mad Wilkinson") built boring machines to accurately shape cannon and later steam engine cylinders (~1774–1775).
🔺 Significance: Precursor to machine-tool revolution 🧭 Probability of high industrial relevance: 88%
🧭 Summary Table
| Year | Innovation/Event | Field | Impact |
|---|---|---|---|
| 1772–1775 | Expansion of Spinning Jenny | Textiles | Start of mechanized clothing |
| 1774 | Oxygen discovered (Priestley) | Chemistry | Modern combustion science |
| 1775 | Watt's steam engine patent | Energy/Mechanics | Efficient industrial steam power |
| 1775 | Volta's electrophorus improved | Electricity | Precursor to battery science |
| 1774 | Wilkinson’s boring machine | Engineering | Precision metalworking |
| 1770s | Water-powered mills (Arkwright) | Industrial design | First factory systems |
🧠 Conclusion: A Quiet Revolution Begins
- 1772–1780 was not yet the boom of industry, but it was the geological rumble before the eruption.
- The tools of the First Industrial Revolution (c. 1780–1820) were being forged here.
- Steam, textiles, chemistry, and early electricity all began to show real technological promise.
Ah! Got it, Lorris — now focusing specifically on technological advances from 1855 to 1870, this period marks a transitional surge in engineering, energy, communication, and materials. It laid the foundation of modern industrial systems, long before they exploded in the 20th century. You could call it the “proto-digital-industrial” age — still analog, but rapidly systematizing everything.
🛠️📡 TECHNOLOGICAL REVOLUTION (1855–1870)
A detailed timeline of game-changing inventions and infrastructure breakthroughs
🔧 1855 – Bessemer Process Patented
- Invented by Henry Bessemer in England.
- Allowed for mass production of steel by blowing air through molten iron.
- Steel became cheaper and faster to produce — revolutionizing railroads, bridges, ships, and weapons.
🔺 Significance: Foundation of modern structural engineering. 🧭 Probability of revolutionary impact: 99%
🛢️ 1859 – First Commercial Oil Well Drilled
- Edwin Drake strikes oil in Titusville, Pennsylvania.
- Sparked the global petroleum industry, replacing whale oil and laying groundwork for combustion engines.
🔺 Significance: Start of the fossil fuel economy. 🧭 Probability of long-term transformation: 99%
📡 1861 – First Transcontinental Telegraph Line Completed (USA)
- Linked the east and west coasts of the U.S.
- Enabled near-instantaneous communication across vast distances.
- Pony Express shut down two days later.
🔺 Significance: Paved the way for global real-time communication. 🧭 Probability of revolution: 95%
⚙️ 1863 – First Subway Opens (London Underground)
- Metropolitan Railway opens in London: the first underground train system.
- Used steam engines at first, later replaced by electric.
- Demonstrated possibility of urban mass transit.
🔺 Significance: Proto-model for modern metros. 🧭 Urban technological impact: 90%
🔋 1866 – Transatlantic Telegraph Cable Successful
- After previous failures, Cyrus Field and team succeed in laying a working submarine cable across the Atlantic.
- Messages now took minutes, not weeks, between Europe and America.
🔺 Significance: Birth of global information flow. 🧭 Communication revolution: 98%
⚡ 1867 – Alfred Nobel Invents Dynamite
- Safer and more controlled than raw nitroglycerin.
- Used in construction, mining, and unfortunately warfare.
- Led to Nobel Prizes as his legacy.
🔺 Significance: Enabled massive-scale civil engineering. 🧭 Probability of explosive impact: 95%
🔩 1869 – Suez Canal Opens
- While not a "technology" per se, its completion represents technological engineering triumph.
- Linked the Mediterranean to the Red Sea — cutting Europe–Asia travel time drastically.
- Involved modern excavation, logistics, and political-tech convergence.
🔺 Significance: Reshaped global trade routes. 🧭 Probability of economic-tech influence: 92%
🧭 BONUS HIGHLIGHTS
| Year | Tech / Invention | Domain | Impact |
|---|---|---|---|
| 1855 | Bessemer steel process | Materials/Industry | Strong, cheap steel |
| 1859 | Oil drilling (Drake) | Energy | Petroleum age begins |
| 1861 | Transcontinental telegraph | Communications | Killed the Pony Express |
| 1863 | London Underground | Transportation | Modern metro systems born |
| 1866 | Transatlantic cable | Global comms | Instant cross-continental msg |
| 1867 | Dynamite (Nobel) | Mining, war, tunnels | Safe explosive power |
| 1869 | Suez Canal | Global logistics | Engineered trade revolution |
🔮 Summary: Was this a technological revolution?
✅ Yes — though less dramatic than later ones, 1855–1870 was the first great infrastructure revolution:
- Steel, oil, telegraph, urban transport, and explosives began reshaping civilization.
- It made modern energy, engineering, and communication possible.
- Many inventions from this period would scale massively by 1900.
Here’s an overview of major military conflicts within ±10 years of each date you listed:
📅 July 2, 1020 (1010–1030)
- Byzantine–Bulgarian Wars (ongoing intermittently): Tensions and conflicts between Byzantium and the Bulgarian Empire continued during this period, notably resuming later in the 1030s. (military-history.fandom.com)
📅 June 14, 1104 (1094–1114)
- Battle of Harran (May 7, 1104): First major defeat for the Crusader states at the hands of the Seljuks in southeast Anatolia. (britannica.com)
- Siege of Acre (May 1104): Crusaders recaptured this key port, pivotal for supply lines. (military-history.fandom.com)
- Korean–Jurchen Border Clashes (1104): The Goryeo kingdom defeated and built fortifications after repeated incursions. (en.wikipedia.org)
📅 May 29, 1188 (1178–1198)
- Sieges in the Levant (1187–1188): Including Kerak, Safed, Laodicea—Saladin’s forces consolidated after Hattin. (en.wikipedia.org)
- Prelude to Third Crusade (1189–1192): Initiated by Hattin’s disaster in 1187, setting stage for later campaigns. (en.wikipedia.org)
📅 August 4, 1271 (1261–1281)
- Mongol Conquest of China (1205–1279): Ongoing campaigns culminated with the Southern Song’s fall under Kublai Khan. (en.wikipedia.org)
- Mongol Invasion of Japan (1274): First major attempt launching from Korea and China. (worldhistory.org)
- Pomerelian Civil War (1271): Regional struggle in Eastern Europe involving Brandenburg and Polish duchies. (military-history.fandom.com)
📅 July 9, 1355 (1345–1365)
- Black Prince’s Chevauchée (Oct–Dec 1355): A devastating raid in Southern France during the Hundred Years’ War. (en.wikipedia.org)
- Siege of Berwick (1355–56): Cross-border conflict between England and Scotland. (en.wikipedia.org)
- Battle of Nesbit Moor (1355): Another localized conflict amid the wider Anglo-Scottish tensions. (en.wikipedia.org)
📅 June 20, 1439 (1429–1449)
- Battle of Grotniki (May 1439): Polish Crown forces defeated Hussite rebels, ending significant resistance. (en.wikipedia.org)
- Hungarian–Ottoman War (1437–1442): Ottoman push into Hungary at this time. (en.wikipedia.org)
- Sieges of Brescia & Älvsborg: Indicative of broader regional conflicts in Europe. (en.wikipedia.org)
📅 June 2, 1523 (1513–1533)
- Swedish War of Liberation (1521–1523): Ended with Sweden breaking from the Kalmar Union. (military-history.fandom.com)
- German Peasants’ War (1524–1525): Major uprising in Holy Roman Empire pushing social change. (worldhistory.org)
- Siege of Fuenterrabía (1523–24): Siege in Northern Spain during the Italian Wars. (en.wikipedia.org)
📅 August 9, 1606 (1596–1616)
- Long War (1591/93–1606): Prolonged Habsburg–Ottoman conflict across the Balkans. (military-history.fandom.com)
- Siege of Moscow Uprising (1606): Internal Russian rebellion against Tsar Vasili IV.
- Siege of Ganja, Malacca, Groenlo, Kandahar (1606): Multiple sieges mark global military tensions. (military-history.fandom.com)
📅 July 10, 1690 (1680–1700)
- Battle of Beachy Head (July 10, 1690): French naval victory during the Nine Years’ War. (Same date you noted.)
- Nine Years’ War (1688–1697): Major continental conflict involving France against Grand Alliance powers.
📅 June 19, 1774 (1764–1784)
- Prelude to American Revolution: Growing tensions following Boston Tea Party (Dec 1773); armies mobilized by April 1775. (No direct battle June 1774.)
- King George’s War (1744–1748): Earlier N. American conflict, but out of immediate range. (americanwars.org)
📅 June 2, 1858 (1848–1868)
- Indian Rebellion Aftermath: The 1857 uprising’s suppression wrapped up by 1858; Britain reorganized rule.
- Second Opium War (1856–1860): Hostilities by Western powers in China during this timeframe.
📅 May 15, 1942 (1932–1952)
- Battle of Rabaul (Jan 1942): Japanese captured the Australian-held base in Papua New Guinea.
- Aleutian Islands Campaign (June 1942): Japanese occupied western Aleutians; U.S. defensive response. (thetimes.co.uk)