User:Pahazzard/sandbox

Coordinates: 52°23′04″N 1°47′18″W / 52.38454°N 1.78839°W / 52.38454; -1.78839
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Bold text[1]

  1. ^ "Vision of Britain, Population Statistics, University of Portsmouth, Birmingham District through time. Total Population, A Vision of Britain through Time". Retrieved 15 July 2013.

Lotus 49, Lotus 72

http://en.wikipedia.org/wiki/User:Skysmith/Missing_topics_about_Engineering Air reheater Air vessel Air-handling system Primary air Secondary air Transfer grille Air washer Working pressure Zone control Air valve Overflow pipe prefilter


Italic textBold textPopular_Science_Monthly [1] Commons images [1]

microtasimeter[edit]

Thomas Edison

Another offshoot of the carbon experiments reached fruition sooner. Samuel Langley, Henry Draper, and other American scientists needed a highly sensitive instrument that could be used to measure minute temperature changes in heat emitted from the Sun’s corona during a solar eclipse along the Rocky Mountains on July 29, 1878. To satisfy those needs Edison devised a “microtasimeter” employing a carbon button. This was a time when great advances were being made in electric arc lighting, and during the expedition, which Edison accompanied, the men discussed the practicality of “subdividing” the intense arc lights so that electricity could be used for lighting in the same fashion as with small, individual gas “burners.” The basic problem seemed to be to keep the burner, or bulb, from being consumed by preventing it from overheating. Edison thought he would be able to solve this by fashioning a microtasimeter-like device to control the current. He boldly announced that he would invent a safe, mild, and inexpensive electric light that would replace the gaslight.

The Tasimeter.—Fig. 32 shows in perspective the latest form of the Edison microtasimeter, or measurer of infinitesimal pressure. The value of the instrument lies in its ability to detect small variations of temperature. This is accomplished indirectly. The change of temperature causes expansion or contraction of a rod of vulcanite, which changes the resistance of an electric circuit by varying the pressure it exerts upon a carbon-button included in the circuit. During the total eclipse of the sun, July 29, 1878, it successfully demonstrated the existence of heat in the corona. It is also of service in ascertaining the relative expansion of substances due to a rise of temperature

ref: Popular Science Monthly/Volume 14/December 1878 [2]

west mids geology[edit]

London example[edit]

The geology of London comprises various differing layers of sedimentary rock upon which London, England is built.

Oldest rocks[edit]

The oldest rocks proved through boreholes to exist below London are the old, hard rocks of the Palaeozoic. These consist of Silurian mudstones and sandstones,[2] generally overlain by Devonian strata which are largely of Old Red Sandstone. The Devonian rocks are absent in parts of South London.[3] The Palaeozoic rocks dip southwards and are more than 1,000 metres below the English Channel. Above this is a 60 metre thick layer of impermeable Gault clays. These clays are relatively young, only going back to the early Cretaceous which began around 144 million years ago.

On top of these clays is a non-contiguous layer of Upper Greensand above which lies a rolling bed of white chalk about 200 metres thick. In the Lower Chalk and in the lower region of the Middle Chalk there are abundant fossilized shell fragments, especially Inoceramus clams. In places these form the greater part of the rock but they decrease in amount upwards in the succession. Flints are abundant in the Upper Chalk.

These bands of chalk form the basis of the London Basin, a v-shaped syncline bounded by chalk outcrops forming hills: the North Downs to the south of London, and the Chilterns to the north. The chalk is a soft white limestone that is different in appearance to other limestones because it is porous and earthy whilst others are compact and crystalline.

Tertiary period[edit]

The chalk basin has been infilled with a sequence of clays and sands of the more recent Tertiary Period (1.6 to 66.4 million years old). Most significant is the stiff, grey-blue London Clay, a marine deposit which is well known for the fossils it contains and can be over 150 metres thick beneath the city. This supports most of the deep foundations and tunnels that exist under London.

Also in this area are the Lambeth Group (formerly known as the Woolwich and Reading Beds) and Thanet Sands. Most of these sand and clays were deposited 60-50 million years ago during the Eocene. Southern England at this time was covered by a warm tropical sea: this is shown by the fossil evidence. The sands contain animals that lived in both estuaries and freshwater. Some species burrowed into the underlying chalk.[4]

Quaternary Period[edit]

Above this is the subsoil which consists of deposits of gravel up to 10 metres deep. This was deposited during the last ice-age ½ million years ago when the River Thames was diverted to its present position. While establishing its new path, the river eroded its valley, creating a series of sand and gravel terraces. These terraces are named after the area they are best known in, for example: Dartford Heath Gravel, Swanscombe, Orsett Heath, Corbets Tey, Mucking, West Thurrock, Kempton Park, Shepperton, Staines and Tilbury Gravels.[5]

The sand and gravel terraces are made up of pebbles with flint, quartz and quartzite. In places, there are deposits of brickearth, which is a mixture of clay and sand that has supported London's long-standing brick-making industry. Atop these natural layers are the deposits of hundreds of years of human occupation. In the oldest parts the City of London and the City of Westminster this layer can be up to 6 metres deep.[6]

See also[edit]

References[edit]

  1. ^ Phenomena "Popular Science Monthly, Volume 02, March 1873". Retrieved 21 December 2012. {{cite web}}: Check |url= value (help)
  2. ^ Chilterns 1:250,000 map sheet, British Geological Survey (1991)
  3. ^ Sumbler, M.G., London and the Thames Valley, British Geological Survey (1996)
  4. ^ Story of London retrieved 14/1/07
  5. ^ BBC retrieved 14/1/07
  6. ^ Shoreham by Sea Geology retrieved 14/1/07

Birmingham[edit]

Birmingham is located in the centre of the West Midlands region of England on the Birmingham Plateau - an area of relatively high ground, ranging around 500 to 1,000 feet (150-300 m) above sea level and crossed by Britain's main north-south watershed between the basins of the Rivers Severn and Trent.

Birmingham is dominated by the Birmingham Fault which runs diagonally through the city from the Lickey Hills in the south west, passing through Edgbaston, the Bull Ring to Erdington and Sutton Coldfield in the north east. To the south and east of the fault the ground is largely softer Keuper Marl, interspersed with beds of Bunter pebbles and crossed by the valleys of the Rivers Tame, Rea and Cole along with their tributaries. Much of this would have been laid down during the Permian and Triassic eras. To the north and west of the fault, varying from 150 to 600 feet (45-180 m) higher than the surrounding area and underlying much of the city centre, lies a long ridge of harder Keuper Sandstone.

A Geological Description of Birmingham from the Triassic to the Present Many millions of years ago in a climate much hotter than the present, most of the Birmingham area was covered by a vast shallow lake which lay below sea level. As there were no river outlets and water escaped only by evaporation, salts washed down into the lake became concentrated making the lake very salty. Over thousands and thousands of years enormous quantities of fine silt was washed down by floods from surrounding mountains and deposited on the lake bed forming a layer of clay hundreds of metres thick. This clay is known as Mercia mudstone, formerly Keuper marl.


The climate changed, the lake vanished and the dry red plain tilted slightly towards the north-east. The clay cracked and when it rained the water flowed along the cracks creating shallow streams and rivers. Gradually the valleys of the Cole, Rea and Tame were formed. However, the clay desert was only lightly grooved as yet.


During the most recent Ice Age which ended 10 000 years ago the land was buried beneath 3000 metres of ice. The climate was like that at the North Pole today. Slow-moving sheets of ice ground the tops from the Welsh Mountains and the great glaciers pushed great masses of earth and broken stone across the clay plain. In huge lakes blocked in by ice barriers a mile high, gales blew the water into mighty waves, which pounded the rocks into smooth gravel.


When the great thaw came, this rubble was left strewn over the landscape forming an uneven, fairly continuous layer known as glacial drift, composed of water-worn pebbles mixed with sand and clay with a few larger boulders.


As the glaciers melted great floods swept in torrents down the river valleys, washing away much of the drift, deepening the river beds into gorges. When conditions stabilised, ours was a sodden landscape: rain and countless tributary rills were starting to smooth and bevel the valley sides. Higher points and the ridges between streams were still covered in drift, but clay was exposed on the valley sides. The swollen rivers oozed through a morass of silt.


Vegetation returned, followed by animals and, some 10 000 years ago, by human beings. They found plateaux and ridges dry and firm, patchily wooded, with heath on the stoniest areas. From scores of springs at the edges of the drift, brooks rushed down the clay sides now hidden under dense oak and underbrush forest. The plateaux provided relatively easy travelling, but the slopes were muddy and the woods impenetrable. The valley floors were largely impassable bog: but here and there gravel deposits made the approaches and river bed firmer. These were discovered by animals and used by the hunters who followed their trails.


12 000 years of wind and rain and snow have rounded the valley sides, creating today's landscape; only the ridges between the rivers are flat-topped and covered with glacial drift, where it forms the highest ground; being relatively porous it soon dries out on top, but it holds water well and springs flow from its edges across the clay below. The slopes are gentle and valleys are filled with silt with trickles of streams. Overlying both the drift and the clay is 10 000 years' accumulation of topsoil, which is wetter and richer in humus on the clay.


Adapted from John Morris Jones 1970-1980 Hall Green & Hereabout and other books, material declared by the author to be free of copyright for non-commercial educational use.

West Midlands (City of Wolverhampton, Walsall, Dudley, Sandwell, Birmingham, Solihull and Coventry Districts)[edit]

The geology of the West Midlands is dominated by the South Staffordshire Coalfield, the exploitation of which has contributed greatly to the industrial and economic development of the area.


Silurian reef limestone overlooking Dudley.

Upper Carboniferous Coal Measures underlie the main conurbation of Wolverhampton, Walsall, West Bromwich and Dudley. Surrounding these shales, sandstones and mudstones are Triassic aged rocks which comprise red mudstones and sandstones. These underlie much of Birmingham and form the solid geology up to Sutton Coldfield. Within the main mass of the Coal Measures are a number of isolated outcrops of older Silurian rock. These shallow water limestones and shales contain a wide range of marine fossils and form the famous outcrops at Wren’s Nest and Dudley Castle Hill. There are also a number of igneous intrusions into the Coal Measures. Much of the area has been mantled in thick deposits of boulder clay and sands and gravel deposited by ice sheets and meltwaters during the Ice Ages of the last two million years.

Silurian

The oldest rocks present in the area are of Silurian age (443 - 417 million years ago). These outcrop, at Dudley Castle Hill, Wren’s Nest Hill and Hurst Hill and also as an isolated block in east Walsall. Their presence here is due to folding and faulting of the rock succession which has led to the main Silurian succession of the Welsh Borders, being brought to the surface in this area.

The Silurian rocks of the West Midlands and the Welsh Borders have traditionally been split into three units on the basis of the type of rocks and the fossils they contain. In the West Midlands, rocks of the Middle Silurian Wenlock Series are represented by the Wenlock or Dudley Limestone. This shallow marine limestone contains a rich and varied suite of fossils including corals, brachiopods, crinoids (sea-lilies) and trilobites. The succeeding shales seen at Dudley belong to the Lower Ludlow Shales of the Ludlow Series. Like the underlying limestone, the shales are richly fossiliferous and yield many types of brachiopods and trilobites. Good displays of the fossils can be seen in Dudley Museum.

Carboniferous

The Carboniferous Period (354-290 million years old) is represented by the Coal Measures of the South Staffordshire Coalfield. These rocks were deposited on a low-lying area of river deltas, feeding off an upland area to the north. The periodic flooding and building of the deltas along the coastline resulted in the deposition of a series of layers of coals (representing the compressed remains of the luxuriant swamp vegetation) interspersed with layers of shale, clay, sandstone and mudstone. The Lower and Middle Coal Measures contain the once economically important coal seams, together with thick sequences of mudstone and shale. These underlie the Dudley-Walsall area. The Upper Coal Measures outcrop between Halesowen and West Bromwich and largely comprise marls, red sandy mudstones and grits. These sediments mark the oncoming of more continental conditions due to uplift of the land at the end of the Carboniferous Period.

Several intrusive masses of igneous rock (basalt or lava) occur in the Coal Measures of the West Midlands. These include outcrops at Rowley (the Rowley Hills), at Wednesfield and Pouk Hill near Walsall. At Rowley, the basalt, known as ‘Rowley Rag’ shows the characteristic columnar jointing. These originally molten rocks were probably intruded during a phase of uplift and mountain-building in the late Carboniferous or early Permian.

Permian and Triassic

The Permian (290-248 million years ago) and Triassic (248-205 million years old) periods in the West Midlands are represented by red mudstones and sandstones that underlie the majority of Birmingham, Solihull and extend northwards through to Sutton Coldfield. They also form the prominent ridge of hills that extends northwards from Bushbury in Wolverhampton. These rocks were deposited under arid, desert conditions. The Lower Triassic sandstones of the Sherwood Sandstone Group occupy the north-east of Birmingham and comprise red, yellow, and brown sandstones that often show colour mottling. Pebbles are scattered through much of the sequence in central England and include the well known Chester Pebble Beds which underlie the area between Walsall and Sutton Coldfield. Where not mantled by thick, younger drift deposits, the pebble beds and sandstones give rise to free-draining soils, such as those supporting the heathland vegetation of Sutton Park. The smoothness and roundness of the pebbles within the Chester Pebble Beds indicates that they were transported by a large and powerful braided-river system, probably on the margin of an arid, desert mountain system.

The mudstones of the overlying Triassic Mercia Mudstone Group probably represent wind-blown dust that settled in shallow salt-lakes and sun-baked mudflats on the extensive alluvial plain. These sediments underlie the south-east Birmingham conurbation and, when weathered, give rise to the characteristic red soils of the area.

Quaternary

Over the last two million years the climate of Britain has varied tremendously with periods of temperate climate interrupted by repeated advances and retreats of glaciers and ice sheets. Collectively these periods have become known as the Ice Age (we are still in one of the temperate phases) and the actions of the ice sheets have been instrumental in forming the landscape we see today.

Various deposits of Quaternary age occur in the West Midlands. The most extensive deposit is till (or boulder clay), which is formed in and beneath glaciers and ice-sheets. Much of the West Midlands has been covered at least twice by the melting and refreezing of ice sheets over the past 1.5 million years. During the last glacial advance some 20,000 years ago, ice invaded from the Irish Sea area and deposited till, sands and gravels with large amounts of gravel and boulders derived from the Lake District and southern Scotland.

Geological Highlights: The 'Black Country' is defined by geology; being the name given to the area where the 30 foot (9.15 metre) coal seam of the Coal Measures occurs. This is Britain's thickest and richest seam of coal which, together with its adjacent seams of thin coal, iron, limestone and clay, supported the development of the industrial region. The coal lies beneath Wednesbury, Darlaston, Wednesfield, Bilston, Coseley, Tipton, Dudley, Brierley Hill and Halesowen and at greater depth beneath West Bromwich, Oldbury and Smethwick. From the early 1700's scores of industrial townships and villages grew in the area to exploit the mineral wealth. The development of the coal industry directly fuelled the industrial revolution, making the area the economic powerhouse of Britain. It is recorded that by 1860, within 5 miles of Dudley there were 441 pits, 181 blast furnaces, 118 iron works, 79 rolling mills and 1,500 puddling furnaces, all pouring out smoke. This led to the region being described as 'black by day and red by night'.


Wren’s Nest, at Dudley is one of England’s most important fossil sites and is of international importance for the abundance and superb preservation of the Silurian fossils that have been found here. Collections of the fossils from the site can be found in Museums throughout the world and they have been discussed and figured in scores of publications from the 18th century onwards. At least 600 fossil species, including brachiopods, trilobites and corals are known from the limestone rocks at Wren's Nest and Dudley is quoted as "the type locality for many of these". In recognition of its geological significance, Wren's Nest was declared a National Nature Reserve in 1956/7.


The local trilobite Calymeme Blumenbachii (the 'Dudley Bug') from the Wenlock Limestone is so famous and strongly linked to Dudley that, until recently, it was to be found at the centre of the Dudley Metropolitan Borough Council’s coat of arms.

Local sites

The following localities represent, in part, the geology of this county. Each locality has a grid reference, a brief description of how to get there and a short summary of the geology you are likely to find. All the localities listed are openly accessible.

  • Wren's Nest (SSSI and NNR)
  • Doulton's Claypit (SSSI)

from [4]

Birmingham geology[edit]

source[5] William Dargue 08.04.09

Surface Geologys and and pebbles

The main Birmingham plateau can be subdivided into smaller units separated by rivers. North of the River Tame is the low Sutton Plateau which lies west of Sutton Coldfield town centre between Aldridge and Hamstead in the west and Bassetts Pole to Tyburn in the east. On its western edge a ridge runs from Shire Oak to Queslett where it rises up to the prominent landmark of Barr Beacon. The West Bromwich-Harborne plateau is a similar low plateau lying south of the River Tame, west of the River Rea. On the low eastern edge of this plateau was founded the tiny Anglo-Saxon settlement of Birmingham. To the south is the higher ground of the Sedgley-Northfield Ridge which marks part of the main English watershed.


These plateaus overlie a mixture of sand and pebbles, made up of beds of quartzite bunter sandstone and pebbles derived from the sandstone. These are Triassic, probably laid down in desert conditions over 200 million years ago. South of the River Rea is the Clent-Lickey Ridge which includes some of the oldest rocks in our area. Some of these date back to the volcanic times of the Precambrian period over 600 million years ago. These upland areas in the west of our region are the result of the underlying geology. Harder rocks from the Triassic period and earlier have survived the erosion of millennia to a greater extent than the lower lying areas to the east.


Land on the sand and pebble beds was formerly heathland, long tough grasses with low bushes and a few small trees. Stone Age people were able to use the pebbles as tools. The soil is light, it drains very quickly but it is not particularly good for farming. Where there were pebbles early people would find difficulty ploughing, although sandy soils would be easier. from north to south, Great Barr, Perry Barr, Handsworth, Aston, Hockley, Winson Green, Rotton Park, Ladywood, Harborne, Quinton, Bartley Green, and Rubery are on sand and pebble land.


sandstone ridge

The Birmingham Ridge runs north to south from Lichfield, through Birmingham city centre and down to Bromsgrove. This is a strip of new red sandstone (Keuper sandstone) about a mile wide which was formed in dry hot desert conditions during the Triassic period. The ridge marks the eastern edge of the areas of harder rock to the west and the softer clays to the east. Outcrops of sandstone are exposed in some places: for instance, on the Tyburn Road at Spaghetti Junction. Sutton Coldfield, Pype Hayes, Witton, Erdington, Birmingham, Edgbaston and Northfield were early Anglo-Saxon settlements on the Birmingham sandstone ridge. Open woods and grassland used to grow on sandstone soil and early hunters would have found deer, hares and birds. Sandstone soil can be good for farming and is easy to plough, but rainwater tends to run through quickly and crops may struggle in dry weather. Travelling on sandstone lands is easy whatever the weather. The stone is easy to cut for building but it wears badly; see some of the stonework of Yardley or Castle Bromwich churches, for instance.


The eastern edge of the sandstone marks a geological faultline which was particularly important to the successful development of Birmingham. Water percolated through the porous sandstone until it met the impervious red clay. Along the faultline was a series of springs which gave ample supplies of water, a factor critical to the town's early industrial development.

red clay

The main part of the Birmingham plateau is separated from the East Warwickshire plateau by the wide valley of the River Blythe. This river runs northwards from Shirley to join the River Tame near Shustoke, and the Tame itself joins the Trent north of Lichfield. The lower-lying Solihull Plateau largely south and west of Solihull town centre is made up of a red clay known as Mercia mudstone, formerly known as Keuper marl. The Rivers Cole and Blythe drain this area on which much of north-east, east and south-east Birmingham is built.


The tiny grains of clay stick together when wet and water cannot pass through. Streams on clay land flood quickly and seriously when it rains, but not for long. On clay land there were thick forests of oak and ash with holly, briar and bramble. Stone Age hunters found hares, deer and wild pigs here as well as nuts and berries. Forest trees were used to build houses and to make carts, ploughs and furniture. Wood was later made into charcoal for melting iron.


Until the Middle Ages the clay lands were part of the Forest of Arden which covered much of Warwickshire north of Stratford-upon-Avon. Early farmers found clay hard to plough, but clay lands make good farmland when broken up. Although clay can be rock-hard when dry, it retains moisture, minerals and nutrients and makes fertile soil. The clay which has a high lime content and was later dug and spread by farmers onto sandy or gravelly land to improve it. Old marl pits were later used to water livestock can be found marked on early Ordnance Survey maps.


In wet weather travel could be very difficult across the sticky clay lands, and in hot weather wheel ruts baked hard and made travel equally difficult. Early settlements on clay lands were usually not on clay but on glacial drift.


This clay is good for making pots and tiles; there were many claypits and brick works in the area. St Andrews Football Ground, for instance, was laid out on the site of extensive clay workings. Thousands of Victorian houses in Birmingham are built of bricks made from Birmingham clay.


river valleys

The gently sloping valleys of the Tame, the Rea and the Cole formed important barrier to travel until modern times. The upper Tame runs south-east from Wolverhampton and cuts the Birmingham Plateau in two from west to east. The courses of the rivers owe much to the melting of the glaciers of the last Ice Age and they wend their way largely over Mercia mudstone, formerly Keuper marl. Both the middle Tame and the Rea were subject to flooding until the early years of the 20th century when they were deeply culverted. Along their courses alluvial deposits have created marshy but fertile land.


Alluvium is fertile mud or river silt washed down into the valleys. In some valleys it made large swampy areas which were difficult to cross. Alder and willow grow well near water; the former tree was used for building, the latter for basket making. Alluvium is good black soil for farmers. Long lush grass is good for grazing cattle or for drying as hay for winter. River reeds were used for thatching roofs. The rivers also gave water for drinking, for fishing, for travelling and later power for the water mills.


glacial drift

During the Ice Ages huge glaciers pushed millions of tonnes of sand, gravel and pebbles from Wales and from the north of Britain to the Midlands. Glacial drifts with different mixtures of sand and gravel, pebbles and clay are found in many places on top of other rocks. Where sand and gravel drifts are found on top of red clay, trees do not grow closely together.


Ploughing is easier and there are drier places to build houses. Springs of fresh water can often be found at the edge of the drift. These were the first places people settled, often on south-facing slopes. Many early settlements including those at Yardley and Moseley were settlements on islands of glacial drift surrounded by clay. Drift makes good routes for travelling even near rivers and in wet weather as long as the muddy valley bottoms are avoided. Drift on river beds makes good crossing places. Many of Birmingham's main roads pick their way from patch to patch of drift to fords with firm gravel crossings. Sand and gravel brought down by the glaciers was quarried commercially.


Gravelly Hill is named after such deposits: there were a number of gravel pits near Salford Bridge. Little Pitts Farm off the Chester Road near Erdington is named after holes left by such excavations; a hollow remains in Pype Hayes Park and there were sandpits on Hodge Hill Common.


Geological Table

Aeon

Era
Period
Epoch
Began BP
Ice Ages
Evolution of Life
Location of England and Birmingham 

BP = years before present Precambrian Time - extreme geological activity

Hadean Aeon

4600 million years BP
 
No life
Uncertain

Archaean Aeon

3900 million
 
First life: algae /bacteria
Birmingham in the Southern Hemisphere and probably on land.

Barnt Green volcanic rocks laid down as volcanic ash.

Proterozoic Aeon

3500 million
At least four ice ages and interglacials
Soft-bodied invertebrates, including jellyfish

Phanerozoic Aeon

Palaeozoic Era

Cambrian Period
 
540 million BP
 
Age of Trilobites

First fish

Birmingham at the South Pole beneath the sea.

Volcanic activity.

Lickey quartzite laid down on the sea bed.

Ordovician Period

505 million
Ordovician Ice Age
 440 - 430 million years before present
First freshwater animals, corals
Birmingham at the Antarctic Circle beneath shallow seas.

Tropical limestone Wenlock reef laid down at Dudley.

Silurian Period

Early/ Late
438 million
 
First land plants, insects
Birmingham on a level with modern South America beneath tropical shallow seas.

Devonian Period

Early/ Middle/ Late
408 million
Permo-Carboniferous

Ice Age 330 - 350 million years before present

First amphibians

Age of Fishes

Birmingham in a hot dry desert on a level with modern South America.

Carboniferous Period

Upper/ Lower
360 million
First reptiles, winged insects, first forests
Birmingham in a tropical swampy river delta on the Equator. South Staffordshire coal deposits laid down.

Permian Period

Early/ Late
286 million
 
More reptiles
Birmingham in hot dry desert conditions now north of Equator.

Clent breccia, compacted gravel laid down by flash floods.

Aeon

Era
Period
Epoch
Began
Ice Ages
Life
Birmingham 

Mesozoic Era

Triassic Period
Early/ Middle/ Late
245 million BP
 
First dinosaurs/ flying reptiles

Age of Reptiles

Birmingham on a river delta in hot dry conditions east of the present Caribbean.

Mercia mudstone (clay) and Keuper red sandstone laid down.

Jurassic Period

Early/ Middle/ Late
208 million
 
First birds
Birmingham in the present mid-Atlantic.

Beneath the sea in a climate much warmer than present.

Cretaceous Period

Early/ Late

Lower/Upper

144 million
 
Age of Dinosaurs Early mammals, flowering plants
Globally high sea levels.

Birmingham beneath a shallow sea; moving towards present position.

Central Europe now land.

Cenozoic Era

Tertiary Period

Palaogene Epoch


Neogene

Palaeocene Epoch
66.4 million
 
Larger mammals
 

All of Europe now on land,

Britain joined to the continent and situated west of present Spain.

Warm climate.

Eocene

Early/ Late

56 million
 
Grasslands develop

Oligocene

34 million
 
Grazing mammals

Miocene

24 million
 
Apes & whales

Pliocene Early/ Late

5 million
 
Earliest hominids

Quaternary Period


Pleistocene Epoch
1.65 million BP
The (Great) Ice Age: at least four glacials and interglacials
Humans
Ice completely covered Midlands on more than one occasion, otherwise frozen tundra. Glaciers moved huge quantities of material southwards – glacial drifts of sand and gravel laid down.

Human stage: Palaeolithic/ Old Stone Age 500 000 – 10 000 years ago.

Holocene

10 000 years ago
Holocene interglacial
The present epoch
Mesolithic/ Middle Stone Age c10 000- 7000 years ago.

Neolithic/ New Stone Age c7000-4000 years ago.

Aeon

Era
Period
Epoch
Began
Ice Ages
Life
Birmingham 



Brief Geological History

Precambrian Time - Archaean and Proterozoic Aeons


This aeon was named with respect to the Cambrian period which follows it. The terms Archaean and Proterozoic derive from Greek and mean ancient aeon and earliest life aeon, respectively.


The Precambrian lasted some 80% of geological time and was the period when the earth was cooling and its crust thickening. By the end of this time one enormous supercontinent had formed. There was extensive volcanic activity. The oldest known rocks in the world are some 4000 million years old; the oldest in Britain are to be found in north-west Scotland. Sediments world-wide bear witness to numerous glaciations, the most severe and extensive between 1000 million and 600 million years ago. Evidence is to be found on the Isle of Islay off Scotland where sedimentary rock shows 17 glaciations on the site with a further 27 periods of nearby glaciation.


Late precambrian rocks can be found in the Lickeys on Cofton Hill, some of the oldest in the Midlands. This fine-grained brown, green or purple rock, known as Barnt Green volcanic rock, was originally deposited as millions of tonnes of volcanic ash which gradually compacted to form a hard rock.


At this time Britain was located at the South Pole. Due to plate tectonics and continental drift it has moved slowly north and eastwards for some 3000 million years.


The original definition of the Precambrian was that it predated life on earth. However, fossil evidence of early organisms has now been found over 3500 million years old. Consequently the Precambrian is now divided into three aeons: the pre-life aeon is now known as the Hadean, the Archaean Aeon saw the evolution of algae and bacteria, the aeon of soft-bodied invertebrates is the Proterozoic Aeon.



Phanerozoic Aeon - Palaeozoic Era - Cambrian Period


The term Phanerozoic derives from Greek meaning visible life and was coined to indicate the beginning of the fossil record. The present epoch is still part of the Phanerozoic Aeon. Palaeozoic also derives from Greek meaning ancient life. The Cambrian period is named after rocks in south-west England and South Wales and derives from Cambria, the Roman name for Wales.


There were at this time three large and a number of smaller continents. England and Wales and southern Ireland lay near the Antarctic Circle on a smaller sub-continent known as Avalonia which also carried Novia Scotia and New England. (Northern Scotland and Ireland at this time lay just south of the equator.)


Avalonia was drifting northwards at some 4cm per year. As it drifted it met with a continental plate below sea level which was moving southwards. The plate moved beneath Avalonia pushing it upwards and causing volcanoes and earthquakes. The Snowdon range and volcanic rocks near Nuneaton date from this time.


The climate during the Cambrian was warmer than today and sea levels rose. Sandstone is commonly found formed from sedimentary water-borne deposits around ancient seashores. The few terrestrial rocks found are water-borne deposits on floodplains and windblown sand. No life, plant or animal, inhabited the desert landscape, and with no plant roots to hold the earth in place, cambrian lands were subject to severe erosion by wind and rain.


Cambrian life was exclusively marine. A wide variety of fossil evidence marks a significant change from the Precambrian. Thousands of species of trilobites have been identified along with other arthropods. The Cambrian is commonly known as The Age of Trilobites. Sponges were common as well as brachiopods; the ancestors of sea urchins and starfish were present as were the molluscs. Graptolites, types of marine plankton are in evidence. For most of this time Birmingham lay at the bottom of a shallow sea south of the great continent of Gondwana. The Welsh slate used to roof most Birmingham houses during the 19th century was formed as deposits of mud over 5 kilometres deep in still deep marine basins in North Wales.


The Lickey ridge if made up of buff or pink-coloured cambrian Lickey quartzite. This soft sandy sedimentary rock may possibly be the result of wind-blown desert conditions. Darker quartzite on Bilberry Hill shows signs of having been deposited as sand at the bottom of a shallow sea.



Phanerozoic Aeon - Palaeozoic Era - Ordovician Period


The Ordovician System was recognised and described 1879 by Birmingham University professor, Charles Lapworth who so named the exposed rocks of the Arenig Mountains east of Bala, North Wales. He took the name from that of a local Celtic tribe, the Ordovices.


A major glaciation lasting over 10 million years dominated much of the period and substantially lowered sea levels by as much as 170 metres exposing vast new areas of land.


Flora and fauna still existed only in the sea. With no terrestrial life, the land was completely barren and oxygen levels consequently low. At the beginning and end of the period there were mass extinctions caused by the effects of glaciation and the corresponding alteration of sea levels. However, a wide variety of new small marine animals, trilobites, brachiopods, and graptolites appeared across the world. Fossils have been found of the first fish, armoured and jawless. It is thought that the first simple plants developed on land in the tropics in the middle of the Ordovician.


The rocks of the English Lake District were formed at this time. They are made up of a mixture which includes enormous amounts of volcanic ash washed into a shallow sea. Ordovician Birmingham lay beneath a shallow sea and continued to move slowly to the north-eastwards.



Phanerozoic Aeon - Palaeozoic Era - Silurian Period


The period is named after the Celtic tribe of the Silures; the first rocks to be recognized as of this period were identified in south-east Wales.


At the end of the Ordovician ice age, deposits of sedimentary rocks around ancient coasts testify to rising sea levels. There is widespread evidence of land plants and early jawed fish.


Southern Irish and Welsh rocks show evidence of the early land plants. A series of islands lay between warm shallow seas roughly where Brazil is now.


The Wenlock Reef: The Wenlock limestone of Dudley is world famous for the exceptional preservation of fossil marine fauna. Limestone is formed from the remains of coral, shells and calcified algae and was deposited when the West Midlands was covered by a warm shallow tropical sea. Some beds contain many fossil fragments indicating that the animal remains had been subject to the movement of waves; other beds contain complete fossils, perfectly preserved by rapid burial under mud on the seabed perhaps after storms. Most of these fossils were found during quarrying in the 18th and 19th centuries when limestone was used as flux in the Black Country iron industry.


The Lapworth Museum at Birmingham University contains the Holcroft Collection, some of the finest collections of fossils of Silurian Wenlock Limestone of the West Midlands and the Welsh Borders, made between 1876 and 1897 by Sir Charles Holcroft, a successful iron and coal master in Dudley. He collected some 4000 specimens including exceptionally preserved examples of more common fossils such as trilobites, corals, crinoids and brachiopods and also some rarer and more unusual fossils. The excellent trilobite specimens are known world-wide as Dudley Bugs. During the Silurian Birmingham would have been at the bottom of a shallow sea where coral reefs swarmed with millions of tiny creatures in the clear warm water.



Phanerozoic Aeon - Palaeozoic Era - Devonian Period


The first rocks to be recognized as of this period were identified in Devon and Cornwall.


The early continent of Baltica of which Britain was a part and Laurentia of which North America was part collided forming a single continent known as Laurussia or Euramerica. Mountains were raised and there was intense volcanic activity along the line of collision; in Britain this was in Scotland. In a climate warmer than the present there was widespread desert. Sediments of sandstone were formed from the eroded mountains. North of a a line from Bristol to Belgium was a great continent; to the south was shallow sea. Birmingham would have been on dry land during the Devonian and situated roughly where Colombia now lies in South America.


A wide variety of invertebrates continued to evolve in fresh and marine waters, but it is the very large number of primitive fish species which has named the Devonian The Age of Fishes. Fish, including the first carnivorous species, inhabited freshwater and marine environments. On land the first amphibians emerged from the sea and fossil evidence of the first tree forests has been found.



Phanerozoic Aeon - Palaeozoic Era - Carboniferous Period


The name Carboniferous is derived from the coal deposits, the fossilised remains of millions of trees growing in warm wet swamp conditions; from Latin carbo = coal.


Laurussia was an early continent north of the Equator consisting of Laurentia (North America) and Baltica (northern Europe) and was largest landmass during the Carboniferous. England and Wales had by now collided with Scotland, uplifting the Scottish Highlands.The coal measures ran in a continous line from Alabama through the Appalachian Mountains, via the Midlands to Germany. The Atlantic Ocean did not exist at this time. The climate was warm and sub-tropical.


Our area was periodically covered with shallow warm sea or by swampy river deltas which ran down from the great land mass to the north into a sea around the Equator. Limestone is found formed from the remains of coral, shells and calcified algae deposited in a warm shallow tropical seas.


The Carboniferous landscape was dominated by plants, from small shrubs to tall trees over 30m in height, the ancestors of our tiny club mosses. Fossil logs have been found measuring as much as one metre at the base. There was now a large variety of insect life on land and in the air. Amphibians date from end of the Devonian, but spread widely during the early Carboniferous as the only land vertebrates and grew to as long as 2m. The earliest reptiles c30cm in length have been found in the Upper Carboniferous in Canada.


South Staffordshire coal measures: Birmingham University's Lapworth Museum contains collections of carboniferous flora and fauna especially from the coal measures of South Staffordshire. Many were collected by Sir Charles Holcroft, a Black Country iron and coal master whose collection came to the museum 1917. The fossils are extremely well preserved and include a wide variety of plants and animal fossils including horseshoe crabs, insects, millipedes, arachnids, crustaceans and fish. 310 million years ago this was a wide flat river delta with a variety of habitats including fresh water, brackish water and dry land.


The shape and position of the delta constantly changed over the millions of years of the Carboniferous, so that layers of coal may be interspersed with alluvial deposits. This great river drained from the Mercian Highlands rising south and west of Coventry and fed via a great delta into the sea north of Cannock Chase. Coal deposits are found west of Birmingham from Cannock to Stourbridge in the Black Country and to the east between Tamworth and Warwick.


The coal-bearing strata consist mainly of grey shale often with associated sandstones and ironstones, once mud- or sand-banks in a great delta; of seat-earths of ganister, once soils on which forests grew; and of coal, once the peat resulting from the decay of the forests. The rhythm, - shale or sandstone,seat-earth, coal - is often repeated. Sometimes the shale contains marine fossils, but more commonly freshwater and terrestrial forms. It is believed that the rhythm was brought about by the intermittent subsidence of a very flat tract of delta to which rivers were bringing great quantities of sediment. After a subsidence the tract was flooded either by fresh river-water lagoons or by marine or brackish incursions of the sea. The rivers continue to bring in sand and mud, but chiefly the latter, until the surface rose above water level and plants began to colonise it and to convert the latest muds into fireclays. The growth of vegetation in stagnant swamps, and probably a hot moist climate, produced the peats which are now the coals. This picture explains the coalescence of seams when traced from the subsiding region of the Pennines in the north towards the more stable areas in the south where peat formation proceeded without interruption by flooding. It also explains why coals die out in the south, for here the stable land stood too high to become part of the coal swamp, whereas to the north the delta area kept intermittently sinking and this providing space for more sediment. British Association for the Advancement of Science 1950 Birmingham and Its Regional Setting article Geology by Leonard J Wills p19


In 1917 Dr Frank Raw Birmingham University collected series of carboniferous reptile footprints and tail marks on red sandstone near Alveley, Shropshire. The fossil footprints formed trackways made by many different animals. 310 million years ago this was a warm river floodplain rich in plant-life, especially club-mosses. Pools or small lakes on the flood plain were colonised by small arthropods, amphibians and reptiles. Both carnivores and herbivores were present. Some rocks have cracks suggesting that later in the Carboniferous the pools and lakes dried out under intense heat; others have rain prints on them. It is suggested that the footprints and tracks were preserved as a result of being quickly buried by sand brought down by torrential flooding.


Carboniferous deposits of Keele clay are found on Beacon Hill in the Lickeys interspersed with thin beds of sandstone. The clay was deposited by a river into a shallow lake in arid conditions. Periods of increasing rainfall carried sand mixed with the clay into the lake. The present rocks were formed as sediments on the bottom of the lake.



Phanerozoic Aeon - Palaeozoic Era - Permian Period


The Permian is named after the district of Perm in the Ural Mountains in Russia where the sequence of rocks of this period were first identified.


At the end of the Carboniferous and beginning of the Permian the Armorican/ Iberian plate which carried parts of western Europe and Spain collided with Avalonia carrying England and Wales. This collision is known as the Variscan orogeny ie. mountain building, which pushed up the earth's crust creating ranges from Ireland across southern Britain and into Germany. In England this formed the Mercian Highlands which no longer exist.


By the middle of the Permian the northern hemisphere continent of Laurasia (present North America and Asia) and southern hemisphere Gondwana (South America, Africa, India, Australia, and Antarctica) formed the supercontinent of Pangaea stretching from pole to pole. While there was extensive glaciation in the south, most of the continent was hot and dry with extensive deserts. Birmingham was roughly in the position of present-day central America and was terrestrial.


Major climate changes affected both marine and terrestrial life. Sea levels fell, the land rose and the climate became much drier bringing to an end the swamps favourable to coal deposits. Climate warming caused widespread extinctions. It is estimated that some 70% of marine species died out at the Permo-Triassic boundary, and 95% of terrestrial animal and plant life. These extinctions later resulted in expansion and diversity in terrestrial plants, insects, and reptiles, particularly pre-mammalian reptiles.


Above the golf-course on Beacon Hill in the Lickeys permian Clent breccia is found. Breccia is compacted gravel, here made up of sharp reddish fragments surrounded by large amounts of muddy rock. It was formed by flash floods rushing down from the Mercian Highlands and laid down in hot desert conditions. Although there is evidence of carboniferous limestone, pebbles are predominantly of precambrian igneous rock suggesting that the Highlands were much reduced by this time.



Phanerozoic Aeon - Mesozoic Era - Triassic Period


Mesozoic derives from Greek and means middle life. Triassic, Greek trias = set of three, derives its name from a central German sequence with three rock formations, the lower being Bunter (German bright or variegated), Muschelkalk (a marine system not found in Britain) and Keuper (a German mining term, pronounced koy-per) uppermost, thought to typify the period.


At the beginning of the Triassic the supercontinent of Pangaea comprised almost all the major landmasses of the world and covered a quarter of the Earth's surface. The climate was largely warm and dry but subject to continental extremes of temperature. Degraded sedimentary rocks of earlier periods accumulated as sediments on land throughout the Triassic. Keuper marl, now known as mercia mudstone, and new red sandstone are examples. Such sediments may be wind-deposited in desert regions or may be the result of river action. Much of Europe lay below the Triassic seas.


In the sea the ancestors of large predatory plesiosaurs evolved, but the largest marine reptiles were carnivorous ichthyosaurs which gave bore live young. At the end of the Permian some 80% of amphibians and reptiles disappeared due to increasing heat and drought. Ancestors of modern animals which appeared in the Triassic include lizards, turtles and crocodiles. Bipedal reptiles made an appearance to evolve into the early predatory dinosaurs which could reach lengths of over 6m. Some early lizards were the first flying vertebrates gliding using skin stretched between extended ribs. This was the Age of Reptiles. The first true mammals appeared at the end of the Triassic Period.


Birmingham lay near the south-west coast of Laurentia in the south of Pangaea on the latitude of the present Sahara Desert, but much to the west of it. As the shallow seas evaporated vast deposits of salt were laid down which are mined to this day across Europe, in Cheshire, for example. Triassic sand and bunter pebble beds are found in Birmingham west of the north-south sandstone ridge and occur in a range of colours, mainly reds, browns and yellows. The beds are a natural source of gravel and sand and made up of a coarse conglomerate of pebbles 2-10cm in diameter, held loosely in sand.


The red colour of the sandstone indicates land-borne rather than sea-bed transportation, erosion and deposition. The iron in the wet sand oxidised on contact with the air giving the sand its rusty red colour. The deposits are the result of river action; this was the site of an enormous inland river delta which stretched from south of Worcester to north of Stoke. The pebbles are of Ordovician or Devonian origin having been washed down by this great river from the Mercian Highlands to the south and south-west which no longer exist.


Keuper marl (now known as mercian mudstone, red clay) was laid down in the Upper Triassic in semi-desert conditions. It is likely to be the final remains of the Mercian Highlands to south, degraded sedimentary rock washed down onto a wide plain liable to drying up in a hot arid climate. The plain which covered most of England to the south was probably at or below sea level, and there are signs that the sea covered the area by the end of the period. The mercia mudstone may have been overlaid in subsequent periods by later sediments which have since been completed eroded. However, they compressed the mudstone to its present consistency leaving a layer some 250 metres thick which covers most of the area north-east, east and south-east of Birmingham city centre.


mercia mudstone is thus the most recent rock to be found in our area. Later depositions of rock almost certainly occurred, but all have since been completely eroded away.



Phanerozoic Aeon - Mesozoic Era - Jurassic Period


Pangaea began to break up with North America separating from Eurasia, and Africa from India, Australia, and Antarctica. On warm shallow seabeds carbonates were deposited, the remains of trillions upon trillions of shells, to form the limestone reefs of the French Jura Mountains (after which the period is named) and of southern England. The climate was warmer than present and the polar ice caps had melted. Further coal deposits indicate a moist climate temperate to tropical.


There was abundant marine life, sharks and bony fish being predominant. Marine reptiles, plesiosaurs and ichthyosaurs also shared the warm seas. Frogs, toads and salamanders evolved at this time, but the dominant land animals were reptiles including the dinosaurs. The largest herbivore, apatosaurus reached 30m in length and weighing some 30 tonnes; the fiercest carnivore, tyrannosaurus stood 6.5 m tall with a head 1.3m long and teeth 15cm long and weighed 8 tonnes. Armoured dinosaurs evolved. Crocodiles, marine turtles and lizard appeared. Flying reptiles were common; they were as small as sparrows and probably warm-blooded. The first birds evolved in the Late Jurassic: archaeopteryx had claws at the ends of its wing and feathers. The first small shrew-like mammals appeared.


Although there is no geological evidence in our area of the Jurassic period, it is likely that the Birmingham area was beneath the sea for most of this time and located south and west of its present position. Higher ground in Scotland, Wales and south-west England was above sea level, as at times was the London area.



Phanerozoic Aeon - Mesozoic Era - Cretaceous Period


The name Cretaceous derives from Latin creta = chalk, a fine soft limestone made up chiefly of the armoured plates of planktonic floating algae.


As the break-up of the Pangaean supercontinent continued, continents began to take on their present shapes, although Europe was separated from North America by a very narrow Atlantic Ocean and from Africa by a very wide Mediterranean Sea. Sea levels varied throughout the period but were the highest in the history of the Earth, by the end of the Cretaceous some 250 higher than at present. All continents lost large amounts of land to the sea which lay wide and shallow around the coasts.


A wide variety of ammonites were prey to larger animals including marine reptiles, the mosasaurs. Other reptiles were plesiosaurs and ichthyosaurs. The ancestors of modern fish were prey to sharks and rays. In the air flying reptiles, the pterosaurs held sway, quetzalcoatlus having a 15m wingspan. The Age of the Dinosaurs continued on land. Early cretaceous plants included cycads, ginkgoes, conifers, and ferns; later to evolve were magnolias, poplars, willows, sycamores, and herbaceous plants. New plants brought new insects. At the end of the Cretaceous the dinosaurs became extinct. Although terrestrial plant life was largely unaffected, in the sea little planktonic flora and fauna was to survive. Ammonites became extinct, along with such marine reptiles as ichthyosaurs, mosasaurs and plesiosaurs. It is believed that this mass extinction may have been caused by a massive meteorite impact on the Yucatan Peninsula in Mexico whose shock waves and subsequent dust clouds caused such severe climate change that many species could not adapt quickly enough to survive. It was in the wake of this event that the surviving life-forms adapted to fill the gaps and become the present successful fauna. Placental and marsupial mammals evolved at this time, as did penguins and marine mammals such as the seal and walrus.


At the beginning of the Cretaceous Birmingham was probably at the bottom of a shallow sea, that grew ever deeper, and was at a higher latitude than the present, perhaps on a level with present-day northern Germany.



Phanerozoic Aeon - Cenozoic Era - Tertiary Period Epochs: Palaeocene, Eocene, Oligocene, Miocene, Pliocene



The name Cenozoic signifies recent life; the Tertiary is the third period following the Palaeozoic and Mesozoic. The -cene of the names of the epochs Palaeocene, Eocene, Oligocene, Miocene, Pliocene derives from Greek and means recent with respect to the types of modern flora and fauna to be found. The epochs are thus respectively ancient, dawn, fewest, less, more modern species. American usage is increasingly to dispense with the term Tertiary in favour of Palaeogene (Greek = old type) with reference to the Palaeocene, Eocene and Oligocene epochs, and to use Neogene (Greek = new type) to cover the Miocene and Pliocene. Some also include the Quaternary Period to the present as the Neogene.


The continents are recognisable as the precursors of the present. The Atlantic continued to widen, the Mediterranean to narrow. Europe was approaching its present position in the northern hemisphere. The break-up of the Laurasian supercontinent was completed in the Eocene by the formation of the Norwegian-Greenland Sea which united the Atlantic and Arctic oceans. Climatic conditions remained subtropical at northern latitudes during the Cenozoic Era. The early Eocene witnessed the warmest conditions of the Cenozoic with evidence of subtropical plants in the south-east of England.


During the Oligocene and Miocene periods the earth's mantle swelled up beneath the Irish Sea causing the whole of Britain to tilt. The north-west of England was raised by up to 2km as a result of the same movements that created the Alps. It is likely that the horst of South Staffordshire and the East Warwickshire Plateau were raised up. During this and the succeeding periods of glaciation, erosion has moved millions of tonnes of rock from the surface of Britain, the more so at higher altitudes. The result of this is that older rocks can now be found at the surface in the north-west, with progressively younger rocks at the surface moving towards south-east of England.


This was a time of mammal diversification: mammals had existed for 100 million years but now evolved into many forms and spread dramatically. Hoofed mammals evolved during the Palaeocene Epoch and proliferated into horses, tapirs, and rhinoceroses, and into pigs, peccaries, hippopotamuses, camels, llamas, deer, giraffes, sheep, goats, musk-oxen, antelopes, and cattle. Elephants of many types spread throughout the world. Some mammals grew to giant size in the Pliocene such as the sabre-toothed cat, the giant ground sloths and woolly mammoths. At this time the first hominids appeared. Early humans did not emerge until the Pleistocene Epoch of the Quaternary Period. The first modern humans did not arrive here until after the Great Ice Age at the end of the Pleistocene.



Phanerozoic Aeon - Cenozoic Era - Quaternary Period - Pleistocene Epoch


The Pleistocene Epoch is usually known as The last Ice Age or The Ice Age. Its name derives from Greek = most modern (species) epoch.


The formation of glaciers actually began at the end of the Tertiary Period, but continued and ebbed and flowed throughout the Pleistocene. At times a third of the Earth was covered in ice, as were significant amounts of sea (At present one tenth of the earth is covered with ice.) There were ice sheets in North and South America, in the Alps, Siberia, New Zealand and even on African mountains on the Equator. Across northern Europe the Scandinavian Ice Sheet covered most of Britain (as far south as Bristol and north London) and Ireland, Germany, Poland and Russia. The weight of thousands of metres of ice (Birmingham was over a mile beneath the ic sheet) caused the land beneath to sink and land beyond to rise, the reverse occurring when the glaciers melted. Glaciers pushed huge quantities of rock which were deposited as moraines at the melting ends of the ice sheets. The Scandinavian ice sheet eroded the bedrock leaving patches of glacial drift several metres thick which had been shifted sometimes hundreds of miles.


Glacial ice completely covered the Midlands once only during the Anglian stage c444 thousand years ago. It is possible that ice also covered the Midlands during the Wolstonian stage 128-367 thousand years ago. The north west Midlands were covered during the latter part of the Devensian stage 15-20 thousand years ago This was the most recent ice age in Britain c10-116 thousand years ago.


The solid geology of the West Midlands is overlaid in places by a variable thickness of glacial drift deposits. These may be over 30m thick though 2-10m is more typical. The rock found in Birmingham drifts generally originates from North Wales and are made up of triassic sand and pebbles mixed with carboniferous and trassic clays. Some large mammals evolved adapted to Arctic conditions, including woolly mammoth, woolly rhinoceros, musk ox, moose and reindeer. They lived in periglacial areas ie. on permafrost or tundra beyond the limit of the glaciers. Large temperate zone mammals present during the warmer inter-glacials included included elephant, mastodon, bison, hippopotamus, wild hog, deer, giant beaver, horse, and ground sloth. However, in general the temperate zone was much further south than the present.


The Pleistocene saw the appearance and evolution of our own genus, homo and is where where geological time merges into human prehistory. The oldest species, homo habilis evolved during the late Pliocene. In Africa fossil evidence has been found 2 million years old. Homo erectus is found in Africa c1.6 million years ago, spreading to other parts of the world during the early Pleistocene; fossils have been found in China and Java c1 million years old. Early forms of our own species, homo sapiens, evolved in the middle Pleistocene c400 000 years ago. More modern forms, homo sapiens neanderthalensis appeared c100 000 years ago during the last interglaciation and are found in Europe and Asia. They became extinct c35 000 years ago replaced by ourselves. At the end of the Pleistocene many large mammals, including mammoths, mastodons, ground sloths, and giant beavers became extinct.


Evidence of homo heidelbergensis and homo neanderthalensis has been found in Essex and in Kent. They may well have walked this way too. In Warwickshire and Worcestershire have been found the fossilised bones of Pleistocene animals: auroch (the ancestor of European bison and domestic cattle), elephant, hippopotamus, hyena, mammoth, stag and wolf. Nearest to Birmingham were auroch, elephant and stag at Shustoke and mammoth bones at Dudley and Minworth. Stone Age handaxes have been discovered at Waverley Wood Farm Pit near Coventry.



Phanerozoic Aeon - Cenozoic Era - Quaternary Period - Holocene Epoch The present epoch


The Quaternary is the fourth period following the Palaeozoic, Mesozoic and Tertiary. Holocene means most recent epoch ie. the present epoch. The end of the Pleistocene is generally taken to mark the end of the Great Ice Age. However, it cannot be known whether this is true or whether we are at present living in an interglacial period.


At the end of the Pleistocene the ice melted quickly. It is estimated that at its height c8000 before the present some 18 trillion tonnes of meltwater were being released annually raising the sea level by 5cm each year flooding former coastlines. As a result Britain became separated by sea from mainland Europe. Another effect caused by the removal of the tremendous weight of the ice sheets was that the level of the land previously under ice began to rise, in Scotland eventually by some 15 metres. The marginal bulge beyond the glaciers also began to subside: recent studies of the Solent show flooding of areas previously above sea level. The end of the Ice Age also saw an enormous increase in rainfall.


Gradually the ice-age tundra became covered with the arctic trees, aspen and birch, subsequently pine and hazel, then alder and oak, then elm and lime, ash, beech, holly, hornbeam and maple which covered virtually the whole of Britain by 7000 BC. Neolithic people spread across Europe and Asia in a climate pleasantly warmer than the present. There were the beginnings of deforestation and consequent land erosion as Bronze Age people extended pastoral and arable agriculture as well as using charcoal for smelting. During the Holocene the human race has increasingly made a major impact on the Earth. However, despite the effects of global warming it is believed by some that we are at present in an interglacial period and that another ice age may be expected.


As for the future: it is estimated that the African continental plate will continue to collide with the Eurasian plate on which the British Isles is situated for many tens of millions of years. Eventually the Atlas mountain ranges of north-west Africa will be pushed up as far as Paris and Berlin. The Eurasian plate is moving north-eastwards at a speed of some 8 mm per year and will, in perhaps 250 million years, lie where Siberia is at present.

Monkspath meadow[edit]

Monkspath Meadow
Site of Special Scientific Interest
LocationWest Midlands
Grid referenceSP145763
InterestBiological
Area1.2 hectares
Notification1986
Location mapEnglish Nature

Monkspath Meadow is a 1.2 ha (3.0 acres) ancient hay-meadow and a biological site of Special Scientific Interest in the West Midlands. The site was notified in 1986 under the Wildlife and Countryside Act 1981. It is on the south-eastern edge of Monkspath. The site has recently been targeted for development for houses but these plans have been met with uproar from locals in Monkspath and nearby villages, such as Cheswick Green and Hockley Heath, as it would destroy such a special natural site.

The site has probably been used as a hay meadow for over 800 years, and has not been ploughed for at least 200 years. It was originally at risk of development from the construction of a new local supermarket and garden centre in 1986. It was saved from development by a campaign led by Members of Warwickshire Nature Conservation Trust when proposals for the new supermarket were outlined. A further 1 ha (2.5 acres) of meadow was relocated in 9 in (23 cm) deep turves to a new site at Temple Balsall.[1]

Today Notcutts Garden Centre manages the site under the direction of English Nature. The meadow supports a diverse level of flora with over 150 recorded species, including various grass species such as Common bent Agrostis capillaris, Red fescue Festuca rubra, Yorkshire fog Holcus lanatus and tufted hair-grass Deschampsia cespitosa. Herbs include for cowslip Primula veris, betony Stachys officinalis, great burnet Sanguisorba officinalis, Dyer's Greenweed Genista tinctoria, Meadow Thistle Cirsium dissectum, Saw-wort Serratula tinctoria, Heath Grass Danthonia decumbens, Heath Spotted Orchid Dactylorhiza maculata, and Common Spotted Orchid Dactylorhiza maculata. Fauna includes for Small Heath Coenonympha pamphilus , Meadow Brown Maniola jurtina and Common Blue Polyommatus icarus butterflies.[2]

The site is open to the public under the guidance of Warwickshire Wildlife Trust on one or two weekends per year. Local schools are also encouraged to arrange field trips.[3]

Members of Warwickshire Nature Conservation Trust have saved a meadow in Monkspath, reputed to have remained in its original state without being mown or ploughed for 200 years. The turf containing hundreds of rare wild plants has been carefully transplanted to a secret site in Temple Balsall five miles away. Tesco, the supermarket chain, donated £27,500 towards the cost of the removal and the land is now Tesco's local supermarket park. http://www.solihulluk.co.uk/historydetail.php?id=28909&cid=592&f=Solihull title=Welcome to Solihull website: Monkspath page

This site is the best example of a species-rich, unimproved hay meadow in the West Midlands County. The pasture has developed on either side of a shallow valley. The grassland consists predominantly of common bent Agrostis capillaris, red fescue Festuca rubra, Yorkshire fog Holcus lanatus and tufted hair-grass Deschampsia cespitosa. This turf also contains a rich variety of herbs including cowslip Primula veris, betony Stachys officinalis, great burnet Sanguisorba officinalis), dyerÕs greenweed Genista tinctoria, saw-wort Serratula tinctoria and yellow-rattle Rhinanthus minor. There are localised damp patches dominated by rushes Juncus spp. with the unusual presence of mat-grass Nardus stricta. The wetter areas also contain a number of rarer plants including dense stands of meadow thistle Cirsium dissectum. Spotted orchids Dactylorhiza maculata agg. are scattered throughout the area. http://www.english-nature.org.uk/citation/citation_photo/1001744.pdf

See also[edit]

References[edit]

52°23′04″N 1°47′18″W / 52.38454°N 1.78839°W / 52.38454; -1.78839



The City's horticultural training facility at King's Heath Park is paired up with Pershore College. More traditional environmental concerns are constantly raised by volunteer pressure group Birmingham Friends of the Earth. That group advocate sustainable travel such as local rail revival, walking and cycling, reduction in energy demand and waste generally and the development of environmental technologies in the city



There are also undersea interconnections to northern France HVDC Cross-Channel, 1961 & 1986, 73 km, 2,000 MW, 400 kV, DC, 4 pole, Bonningues-lès-Calais, France, Sellindge, United Kingdom

Northern Ireland HVDC Moyle, 2001, 63.5km, 500 MW, 250 kV, DC, 2 pole, Auchencrosh, South Ayrshire in Scotland and Ballycronan More, County Antrim in Northern Ireland

the Isle of Man Isle of Man to England Interconnector, 2000, 104 km, 40 MW, 90 kV, AC, between Bispham, Blackpool, England, and Douglas Head on the Isle of Man,

Netherlands BritNed 2011, 260km, 1,000 MW, 450 kV, DC, 2 pole, Isle of Grain in Kent, the United Kingdom, and Maasvlakte in Rotterdam, the Netherlands.


under construction Wales Ireland East–West Interconnector, 2012, 261 km, 500MW, 400kV, DC, Shotton, North Wales, Rush North Beach, County Dublin

proposed Scotland–Norway interconnector HVDC Norway–Great Britain

Scotland - Iceland


See also[edit]

Related Lists

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Other related

References[edit]

External links[edit]


Watch! User:Skysmith/Missing topics about Engineering
Bellows expansion joint
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My Geography[edit]

Places I've drawn a pay-cheque:
Places I've visited for work: File:Flag of the Netherlands
Places I've slept overnight, holidayed or partied in:
Template purloined from Trident13 who shimmied it away from Bucketsofg who plagiarized it from Grutness who lifted idea from Moriori who half-inched from Calton who nicked it from Salsb who stole it from Guettarda who borrowed it from White Cat

Almshouses[edit]

A close of red brick almshouses erected along three sides of a rectangular green, with a warden's house in the centre of the end which is open to the street. Built in 1879 by J A Chatwin in a transitional design of Birmingham Gothic with the more up to date late 17th century revival style seen in the local idiom of moulded and cut brickwork. The end houses and the warden's house are the more lavishly decorated with the revival details. They have steep hipped, tiled roofs with gable ends and rall ribbed chimneys. The north end of the site is enclosed by a high screen wall with pointed moulded brick arcading to the upper half.

[6]

Solihull Church[edit]

The church is of cross-shaped plan with a chancel having a two-storied chapel north of it, a central tower, north and south transepts, a nave with north and south aisles, and a north porch. There was originally a late 12th century church on the site, of which the only evidence of this is the east end of the south wall of the nave with a blocked window, and the marks of its steeply pitched roof on the west face of the tower. It would have been shorter and slightly narrower than the present nave. The church was enlarged in around 1290 by Sir William de Oddingeseles with the addition or rebuilding of the central tower, the upper part of the chancel, and a vaulted chamber and chapel dedicated to St. Alphege to the north of it. A 13th century north aisle with a chapel of St. Thomas the Martyr was added to the nave and some remains of an arch between the two still exist. This was followed in the 14th century by the addition of the transepts, with the insertion of side-arches in the tower and the enlargement of those in the east and west walls. The rebuilding and widening of the north aisle followed, alongwith with the north porch. A little later in the 14th century the aisle was continued westwards, beyond the original west end. The present aisle was added in 1535, when both arcades were rebuilt and the nave lengthened.[1]

The top section of the tower was constructed much later on than the lower part, probably near the date of other 16th century work, likeley undertaken before the nave and aisles were completed. The original stone spire collapsed in 1757 and was rebuilt soon afterwards to a lesser height. The south aisle, owing to a structural weekness in the arcade and the pressure of the nave roof, collapsed in 1751 and was again rebuilt almost immediately afterwards, but the arcade and aisle again failed to resist the thrust of the roof in 1939 were heavily shored with timber until the work of restoration was again be undertaken.[1]

There have been several restorations. In 1879 the west window was renewed and other repairs executed, including work to the roofs of the nave and aisles, which were stripped and rebolted. The chancel roof, which had suffered severely from the ravages of the death watch beetle, was reconstructed in 1933. At the apex of the spire is a weather-vane. There are ten bells in the belfry, all recast and re-hung in 1932 by Taylor's of Loughborough. The church registers date from 1538.[1]

The chancel measures about 52 ft (16 m) by 22 ft (6.7 m) and has an east window of five trefoiled ogee headed lights with foiled interlacing tracery in a two centred head with hood-moulds having carved stops. In each of the side walls are four windows, each of two cinquefoiled pointed lights and a single piercing above with eight foils. Between the second and third windows is a larger pointed opening with canted reveals, through which steps lead up to the upper chapel: it has hollow-chamfered splays and the string course leaps it as a hood mould. On the south side is a priest's doorway with moulded jambs and pointed head with an external hood-mould, and the internal string-course carried over it as a stilted hood. The walls are of red sandstone. The east wall is of rubble and has a narrow loop in the gable-head. At the angles are square buttresses. There is no plinth, but below the window is a plain string-course that drops to a lower level at the buttresses. The south wall is of rough ashlar, in large courses below the string-course under the windows, and in smaller courses above. In the middle is a buttress like the others. The west bay of the north wall is similar. On the north side, east of the crypt doorway, is a stone wall-bench. The roof is gabled and has a round barrel-vault of open timbers, dating from 1933. It is covered with tiles.

The lower north chapel, in honour of All Souls, was probably the priests' chamber originally; six steps lead down to it from the chancel. It has two bays of quad-ripartite vaulting with hollow-chamfered ribs springing from corbel-capitals carved with foliage. It is lighted by trefoiled lancet windows, two in the north wall and one each east and west, chamfered outside, and rebated inside for shutters; the wall-ribs form their rear-arches. In the west wall is a fire-place 2.66 ft (0.81 m) wide with a segmental-pointed arch of rough ashlar voussoirs. At the east end is a stone altar. The door in the entrance is ancient, of nail-studded plain battens hung on straphinges.

The upper chapel of St. Alphege is approached by eleven steps from the chancel. The upper doorway, splayed across the south-west angle, has hollow-chamfered jambs and two-centred head with a hood-mould having a south mask-stop. The two northeastern windows of the chancel look into the chapel and the jambs are splayed on this side as in the chancel. The chapel measure 25 ft (7.6 m) by 11 ft (3.4 m) has an east window of three trefoiled lights with interlacing tracery like that of the chancel. The west window is similar. The two north windows are like those in the chancel and the internal hood-moulds have the trefoil treatment in continuation east and west of them, the east end with a mask-stop: also on the south side, east of the chancel-windows. The walls are of squared rubble, much as in the chancel. The east and west gable-heads are irregular, the south slopes being of sharper pitch than the north. The north wall has a buttress at each end.

The steep pitched roof follows the irregularity of the gables, the north half being wider than the south: it has open timbers forming a pointed barrel vault, the wall-plates are modern. The crossing, or base of the central tower (measuring about 21 ft (6.4 m) square) has mid 14th century arches in its four sides with plain splayed responds of coarsely tooled ashlar and having moulded bases and capitals. Immediately above them are concentric relieving arches of uneven voussoirs. The masonry about and above the arches is of squared red sandstone rubble. Over the western arch are the lines where the former steeply pitched nave roof abutted the tower much lower than the present roof: its apex is rather to the south of the middle of the arch. Over it is a small blocked window, originally external, and there is said to be a similar window in the east wall hidden by the chancel roof. The south east angle is splayed for the stair vice and has a pointed doorway with chamfered jambs: higher is the blocked rood-loft doorway.

The north transept, formerly St. Katherine's but now St. George's Chapel measures about 33 ft (10 m) by 21.5 ft (6.6 m) has a west and two east windows which resemble the chancel windows but have no carved cusp points. The window in the north wall is of four trefoiled lights and intersecting tracery similar to the chancel east window, but again without the cusp points. The walling is of red square ashlar with a string-course below the sills and a moulded plinth. At the angles are pairs of square buttresses. There appears to have been a doorway under the north window, now abolished. The walls inside are mostly plastered, except for 5 ft (1.5 m) at the south end of each side wall (the sides of the tower-buttresses) which is of squared rubble. The gabled roof has a plastered ceiling indicating from its shape trussed-rafter construction.

The south transept, St. Mary's Chapel, used as an organ-chamber and vestry, is smaller than the other and measures about 28.5 ft (8.7 m) by 17.5 ft (5.3 m). In the east wall is a doorway inserted in 1909, but no windows. The four light south window is like that in the north wall of the other transept, but all modern. The two light window in the west wall also resembles those in the other transept: the external hood-mould has head-stops. The walls are of regularly coursed red ashlar, mostly restored. The roof has a plastered barrel vaulted ceiling.

The nave measures 84 ft (26 m) by 23.5 ft (7.2 m) has early 16th century arcades of five bays with tall octagonal pillars, and east responds to match, in large courses, and with moulded capitals and chamfered bases; the arches are of two chamfered orders. The south arcade has a large number of reused 13th century small voussoirs mixed with later larger stones; the north arcade has only a few of them in the outer orders. The west responds are probably of mid 14th century date; each has a middle half-round shaft between two splayed wide hollows: the shaft has a moulded semi-octagonal base and capital with a plain vertical leaf carved in the bell on each face: the responds are of smaller courses than the pillars. There is a short length of wall east of each arcade. The southern is thicker than the arcade wall and is a fragment of the original south wall of the nave. On the north side is seen the straight joint between the 16th century masonry and the east respond of the 13th century arch to St. Thomas's Chapel, and a few of the voussoirs. Above the level of the 16th century capital the rubble buttress of the tower overhangs the south face. The west doorway has continuous jambs and four centred head moulded with shallow hollows and small rolls or shafts. The outermost roll projects from the west face of the wall and not only follows the arch as a kind of hood-mould but is continued up vertically to meet the string-course below the window sill. The jambs are of yellow and the head of red stone. The west window, renewed in 1879, is of five trefoiled lights with a range of ten quatrefoils above them and vertical tracery in a four centred head; at mid height is a plain transom; the jambs are moulded with a shallow casement. The west wall is of red ashlar in large courses with a plinth that has two moulded courses at the top and a chamfered lower member. The wall is thinned inside above the sill and of smaller courses of mixed red and yellow stone. The upper half of the gable-head is modern. Between the nave and aisles are narrow buttresses. The nave roof dates from around 1535 and has curved braces forming an open-timbered wagon-head soffit.

The north aisle has four north windows of the 14th century. The north doorway has moulded jambs and a two-centred arch in a square head with a moulded label that returns to the side of the porch as a string-course. The walls inside and out are faced with red sandstone ashlar repaired at the top and having a modern embattled parapet. The north porch is of the same date and material as the aisle. It has a two centred entrance with mouldings resembling those of the inner doorway. In each side is a small trefoiled light.

The south aisle has three south windows. The walls are of red sandstone ashlar, many of the courses being large. The plinths are like that of the west wall of the nave. The parapet, of lighter-coloured stone, is of the 18th century. The south wall has two buttresses. In the east wall are several straight joints in the masonry marking the blocking of the former archway from the transept and other later changes. They are now mostly concealed by a recently built stone altar dedicated to St. Anthony. Both aisle-roofs, of lean-to type, are of the 18th century or later.

The central tower outside is of three stages, two above the ridges of the main roofs, divided by plain string courses. The two lower stages are of red sandstone rubble, the later top stage of grey rubble. At the south-east angle is the projecting square stair-turret, tabled back at the top of the second stage. East of the turret and at the other main angles are pairs of square buttresses rising nearly to the same level. The top stage (bell-chamber) has small diagonal buttresses. The 18th century parapet is embattled and has angle pinnacles. In each wall of the second stage is a twin lancet window under a rough segmental relieving arch. All are blocked except the upper half of the south window, which has been restored. Over the north window is a clock face. Below this stage on the north and south sides are two trefoiled lancets, one on each side of the transept roof. The bell-chamber has a pair of windows in each wall, each of two trefoiled lights and a quatrefoil in a four centred head. They have embattled transoms, below which the trefoil-headed lights are walled up. The tower is surmounted by the slender octagonal stone spire of 1757, rising to 168 ft (51 m) above the ground. It is divided into five stages by string-courses and has quatrefoil spire lights alternating with blanks, in each stage. At the apex is a weather-vane. There are ten bells, all recast and rehung in 1932 by Taylor's of Loughborough. The church registers date from 1538.




Name
Type
Date
Condition
Image Notes

Grovely Castle[edit]

Grovely Castle
Pahazzard/sandbox is located in Wiltshire
Pahazzard/sandbox
Shown within Wiltshire
LocationWiltshire
RegionSouthern England
Coordinates51°07′16″N 1°55′55″W / 51.1211°N 1.932°W / 51.1211; -1.932
Typepossible hillfort
Area13 acres (5.3 ha)
History
PeriodsIron Age
Site notes
ArchaeologistsP.F.Ewence
Grinsell

Grovely Castle is the site of an Iron Age univallate hill-fort in the Parish of Steeple Langford, in Wiltshire. The remaining ramparts stand approximately 3.2 m (10 ft) high, with 1.5 m (4.9 ft) deep ditches, although ploughing has damaged the earthworks in some parts of the site. Excavations have uncovered the remains of five human skeletons within the ramparts. Entrances are located in the southwest and northeast corners of the hillfort. A circular enclosure of 35 to 40 m (115 to 131 ft) is evident in aerial photographs of the hillfort interior. There is also a later bank and ditch which runs through the hill-fort from south-west to north-east, and is probably part of an extensive surrounding Celtic field system.[2]

Location[edit]

The site is located at grid reference SU048357, to the south of the village of Little Langford. The site has a summit of 156 m (512 ft) AOD. Nearby to the east lies the Iron age site of Ebsbury, and to the south, the largest forest in Wiltshire, Grovely Wood.

References[edit]

  1. ^ a b c A History of the County of Warwick: Volume 4: section: Parishes: Solihull, Hemlingford Hundred (1947), pp. 214-229. URL: http://www.british-history.ac.uk/report.aspx?compid=42685; Date accessed: 23 February 2012.
  2. ^ "English heritage Pastscape page for Grovely castle". {{cite web}}: Unknown parameter |access date= ignored (|access-date= suggested) (help)

See also[edit]


East Castle[edit]

grid reference SU031361, http://www.pastscape.org.uk/hob.aspx?hob_id=214487&sort=4&search=all&criteria=east_castle_enclosure&rational=q&recordsperpage=10

Church end Ring[edit]

grid reference SU012355, http://www.pastscape.org.uk/hob.aspx?hob_id=214496&sort=4&search=all&criteria=church_end_ring&rational=q&recordsperpage=10

Hanging Langford Camp[edit]

grid reference SU012352, http://www.pastscape.org.uk/hob.aspx?hob_id=214496&sort=4&search=all&criteria=church_end_ring&rational=q&recordsperpage=10

Ebsbury[edit]

Ebsbury
The northern flank of Ebsbury Hill with strip lynchets visible.
Pahazzard/sandbox is located in Wiltshire
Pahazzard/sandbox
Shown within Wiltshire
Alternative nameGrovely Earthworks
LocationWiltshire
RegionSouthern England
Coordinates51°07′03″N 1°54′43″W / 51.117586°N 1.911964°W / 51.117586; -1.911964
Typepossible hillfort
History
PeriodsIron Age
Site notes
Excavation dates1906
ArchaeologistsSW Doughty

The site of Ebsbury includes the remains of an Iron Age enclosed settlement, field system and possible hillfort, and a Romano-British enclosed settlement, located in the parish of Barford St Martin, in Wiltshire.

The site occupies the spur of a downland hill with the possible hillfort enclosure measuring approximately 700 m (770 yd) by 400 m (440 yd), inside of which lies the remains of a field system with two further smaller oval enclosures and one triangular enclosure. To the north and east sides of the site the contours of the hill have been reinforced by multiple banks. The site of an iron age settlement lays to the eastern end of the site.[1]

The site was subject to archaelogical surveys and excavations in 1906 by S.W.Doughty. Finds include for a Neolithic perforated mace-head and two Roman coin hoards. The latter were found buried in two earthenware pots, the coins date from between AD 337 and AD 408, and were found with the remians of a glass vessel, and six silver rings.[1]

Location[edit]

The site is located at grid reference SU061354, just to the west of the village of Great Wishford. The hill has a summit of 175 m (574 ft) AOD. Nearby to the west lies the site of Grovely castle, and to the south, the largest forest in Wiltshire, Grovely Wood.

See also[edit]




Parts of the outer ramparts of the fort are visible as cropmarks to the south east of the complex of earthworks. The field system which extends around and beyond the hiiltop is visible as earthworks immediately around the possible fort but beyond this it has been ploughed level and is visible as cropmarks on aerial photographs. Parts of this system, in particular the lynchets on the steeper slopes (e.g. SU 03 NE 21), appear more like Medieval and/or Post Medieval lynchets and may be where the field system has been adapted in these later periods. Associated with the field system is a possible Romano-British settlement outside the east end of the fort. It comprises a series of scoops and conjoined enclosures defined by low banks. Other possible house platforms and trackways, of uncertain date, are incoroprated into the field system at the north west side of the fort. Finds of a Neolithic perforated mace-head and two Roman coins hoards ranging between AD 337 and AD 408, with part of a glass vessel, and six silver rings were found buried in two earthenware pots, in 1906 by SW Doughty while digging for stones on the line of the ramparts on the north west brow of the hill. Some of the coins and the rings are in the British Museum. The earthworks were surveyed by RCHME in the 1980's. The whole complex has been extensively recorded on aerial photographs. http://www.pastscape.org.uk/hob.aspx?hob_id=214402&sort=4&search=all&criteria=ebsbury&rational=q&recordsperpage=10


An Iron Age/Romano British (2) settlement area on Ebsbury Hill, consisting of an extensive complex of earthworks (see plan (3) and air-photographs (4)), known as Ebsbury or Grovely Earthworks (5). There are extensive runs of bank and ditch which are often multiple for part of their length, mainly of comparatively modest dimensions, which Bonney (2) suggests may have functioned as boundary banks rather than defences. These at some stage probably enclosed the settlement areas, but by the Roman period occupation seems to have been outside the main lines of bank and ditch. Bonney concludes that where the banks and ditches assume defensive proportions (SU 05943551 - SU 06143556 and SU 06443524 - SU 06483546: see plan (6)), that it is for such a short length "as to be scarcely compatible with serious defence." Grinsell (5) however considers that these probably form part of an unfinished and/or mutilated hillfort of Phase 3, bivallate on the north only with an outer rampart probably of Phase 3c. Crawford (b) was also of this opinion putting the discontinuity down to delibrate destruction by continuous cultivation. Within the circuit of the earthworks in Ebsbury Copse, SU 062353, is a small circular enclosure and linear ditch (5). A mound, 12 paces x 2 1/2ft (SU 06073552)(7) described by Crawford (6) as a barrow is discounted by Grinsell (7) as being part of the Romano British settlement. Finds from the earthworks include Iron Age 'C' sherds by Ewence (5) who also found Iron Age 'A' and 'B' (Phases 2 and 3) and Belgic (Phases 3c) sherds from within the circular ditch in Ebsbury Copse. Now in his private collection. Two coins hoards ranging between AD 337 and AD 408, with part of a glass vessel, and six silver rings were found buried in two earthenware pots, in 1906 by SW Doughty (8) while digging for stones on the line of the ramparts (SU 05793548 (7)), on the north west brow of the hill (a). Some of the coins and the rings are in the British Museum (5). Half of a Neolithic quartz mace-head with hour-glass perforation from Ebsbury Hill, was presented to Salisbury Museum, in 1965 by Mr P Dewey. (Acc no 48/65) (10). The earthworks at Ebsbury have affinities in form with two neighbouring settlements on the Grovely Ridge, namely Hanging Langford Camp (SU 03 NW 14) and Hamshill Ditches (SU 03 SE 21) (2) and in common with these settlements had a continuity of occupation throughout the Roman period and on into the early years of the 5th century. (2-10)

Centred at SU 06163538, the Ebsbury earthworks occupy a hilltop on a NE spur of downland and form a partially enclosed oval area 700m by 400m. In the interior is a field system complex (of which the mound at SU 06073551 is a part), with two associated oval enclosures and one triangular enclosure. The latter, at SU 06083534, contains two shallow scoops and is probably the nucleus of the settlement. The main enclosing bank has been strenghtened by multiple banks, for two legnths of 250 metres, in the N and E, and overlies the internal field system. It is not possible to determine by visual inspection whether or not these represent the initial construction of a hillfort. The terminals of both these sections of rampart are very abrupt, and there is nothing to suggest that the later field system outside the enclosure has destroyed any of this work (ie at SU 05883554 and SU 06493547). This field system extends over approximately 120 hectares, generally between the 400 ft and 500 ft contours, and is best preserved on the NW hillside in an area centred at SU 05463534, where terraces and field ways are an average 1.0m deep. Associated with this field system is the RB settlement outside the main enclosure, at SU 06633529. It comprises a series of shallow scoops and low banks within two adjoining enclosures which have straight sides and rounded corners, and in all extend over almost two hectares. Surveyed at 1:2500 in conjunction with RCHM manuscript plan at 1:1250. (11)

Further reference. Suggestion that the earthworks may be Mediaeval (12)

The earthworks were resurveyed by the RCHME in the 1980s. (13)

The possible late prehistoric or Roman features described above have been partially mapped from aerial photographs. The areas covered in trees, in particular the interior of the possible hillfort, have not been mapped. Part of the outer rampart of the fort is visibel as cropmarks at SU 0623 3601. It is 570m long and is defined by two parallel banks. Some additional features have been added to the field survey carried out in the 1980's by RCHME. These mainly comprise an extension of the field system which surrounds the possible fort. The ploughed down remains of this field system are visible as cropmarks north and east as far as the railway line. It is defined by a series of incomplete bank defined rectangular fields. What appears to be the remains of straight ridge and furrow is visible in some of the fields. Some possible house platforms and trackways are also visible as low earthworks to the north west of Ebsbury Copse at SU 0535 3537, SU 0532 3518, SU 0543 3534 and SU 0546 3528. It is possible these are Medieval and/or Post Medieval features. Parts of the field system have the appearance of Medieval and/or Post medieval lynchets, in particular those on the steeper slopes, (E.g. SU 03 NE 21), to the north of the earthworks, and may represent the re-use of the earlier system. A Post Medieval dew pond has been constructed over part of the settlement outside the eastern entrance to the hillfort. A possible dew pond is also visible as an oval and as a rectangular cropmark in the midst of the field system at SU 0623 3601.

The site has been extensively photographed from the air and the key photographs used to map the site are listed in the references. (14-24)

The cropmarks of further elements of the field system described by the previous authorities are visible on aerial photographs taken in 2005. These are centred on SU 0691 3493 and lie to the south of the Stonehenge WHS project area. (25-26)

The Wiltshire archaeological and natural history magazine

(D J Bonney and C N Moore) 62, 1967 Page(s)120-1

(5) edited by R B Pugh and Elizabeth Crittall 1957 A history of Wiltshire: volume 1, part 1

The Victoria history of the counties of England Page(s)36, 74, 262, 266

( 6) O G S Crawford and Alexander Keiller 1928 Wessex from the air

Page(s)120-2

( 8) The Wiltshire archaeological and natural history magazine

(G F Hill) 35, 1907-8 Page(s)115-31
( 9) Antiquity Publications Limited Antiquity
(OGS Crawford) 2, 1928 Page(s)177, 184
(10) General reference
Salisbury Museum Archaeol Report 1965-6 (Accessions) Page(s)16

(12) Medieval Settlement Research Group : annual report

31, 1983 Page(s)11
(13) Mark Corney 1989 Multiple ditch systems and Late Iron Age settlement in central Wessex

From Cornwall to Caithness : some aspects of British field archaeology : papers presented to Norman V. Quinnell Page(s)111-28

MONUMENT NUMBER:214402

Etymology[edit]

Background[edit]

Hill forts developed in the Late Bronze and Early Iron Age, roughly the start of the first millennium BC.[2] The reason for their emergence in Britain, and their purpose, has been a subject of debate. It has been argued that they could have been military sites constructed in response to invasion from continental Europe, sites built by invaders, or a military reaction to social tensions caused by an increasing population and consequent pressure on agriculture. The dominant view since the 1960s has been that the increasing use of iron led to social changes in Britain. Deposits of iron ore were located in different places to the tin and copper ore necessary to make bronze, and as a result trading patterns shifted and the old elites lost their economic and social status. Power passed into the hands of a new group of people.[3] Archaeologist Barry Cunliffe believes that population increase still played a role and has stated "[the forts] provided defensive possibilities for the community at those times when the stress [of an increasing population] burst out into open warfare. But I wouldn't see them as having been built because there was a state of war. They would be functional as defensive strongholds when there were tensions and undoubtedly some of them were attacked and destroyed, but this was not the only, or even the most significant, factor in their construction".[4]

Description[edit]

Iron Age Hillfort[edit]

Earlier Enclosure[edit]

Later Features[edit]

Construction Phases[edit]

Archaeology[edit]

Geography[edit]

Ecology[edit]

References[edit]

  1. ^ a b "English heritage Pastscape page for Ebsbury". {{cite web}}: Unknown parameter |access date= ignored (|access-date= suggested) (help)
  2. ^ Payne, Andrew; Corney, Mark; Cunliffe, Barry (2007), The Wessex Hillforts Project: Extensive Survey of Hillfort Interiors in Central Southern England, English Heritage, p. 1, ISBN 9781873592854
  3. ^ Sharples, Niall M (1991), English Heritage Book of Maiden Castle, London: B. T. Batsford, pp. 71–72, ISBN 0-7134-6083-0
  4. ^ Time Team: Swords, skulls and strongholds, Channel 4, 2008-05-19, retrieved 16 September 2009

Further Reading[edit]

  • [7] Wiltshire Heritage Museum records for Scratchbury Camp and Tumuli.
  • [8] Photograph of Scratchbury Camp finds, from Society of Antiquaries website.
  • [9] English Heritage Pastscape page for Scratchbury Camp. (Monument number: 211396)
  • [10] English Heritage Pastscape page for the Scratchbury Camp barrow group (Monument number 211401)
  • [11] Wiltshire Walks no.8: Norton Bavant and Scratchbury Hill (5.3 km/ 3.25 miles, 1 hour, Moderate)

See also[edit]