David Rittenhouse Essay

Amber Stich

Percival

D.E. Astronomy

19 December 2014

David Rittenhouse Essay

            David, the son of Matthias and Elizabeth Williams Rittenhouse, was born on a farm in 1732, about 20 miles north of Philadelphia in the town of Norriton. Of German Mennonite and Welsh Quaker decent, Rittenhouse belonged to the Presbyterian Church and was given informal education. Most of Rittenhouse’s education was self-taught. Rittenhouse married Eleanor Coulston in 1766 and had two daughters. When Eleanor died, Rittenhouse married Hannah Jacobs in 1772. Rittenhouse was of poor health, mostly due to his duodenal ulcer. But despite his ailments, Rittenhouse was a major contributor to both astronomy, and the early United States. Rittenhouse spent most of his life in Philadelphia.

            By trade, Rittenhouse was a clock and mathematical instrument maker. He was known for his workmanship. His astronomical clock used a pendulum he himself had designed. Many of Rittenhouse’s instruments were so well made they were able to be preserved to this day. His handmade instruments were far superior to any other in the United States at that time. Some of the instruments Rittenhouse made were surveyors’ compasses, levels, transits, telescopes, zenith sectors, thermometers, barometers, a hygrometer, and eyeglasses. Rittenhouse was one of the early users of spider webs over a telescope’s eyepiece to be used for cross hairs. He also built a collimating telescope in his observatory. The Vernier compasses Rittenhouse built were known in America as “Rittenhouse compasses”, and the stove type he made for Benjamin Franklin’s fireplace were deemed a “Rittenhouse stove”. Rittenhouse, among his experiments with pendulums, created the concept of magnetic dipoles. During his diffraction studies, Rittenhouse created plane transmission gratings, using fine wire across a frame and followed this by stating the law of governing their displacement.

Though it was often overlooked –David Rittenhouse played an important part in the development of Pennsylvania. Rittenhouse was the most celebrated American surveyor; marking Pennsylvania’s borders with its surrounding states. During the American Revolution, Rittenhouse helped design the Delaware River defenses and worked on the production of saltpeter and guns. Rittenhouse also experimented with telescope scopes for rifles and cannons. Along with this, Rittenhouse participated in the forming of the Pennsylvanian Constitution of 1776, the Board of War, and the vice-presidency of the Council of Safety. Occasionally, Rittenhouse held the responsibility of executive leadership of the state. From 1777-1798, Rittenhouse served as the treasurer of Pennsylvania. And when Thomas Jefferson was working on his report for weights and measured, he turned to Rittenhouse as a consultant and named him the first director of the U.S. Mint in 1792.

            Beginning in 1773, Rittenhouse moved his talents to astronomy. Rittenhouse began supplying almanacs in Pennsylvania, Maryland, and Virginia with astronomical calculations. Rittenhouse first success was in his observation of the transit of Venus in 1769. He then submitted the best American calculation contribution to the worldwide efforts to establish the sun’s parallax. On his publishing of his initial volume of Transactions, which is where he published most of his work, Rittenhouse was made the President of the American Philosophical Society, succeeding Ben Franklin. Rittenhouse built all of the instruments used by the Norriton observation group. To enable him to keep daily records and conduct regular observations for his publishing data and calculations on meteors, comets, Jupiter’s satellites, Mercury, Uranus and various eclipses- Rittenhouse established the Philadelphia observatory. Rittenhouse’s best published work was an original formula for finding the place of a planet in its orbit. Rittenhouse also figured out logarithm calculations as a study of the period of a pendulum. Rittenhouse may have independently developed a system of calculus during his research of the area. Rittenhouse also published various accounts of lightning, meteorology, geology, and aspects of natural history.

            Rittenhouse, a prominent American figure of his time, is often overlooked by historians. Rittenhouse was the power-house of behind-the-scenes work, overshadowed, but not underappreciated, by public figures. He contributed major advancements in mathematical and astronomical instruments, which he used himself to contribute valuable data to the scientific community. Rittenhouse’s poor health was the cause of his death; he died on June 26^th, 1796 of cholera. His legacy was of being one of American’s “untutored geniuses”.

APOD 2.6

One celestial body that never fails to amaze is the Nebula. The nebula pictured above is the Flame Nebula- about 1,500 light years away. The Nebula is located near the Orion constellation. The glow and dark dust lanes gives the nebula the fire-like appearance. The bright star Alnitak, of the Belt of Orion, shines the energetic light on the nebula. Alnitak does this by knocking electrons away from the hydrogen gas clouds that reside in the nebula -the electrons and ionized hydrogen then recombine. The Flame Nebula (NGC 2024) picture is a mixed composite of both visible and infrared light. The Flame Nebula is part of the Orion Molecular Cloud Complex, a star-forming region that also houses the Horsehead Nebula.

Observation Post (12/15/14)

After watching the Gemini meteor shower a few nights ago, I gained a new appreciation for what I'm learning in astronomy. Things are happening in space that I never knew about before- and now I get to go outside and not only watch them happen- but understand what's happening and why. I have always liked stargazing, but actually being able to identify constellations and stars gives the practice a whole new light. One of my favorite things to do is to stargaze with my boyfriend and compete to see who can find the most satellites in one night. I never before had this appreciation for doing something so simple as just looking up.

D. Rittenhouse (Sources)

David Rittenhouse Biography Sources

Science and Its Times:
"David Rittenhouse." Science and Its Times. Ed. Neil Schlager and Josh Lauer. Vol. 4: 1700 to 1799. Detroit: Gale, 2000. 367. Gale Virtual Reference Library. Web. 8 Dec. 2014.

The Complete Dictionary of Scientific Biography:
"Rittenhouse, David." Complete Dictionary of Scientific Biography. Vol. 11. Detroit: Charles Scribner's Sons, 2008. 471-473. Gale Virtual Reference Library. Web. 8 Dec. 2014.

Encyclopedia of World Biography:
"David Rittenhouse." Encyclopedia of World Biography. 2nd ed. Vol. 13. Detroit: Gale, 2004. 180-181. Gale Virtual Reference Library. Web. 8 Dec. 2014.

APOD 2.5

 

This pillar of dust makes what looks like to be a 20 light year long seahorse. The dust structure art is provided to courtesy of our neighboring Large Magellanic Cloud. The Large Magellanic Cloud is inside a star forming region near the Tarantula Nebula. The nebula is in the midst of forming a star cluster is referred to as NGC 2074. The center is visible in this image if you look towards the top around where the neck of the seahorse is. This image was taken back in 2008 by the Hubble Space Telescope using its Wide Field Planetary Camera 2 to celebrate Hubble's 100,000th trip around Earth. As these stars form in the cluster, their light and wind will erode the dust structure away over the next million years or so.

Observation (12.3)

In all honesty -astronomy is starting to impact my life. The other day while the sky was clear I was too busy identifying constellations such as Ursa Minor to notice the car heading for me. Also, I had to explain to my coach why I was late for a 5 am practice because I was too busy trying to find zodiacal constellations across the ecliptic. This morning was beautifully clear, but as much as I wanted to stop and stare -I knew I coach wouldn't buy my excuse again.

APOD 2.4

The wonders of the universe mix with the wonders of imagination with this artist's concept of dust disks that may be forming planets. The observations are done of nearby stars by infrared light. The Spitzer Space Telescope and the Herschel Space Observatory have found that planetary system HD 95086 has 2 dust disks (above)- a hot one near the star and a cooler one at a further distance. The artist took the liberty of forming their own planets with rings. The planets may explain why there's such a large gap between the rings by their absorption and deflecting of dust via their gravity. HD 95086 is a blue star about 60% larger than our own. It lie 300 light years from Earth, but is visible with binocular toward the constellation of Carina. By monitoring these rings, astronomers may get an inside look at how our own solar system formed.

APOD 2.3

One of my observation posts that I made during a week of unclear skies was on a podcast from Astronomycast.com -and the podcast? the Rosetta Mission in route to land on a comet. Well I guess I'll count this as a success! Philae, after two bounces, landed on C67/P Churyumov-Gerasimenko. There is less illumination for the solar pannels than astronomers had hoped for- but that is the only complaint. All sytems are fully functional and the pictures (like the one above) are coming through nice and clear. The Rosetta Mission won't come to and end (if all goes well) until December of 2015, after the comet has passed by the Sun.

APOD 2.2

Words cannot begin to describe my envy for the person standing atop a mountian and getting an up close and personal look at an aurora. To see an aurora in person is on my personal bucket list, and whoever this person is got an experinec of a lifetime. The person in is northen Norway, on the summit of the Austnesfjorden fjord close to the town of Svolvear on the Lofoten island. Due to the sun reaching its maximum surface activity of its 11 year magnetic cycle, auroras like this one have not been a rarity.

APOD 2.1

Black holes. The ultimate nightmare, the unknown, the "once you go in you'll never come back" of  the universe. The picture above is a computer generated image of what it would look like to confront a black hole straight on. The gravity of a black hole is so powerful that it bends light and sends it back towards you. Black holes are the densest state of matter in the universe (that we know of). This particular image's background is form the 2MASS infrared sky survey, and the stars used are from the Henry Draper catalog.

The Great World-Wide Star Count

Date: 10/28/14
Local Times: 8:30
Magnitude Limiting Magnitude 3 (Cygnus)
Lat: 27.26
Lon: -82.46
Country: United States of America

It was extremely cool to be apart of something this big!

Stargazing (10.18.14)

The brave souls that fought off the mosquitos got to opportunity to see many abnormalities of the sky. Judging by the ability to see all 7 stars of Ursa Minor- tonight was what astronomers call a "severe clear".
Some of the astronomical objects we saw:
M27
M57
M11
The Summer Triangle
Ursa Minor
Alberio (the binary)
Epsilon Lyrae  (the double double)
Job's Coffin
5 Satellites
1 shooting star (meteor)
Cepheious
The Northern Cross
Antares
Around 6 1st magnitude stars
Mars
Saturn

Nights like these are a great time to keep looking up!

APOD 1.8

Some of the astronomical happenings that we've observed we cannot yet fully identify and understand. One of those phenomena is the allusive 'lighting sprite". An APOD member was lucky enough to catch a video of the sprite (at 10,000 frames per second). The clip is seconds long; but the lighting is unusual. Instead of usual, clean, streaks- the lightning sprite more resembles bombs dropping to the ground. Only certain thunderstorms carry lightning sprites, which is why it's so difficult for those who try to be able identify their origins. Like many astronomical occurrences- our technology will have to catch up to the universe before we can get a full understanding,.

APOD 1.7

A picture-perfect example of a natural wonder. Natural sandstone monoliths the "Temple of the Sun" (left) and the "Temple of the Moon" (right) are 'connected' by a Milky Way Galaxy 'bridge'. The Temples stand in Capital Reef National Park of Utah in the US. The Temples have been around since the Jurassic period (160 million years ago), mere babies in regards to the stars, including the Andromeda Galaxy that seems to connect them. The sight is awe-inspiring.

APOD 1.6

NGC 7635- The Bubble Nebula. Like many things of nature, the most innocent of appearances is linked to the most violent. The bubble itself has a diameter of 10 light years, with an O star in the center. The O star alone is over 100,000 times for luminous and 45 times bigger than our Sun. The Bubble Nebula is a result of violent winds from a massive star. The wind combined with the radiation blasted the Bubble Nebula into its shape. The Bubble is surrounded by a dense molecular cloud containing ionized hydrogen and oxygen. From Earth, the Bubble Nebula is 11,000 light years away- just little bigger than the bubble itself.

Observation Post (10.2.14)

Due to the unfortunate weather conditions this week- I have not been able to do very much observing. So I took Mr. Percival's advice and went onto www.astronomycast.com and listen to one of their episodes. The episode I chose was Episode 351: Asteroid Adventures.

Episode 351: Asteroid Adventures
This episode focuses on Rosetta's arrival at Comet 67/P. They're landing Rosetta on the Comet- something scientists didn't think there was enough gravity to do. Comet 67/P is beyond Mars. It is making an elliptical orbit around the comet, which it will eventually harpoon and land on. Solar power here is almost non-collectable and it takes 10-11 years to get the correct orbit and ability to land. Rosetta will approach Comet 67/P at 2 miles an hour until it touches, then it will eject 2 harpoons to anchor itself. Comet 67/P is about the size of Texas, meaning it has extremely low gravity.
Comet 67/P will only get aobut 3 AU from the Sun. The goal of the mission is to collect samples of what comes off of the comet, and what to comet does, as it passes perihelion in December of 2015.

APOD 1.5

During the Stargazing last week, I was able to see Saturn and its rings through Mr. Percival's telescope. It was one of the most interesting things I've ever seen. The rings of Saturn are so thin that when they face the Earth and Sun, they seem to disappear. This happens every 15 years, like so many things in astronomy, you have to know what's approaching or it might be a very long time if you ever get to see it again. This picture (a composite of 75), was captured by Cassini, its orbiting satellite. The rings almost look transparent. There's pictures help us determine the particle size of Saturn's rings, along with its dynamics of orbital motion. The rings are dark enough to even make out some of Saturn's clouds. As our technology expands, so does our knowledge.
 

Regiomontanus (Essay)

Amber Stich

Percival

Astronomy

15 September, 2014

Johannes Regiomontanus

            Born on June 6^th, 1436 in Konigsberg, Franconia, Johannes Muller Latinized his name to “Johannes de Monte Regio” (Latin for “King’s Mountain"). He would later come to be known as Johannes Regiomontanus. Inspired by astronomer Georg von Purbach, Regiomontanus enrolled in the University of Vienna on April 14^th, 1450, at the age of only 13. By the time he was 15 years old, Regiomontanus earned his bachelor’s degree on January 16^th, 1452. Due to University restrictions, a student had to wait to be 21 years of age in order to earn their master’s degree, Regiomontanus received his in 1457 at this minimum age. On November of the same year, Regiomontanus joined the University faculty- Regiomontanus was now a colleague of Purbach and the two became close.

            It was because of Purbach that Regiomontanus started in on his accomplishments in astronomy. Purbach assigned Regiomontanus to revise and translate the Alfonsine Tables along with other Greek works. Purbach started translating Ptolemy’s work- and on his death bed, Regiomontanus promised to see his work finished, they called it the Epitome of Astronomy. In the Epitome, Regiomontanus pointed out errors in Jacopo Angeli’s work.

Some of Regiomontanus’s literature became extremely popular. Regiomontanus started the first newspaper dedicated solely for providing error-free literature on astronomy and mathematics. He published this paper in hopes of advancing science by providing quality information. Another popular work of Regiomontanus was Ephemerides (1447), this work was the first of its kind; it gave positions of the heavenly bodies every day from 1473-1506. Which is astounding for the technology they had at that time.

When the rich Bernard Walther started in on astronomy, he gave Regiomontanus access to his observatory and workshop. It was in this observatory that Regiomontanus started his observations in regard to “The Comet of 1472”, which later became known as Haley’s comet. Regiomontanus was the first astronomer to attempt to scientifically study comets; not simply regard them as superstition.

            It was also through Purbach that Regiomontanus started his accomplishments in mathematics. In his work De triangulis omnimodis (1533), Regiomontanus developed the earliest statement of sine and cosine for spherical triangles. In his 3 part work of Tables (1490, 1557), Regiomontanus complied a value table of tangents, and also longitudes for celestial bodies in relation to daily rotations of the heavens. Regiomontanus was credited with the revival of Arabic algebra and geometry in Europe.

            Regiomontanus’s work had heavy influence on the people of the 15^th century, and among them are some popular names. Ephemerides became so popular that Christopher Columbus took it with him on his 4^th voyage; he was able to use it to gain the submission hostile Indians of Jamaica by using its prediction regarding the lunar eclipse on February 29^th, 1504. Regiomontanus and Purbach’s Epitome inspired Nicholas Copernicus and eventually led to his view on heliocentricity. It was rumored that Copernicus’s idea was actually Regiomontanus’s. In a letter to Novara, the teacher of Copernicus, Regiomontanus wrote “The motion of the stars must vary a tiny bit on account of the motion of the earth”.

            By the date of his death on July 8^th, 1476- Regiomontanus was considered one of the most important astronomers of the 15^th century. He died in Rome, where Pope Sixtus IV summoned him to reform the Julian calendar. Regiomontanus died before he could do this task. There are two speculations regarding Regiomontanus’s sudden death at only age 40: one being the plague caused by the Tibetan overflowing; the other is that upon announcing his future plans of discrediting George of Trebizond in his work Syntaxis, George’s sons poisoned him.

Regiomontanus (Sources)

Johannes Regiomontanus

Science and Its Times:

Schlager, Neil. "Johannes Regiomontanus." Science and Its Times: Understanding the Social Significance of Scientific Discovery. Detroit: Gale Group, 2000. N. pag. Web.

 Complete Dictionary of Scientific Biography:

Gillispie, Charles. "Johannes Regiomontanus." Complete Dictionary of Scientific Biography. Farmington Hills (Michigan): Gale Cengage Learning, 2008. N. pag. Web.

APOD 1.4

As we continue to ruin our planet with pollutants, or continue to run out of space on Earth as we overpopulate- we must take into consideration new celestial objects to inhabit (that of course is supposing that the human race has the desire to live on). For an object to be habitable (or to be in a habitable zone), it must have the temperature that allows it to be able to support liquid water. The four moons pictured below- Ganymede (Jupiter), Cassini (Jupiter), Enceladus (Saturn), and Titan (Saturn) all have some sort of water. These moons are all found locally in our solar system. Research suggests that exomoons could outnumber exoplanets in regards to stellar habitual zones. In our future, moons could become the most common type of habitable worlds in the Universe.

Who knows? Maybe we'll find some moons have already found inhabitants.

Observation -Stargazing- 9.18

While at the Casey Key Fish House, the clouds were heavy and lightning threatend in the distance- but the stargazing went on. Between gaps in the overcast we got to celestial objects such as: Mars, Saturn and its rings, Saturn's moon Titan, Scorpio, the Summer Triangle, Hercules, Arcturus, Deneb, the Big Dipper and Vega.
Though the clouds ended the stargazing at an early 8:59 pm, instead of the scheduled 9:30 pm, we still managed to see over 10 celestial objects.
We just had to keep looking up.

Observation Post (9.17.14)

On a clear morning at 4:35 am, I walk out my door to be greeted by the moon as it passes through its phases. As I throw my swim bag in the car, and as I look over the roof of my house I see the Belt of the Hunter as it makes its way through the sky early morning till early morning. But lately my view has been blocked by heat lighting clouds, and while the lights are pretty in their own right- they are not the lights I intended on seeing.

APOD 1.3

 

Some day, our Sun will die out. If it happens to explode, our solar system will be reduced to nothing more than remnants of a supernova. Unfortunately, it will not look like a piece for art- the colors in the picture above are untrue. When stars explode, the shock wave can reach out for light years. The collapsing of a star's core causes the supernova, which will continue to emit light from the incident for countless millenniums to come. Supernova Remnant Puppis A (above) is only 180 light years in length; but the view of the supernova (7,000 light years from our location) already graced the people of Earth some 3,700 years ago. 

APOD 1.2

Space shuttles are amazing things. They were built at a time when computers had less intelligent processing systems than the ones found in smart phones today. They are entrusted to take astronauts from our world into a limitless frontier. They're one of our greatest technological achievements to date. Space shuttles don't kill, they don't entertain, they don't make life easier for us; they were built for us to be able to expand our horizons, to see things never possible before, they're a source of transportation to new discoveries and knowledge that was out of our grasp prior.

The space shuttle named "The Endeavor" alone made 5 different trips into space. From 1992 to 2011, this $196 billion space shuttle was in and out of our planet. It's a piece of history.

 

 

APOD 1.1

Let’s be open about open clusters, or “galactic clusters” if you’d prefer. These clusters form thousands of stars around the same time out of a single giant molecular cloud. In our galaxy alone, there are around 1,100 clusters… that we know of. A mutual gravitational attraction loosely holds the cluster together, this is not strong enough to prevent other clusters or gas clouds from breaking off pieces as the cluster moves through space. These clusters last about a few hundred million years (nothing major). These clusters help up study stellar evolution, seeing as the stars are all similar age and chemical composition as opposed to the lone star. Some of these clusters are even big enough  as to be seen with the eye alone.