The Alluna RC-20 Ritchey Chrétien telescope was installed in March, 2016.

The telescope is able to locate and track any sky object (including Earth satellites and the International Space Station) with software called TheSkyX Professional, into which is embedded a unique T-Point model developed for our site with our equipment over the past year.

When a planet is referred to as ‘stationary’, it means that its movement across the stellar background appears to have ceased, not that the planet itself has stopped. With inferior planets (those inside the Earth’s orbit, Mercury and Venus), this is caused by the planet heading either directly towards or directly away from the Earth. With superior planets (Mars out to Pluto), this phenomenon is caused by the planet either beginning or ending its retrograde loop due to the Earth’s overtaking it.

Apogee and perigee:   Maximum and minimum distances of the Moon or artificial satellite from the Earth.

Aphelion and perihelion:  Maximum and minimum distances of a planet, asteroid or comet from the Sun.

A handspan at arm's length covers an angle of approximately 18 - 20 degrees.

m_v = visual magnitude or brightness. Magnitude 1 stars are very bright, magnitude 2 less so, and magnitude 6 stars are so faint that the unaided eye can only just detect them under good, dark conditions. Binoculars will allow us to see down to magnitude 8, and the Observatory telescope can reach visual magnitude 17 or 22 photographically. The world's biggest telescopes have detected stars and galaxies as faint as magnitude 30. The sixteen very brightest stars are assigned magnitudes of 0 or even -1. The brightest star, Sirius, has a magnitude of -1.44. Jupiter can reach -2.4, and Venus can be more than 6 times brighter at magnitude -4.7, bright enough to cast shadows. The Full Moon can reach magnitude -12 and the overhead Sun is magnitude -26.5. Each magnitude step is 2.51 times brighter or fainter than the next one, i.e. a magnitude 3.0 star is 2.51 times brighter than a magnitude 4.0. Magnitude 1.0 stars are exactly 100 times brighter than magnitude 6.0 (5 steps each of 2.51 times, 2.51x2.51x2.51x2.51x2.51 = 2.51⁵ = 100).

 Solar System

This eclipse of the Sun can be seen over the whole of the United States, so is being touted by them as the "American Eclipse". The path of totality begins in the North Pacific Ocean between Hawaii and the Aleutian Islands of Alaska. It proceeds in an east-south-easterly direction, reaching the continental USA just south of Portland, Oregon. The Moon's shadow continues over Idaho, Wyoming, Nebraska, Kansas, Missouri, Illinois, Kentucky, Tennessee, Georgia, North Carolina and South Carolina and then passes over the North Atlantic, the eclipse ending in mid-ocean.

The eclipse will be perfectly timed for observers, lasting a little over two and a half hours in mid-morning in Oregon, and a little over three hours inmid-afternoon in South Carolina. 12 million people live within the path of totality, and 25 million within a day's drive of it, so NASA has sent out traffic warnings. The totality of this eclipse is unfortunately fairly short, averaging between two and two and a half minutes. The centre of the eclipse track is near the town of Hopkinsville in Kentucky, which will enjoy 2 minutes 40 seconds of darkness at 1:24 pm. Four minutes later, Nashville in Tennessee will also experience totality. The further east in the United States you are, the more likely it is that clouds may interfere with the eclipse.

This event will be seen as a partial eclipse from Hawaii, Alaska, Canada, Central America, Equador, the Caribbean Islands, countries in South America that border the Caribbean, and north Brazil. Ireland, the United Kingdom, France, Portugal and Spain may catch a glimpse just before sunset. No part of the eclipse will be observable from Africa, most of Europe, Asia or Australia.

Full Moon:                August 08                 04:12 hrs           diameter = 30.3'     Partial lunar eclipse
Last Quarter:           August 15                 11:16 hrs           diameter = 32.2' 
New Moon:               August 22                 04:31 hrs          diameter = 32.1'     Total solar eclipse (USA only)
First Quarter:           August 29                 18:14 hrs           diameter = 29.6' 

Full Moon:                September 06           17:03 hrs          diameter = 31.1'
Last Quarter:           September 13           16:26 hrs          diameter = 32.3' 
New Moon:               September 20           15:30 hrs          diameter = 31.2'
First Quarter:           September 28           12:54 hrs          diameter = 29.6' 

Lunar Orbital Elements:

August 03:              Moon at apogee (405 053 km) at 03:46 hrs, diameter = 29.5'
August 08:              Moon at descending node at 20:54 hrs, diameter = 30.4'
August 18:              Moon at perigee (366 120 km) at 22:56 hrs, diameter = 32.6'
August 21:              Moon at ascending node at 20:35 hrs, diameter = 32.2'
August 30:              Moon at apogee (404 313 km) at 21:51 hrs, diameter = 29.6'

September 05:        Moon at descending node at 04:39 hrs, diameter = 30.6'
September 14:        Moon at perigee (369 859 km) at 01:17 hrs, diameter = 32.3'
September 18:        Moon at ascending node at 04:28 hrs, diameter = 31.9'
September 27:        Moon at apogee (404 350 km) at 16:42 hrs, diameter = 29.6'

This area was photographed from Starfield Observatory, Nambour on October 10, 2017. East (where the Sun is rising) is to the right, north is to the top. The area is dominated by the large walled plain Plato at upper left, and the impact crater Cassini at lower right. Between the two is a rugged mountainous area called the Alps, to the west of which is a large basin filled with solidified lava, called Mare Imbrium (the Sea of Rains). Some of the more notable features are named.

The rectangle shows the location of the top image on the Moon. The dotted circle shows the full extent of the Mare Imbrium.

Plato in close-up. Five craterlets with diameters of 2 to 3 kilometres are visible inside it, as well as several smaller ones.

The Vallis Alpes (Alpine Valley) is 134 km long. Along its length runs a delicate rille which varies between 500 and 700 metres across, and averages 78 metres deep. Although it looks like a water course, there is no running water on the Moon. It is probably volcanic in origin. Both images above were photographed at Starfield Observatory through the Alluna 20 inch Ritchey Chrétien telescope on August 2, 2017.

This area includes parts of two lava plains, which as they are basically cold basalt appear darker in colour than some other areas. In ancient times the Moon was thought to be a perfect, silver mirror, reflecting the seas and continents of the Earth. This idea persisted until the 16th century. By 1600, some people including Leonardo da Vinci in Italy and William Gilbert in England believed that the darker areas were reflections of our continents and the lighter areas were reflection of the Earthly seas and oceans, but most thinkers thought that the opposite was true, that the darker areas were seas ("mare" singular and "maria" plural) and the sole larger one an ocean ("oceanus"). The lighter areas were lands ("terrae"). This second view was the one held by the first makers of Moon maps, Langrenus, Hevelius, Riccioli and Grimaldi.

As Riccioli and Grimaldi have given us most of the names of places on the Moon that they could see with their primitive telescope, the darker areas in the pictures above are the Mare Imbrium (Sea of Rains) and the Mare Frigoris (Sea of Cold). The Mare Imbrium is a great circular plain on the Moon, caused by a massive asteroid impact - see "The Imbrium Event" below. All of the seas and the solitary ocean were formed by such impacts and are also dry, cold plains of solidified lava. The terrae around them are much more ancient and are totally covered with fairly large craters, most overlapping older craters, but the Seas are more recent, and show fewer large craters, although they also are peppered with thousands of craterlets.

The impact of asteroids, meteoroids, rocks, and micrometeoroids with the Moon’s surface over the eons has left it covered with a thick layer of dust, soil and shattered rocks. This layer averages 4 to 5 metres deep over the maria, but can be up to 30 metres deep in the valleys of the ancient highlands or terrae. This layer is called the regolith. The dusty upper surface is fine and powdery, like talcum powder, and holds astronaut’s bootprints very well.  The Apollo 16 astronauts landed near the crater Descartes, at a small recent crater with rays, called North Ray Crater. The regolith near this crater was found to be only a few centimetres thick. Many samples of the regolith have been brought to Earth for analysis. Those from sites on maria are generally rock fragments o f basalt, with pyroxene and plagioclase. Those from highland sites are mainly broken plagioclase rocks and crystals.

Beneath the regolith of the maria there is a layer of basalt, averaging 20 kilometres deep, formed when the initial asteroid fractured the surface down to a depth of 60 kilometres, to the Moon's mantle. These fractures released pressure on the superheated rocks in the top layers of the mantle. They immediately liquefied into molten basaltic magma which forced its way to the surface and spread out over the landscape as lava, swamping or partially swamping existing craters and mountains, and spreading out over thousands of square kilometres. The lava cooled and hardened to form the "seas" that are such a notable feature of our side of the Moon.

In the pictures above, the lava has covered the bases of the Teneriffe Mountains, Mount Pico and Mount Piton to a great depth, although their lofty peaks protrude above the plain of Mare Imbrium. The crater Plato was caused not long after the Imbrium Event, but just south of Plato can be seen the faint outline of a similar but slightly larger crater, that was completely submerged under the lava except for some of the ramparts of its wall which were high enough not to be swamped - these ramparts are now called the Teneriffe Mountains (1.4 kilometres high) and Mount Pico (2.4 kilometres high).

Three impact craters on Mare Imbrium of more recent origin are Piazzi Smyth (22 km), Kirch (12 km) and spectacular Cassini (60 km).

Between Mare Imbrium and Mare Frigoris (Sea of Cold) is a rough chain of lofty mountains, trending from north-west to south-east. Johannes Hevelius called this mountainous area the "Montes Alpes", and Riccioli named it the "Terra Grandinis (High Land"). This was one case where the name given by Hevelius was preferred over Riccioli's alternative, and the range is usually known simply as the Alps. Its highest mountain is Mont Blanc (White Mountain) and is 3.6 kilometres high.

The Alps are divided in two by a straight valley called the Vallis Alpes (Alpine Valley). It is 134 kilometres long and is a linear fault or graben that was filled with lava. Along its length runs a delicate rille that is shown in the picture above and on our  Gallery  webpage.