Geological

Geology from Ancient Greek gῆ ge earth and logia logia study of discourse is a branch of natural science concerned with the Earth and other astronomical objects the rocks of which they are composed and the processes by which they change over time Modern geology significantly overlaps all other Earth sciences including hydrology It is integrated with Earth system science and planetary science Solidified lava flow in HawaiiSedimentary layers in Badlands National Park South DakotaMetamorphic rock Nunavut Canada Geology describes the structure of the Earth on and beneath its surface and the processes that have shaped that structure Geologists study the mineralogical composition of rocks in order to get insight into their history of formation Geology determines the relative ages of rocks found at a given location geochemistry a branch of geology determines their absolute ages By combining various petrological crystallographic and paleontological tools geologists are able to chronicle the geological history of the Earth as a whole One aspect is to demonstrate the age of the Earth Geology provides evidence for plate tectonics the evolutionary history of life and the Earth s past climates Geologists broadly study the properties and processes of Earth and other terrestrial planets Geologists use a wide variety of methods to understand the Earth s structure and evolution including fieldwork rock description geophysical techniques chemical analysis physical experiments and numerical modelling In practical terms geology is important for mineral and hydrocarbon exploration and exploitation evaluating water resources understanding natural hazards remediating environmental problems and providing insights into past climate change Geology is a major academic discipline and it is central to geological engineering and plays an important role in geotechnical engineering Geological materialNative gold from VenezuelaQuartz from Tibet Quartz makes up more than 10 of the Earth s crust by mass The majority of geological data comes from research on solid Earth materials Meteorites and other extraterrestrial natural materials are also studied by geological methods Minerals Minerals are naturally occurring elements and compounds with a definite homogeneous chemical composition and an ordered atomic arrangement Each mineral has distinct physical properties and there are many tests to determine each of them Minerals are often identified through these tests The specimens can be tested for Color Minerals are grouped by their color Mostly diagnostic but impurities can change a mineral s color Streak Performed by scratching the sample on a porcelain plate The color of the streak can help identify the mineral Hardness The resistance of a mineral to scratching or indentation Breakage pattern A mineral can either show fracture or cleavage the former being breakage of uneven surfaces and the latter a breakage along closely spaced parallel planes Luster Quality of light reflected from the surface of a mineral Examples are metallic pearly waxy dull Specific gravity the weight of a specific volume of a mineral Effervescence Involves dripping hydrochloric acid on the mineral to test for fizzing Magnetism Involves using a magnet to test for magnetism Taste Minerals can have a distinctive taste such as halite which tastes like table salt Rock The rock cycle shows the relationship between igneous sedimentary and metamorphic rocks A rock is any naturally occurring solid mass or aggregate of minerals or mineraloids Most research in geology is associated with the study of rocks as they provide the primary record of the majority of the geological history of the Earth There are three major types of rock igneous sedimentary and metamorphic The rock cycle illustrates the relationships among them see diagram When a rock solidifies or crystallizes from melt magma or lava it is an igneous rock This rock can be weathered and eroded then redeposited and lithified into a sedimentary rock Sedimentary rocks are mainly divided into four categories sandstone shale carbonate and evaporite This group of classifications focuses partly on the size of sedimentary particles sandstone and shale and partly on mineralogy and formation processes carbonation and evaporation Igneous and sedimentary rocks can then be turned into metamorphic rocks by heat and pressure that change its mineral content resulting in a characteristic fabric All three types may melt again and when this happens new magma is formed from which an igneous rock may once again solidify Organic matter such as coal bitumen oil and natural gas is linked mainly to organic rich sedimentary rocks To study all three types of rock geologists evaluate the minerals of which they are composed and their other physical properties such as texture and fabric Unlithified material Geologists also study unlithified materials referred to as superficial deposits that lie above the bedrock This study is often known as Quaternary geology after the Quaternary period of geologic history which is the most recent period of geologic time Magma Magma is the original unlithified source of all igneous rocks The active flow of molten rock is closely studied in volcanology and igneous petrology aims to determine the history of igneous rocks from their original molten source to their final crystallization Whole Earth structurePlate tectonics The major tectonic plates of the Earth In the 1960s it was discovered that the Earth s lithosphere which includes the crust and rigid uppermost portion of the upper mantle is separated into tectonic plates that move across the plastically deforming solid upper mantle which is called the asthenosphere This theory is supported by several types of observations including seafloor spreading and the global distribution of mountain terrain and seismicity There is an intimate coupling between the movement of the plates on the surface and the convection of the mantle that is the heat transfer caused by the slow movement of ductile mantle rock Thus oceanic parts of plates and the adjoining mantle convection currents always move in the same direction because the oceanic lithosphere is actually the rigid upper thermal boundary layer of the convecting mantle This coupling between rigid plates moving on the surface of the Earth and the convecting mantle is called plate tectonics The development of plate tectonics has provided a physical basis for many observations of the solid Earth Long linear regions of geological features are explained as plate boundaries Oceanic continental convergence resulting in subduction and volcanic arcs illustrates one effect of plate tectonics Mid ocean ridges high regions on the seafloor where hydrothermal vents and volcanoes exist are seen as divergent boundaries where two plates move apart Arcs of volcanoes and earthquakes are theorized as convergent boundaries where one plate subducts or moves under another Transform boundaries such as the San Andreas Fault system are where plates slide horizontally past each other Plate tectonics has provided a mechanism for Alfred Wegener s theory of continental drift in which the continents move across the surface of the Earth over geological time They also provided a driving force for crustal deformation and a new setting for the observations of structural geology The power of the theory of plate tectonics lies in its ability to combine all of these observations into a single theory of how the lithosphere moves over the convecting mantle Earth structure The Earth s layered structure 1 inner core 2 outer core 3 lower mantle 4 upper mantle 5 lithosphere 6 crust uppermost part of the lithosphere Earth layered structure Typical wave paths from earthquakes like these gave early seismologists insights into the layered structure of the Earth Advances in seismology computer modeling and mineralogy and crystallography at high temperatures and pressures give insights into the internal composition and structure of the Earth Seismologists can use the arrival times of seismic waves to image the interior of the Earth Early advances in this field showed the existence of a liquid outer core where shear waves were not able to propagate and a dense solid inner core These advances led to the development of a layered model of the Earth with a lithosphere including crust on top the mantle below separated within itself by seismic discontinuities at 410 and 660 kilometers and the outer core and inner core below that More recently seismologists have been able to create detailed images of wave speeds inside the earth in the same way a doctor images a body in a CT scan These images have led to a much more detailed view of the interior of the Earth and have replaced the simplified layered model with a much more dynamic model Mineralogists have been able to use the pressure and temperature data from the seismic and modeling studies alongside knowledge of the elemental composition of the Earth to reproduce these conditions in experimental settings and measure changes within the crystal structure These studies explain the chemical changes associated with the major seismic discontinuities in the mantle and show the crystallographic structures expected in the inner core of the Earth Geological timeThe geological time scale encompasses the history of the Earth It is bracketed at the earliest by the dates of the first Solar System material at 4 567 Ga or 4 567 billion years ago and the formation of the Earth at 4 54 Ga 4 54 billion years which is the beginning of the Hadean eon a division of geological time At the later end of the scale it is marked by the present day in the Holocene epoch Timescale of the Earth The following five timelines show the geologic time scale to scale The first shows the entire time from the formation of the Earth to the present but this gives little space for the most recent eon The second timeline shows an expanded view of the most recent eon In a similar way the most recent era is expanded in the third timeline the most recent period is expanded in the fourth timeline and the most recent epoch is expanded in the fifth timeline Horizontal scale is millions of years for the above timelines thousands of years for the timeline below Important milestones on Earth Geological time in a diagram called a geological clock showing the relative lengths of the eons and eras of the Earth s history4 567 Ga gigaannum billion years ago Solar system formation 4 54 Ga Accretion or formation of Earth c 4 Ga End of Late Heavy Bombardment the first life c 3 5 Ga Start of photosynthesis c 2 3 Ga Oxygenated atmosphere first snowball Earth 730 635 Ma megaannum million years ago second snowball Earth 541 0 3 Ma Cambrian explosion vast multiplication of hard bodied life first abundant fossils start of the Paleozoic c 380 Ma First vertebrate land animals 250 Ma Permian Triassic extinction 90 of all land animals die end of Paleozoic and beginning of Mesozoic 66 Ma Cretaceous Paleogene extinction Dinosaurs die end of Mesozoic and beginning of Cenozoic c 7 Ma First hominins appear 3 9 Ma First Australopithecus direct ancestor to modern Homo sapiens appear 200 ka kiloannum thousand years ago First modern Homo sapiens appear in East AfricaTimescale of the Moon Millions of years before present Timescale of Mars Martian time periods millions of years ago Epochs Dating methodsRelative dating Cross cutting relations can be used to determine the relative ages of rock strata and other geological structures Explanations A folded rock strata cut by a thrust fault B large intrusion cutting through A C erosional angular unconformity cutting off A amp B on which rock strata were deposited D volcanic dyke cutting through A B amp C E even younger rock strata overlying C amp D F normal fault cutting through A B C amp E Methods for relative dating were developed when geology first emerged as a natural science Geologists still use the following principles today as a means to provide information about geological history and the timing of geological events The principle of uniformitarianism states that the geological processes observed in operation that modify the Earth s crust at present have worked in much the same way over geological time A fundamental principle of geology advanced by the 18th century Scottish physician and geologist James Hutton is that the present is the key to the past In Hutton s words the past history of our globe must be explained by what can be seen to be happening now The principle of intrusive relationships concerns crosscutting intrusions In geology when an igneous intrusion cuts across a formation of sedimentary rock it can be determined that the igneous intrusion is younger than the sedimentary rock Different types of intrusions include stocks laccoliths batholiths sills and dikes The principle of cross cutting relationships pertains to the formation of faults and the age of the sequences through which they cut Faults are younger than the rocks they cut accordingly if a fault is found that penetrates some formations but not those on top of it then the formations that were cut are older than the fault and the ones that are not cut must be younger than the fault Finding the key bed in these situations may help determine whether the fault is a normal fault or a thrust fault The principle of inclusions and components states that with sedimentary rocks if inclusions or clasts are found in a formation then the inclusions must be older than the formation that contains them For example in sedimentary rocks it is common for gravel from an older formation to be ripped up and included in a newer layer A similar situation with igneous rocks occurs when xenoliths are found These foreign bodies are picked up as magma or lava flows and are incorporated later to cool in the matrix As a result xenoliths are older than the rock that contains them The Permian through Jurassic stratigraphy of the Colorado Plateau area of southeastern Utah is an example of both original horizontality and the law of superposition These strata make up much of the famous prominent rock formations in widely spaced protected areas such as Capitol Reef National Park and Canyonlands National Park From top to bottom Rounded tan domes of the Navajo Sandstone layered red Kayenta Formation cliff forming vertically jointed red Wingate Sandstone slope forming purplish Chinle Formation layered lighter red Moenkopi Formation and white layered Cutler Formation sandstone Picture from Glen Canyon National Recreation Area Utah The principle of original horizontality states that the deposition of sediments occurs as essentially horizontal beds Observation of modern marine and non marine sediments in a wide variety of environments supports this generalization although cross bedding is inclined the overall orientation of cross bedded units is horizontal The principle of superposition states that a sedimentary rock layer in a tectonically undisturbed sequence is younger than the one beneath it and older than the one above it Logically a younger layer cannot slip beneath a layer previously deposited This principle allows sedimentary layers to be viewed as a form of the vertical timeline a partial or complete record of the time elapsed from deposition of the lowest layer to deposition of the highest bed The principle of faunal succession is based on the appearance of fossils in sedimentary rocks As organisms exist during the same period throughout the world their presence or sometimes absence provides a relative age of the formations where they appear Based on principles that William Smith laid out almost a hundred years before the publication of Charles Darwin s theory of evolution the principles of succession developed independently of evolutionary thought The principle becomes quite complex however given the uncertainties of fossilization localization of fossil types due to lateral changes in habitat facies change in sedimentary strata and that not all fossils formed globally at the same time Absolute dating The mineral zircon is often used in radiometric dating Geologists also use methods to determine the absolute age of rock samples and geological events These dates are useful on their own and may also be used in conjunction with relative dating methods or to calibrate relative methods At the beginning of the 20th century advancement in geological science was facilitated by the ability to obtain accurate absolute dates to geological events using radioactive isotopes and other methods This changed the understanding of geological time Previously geologists could only use fossils and stratigraphic correlation to date sections of rock relative to one another With isotopic dates it became possible to assign absolute ages to rock units and these absolute dates could be applied to fossil sequences in which there was datable material converting the old relative ages into new absolute ages For many geological applications isotope ratios of radioactive elements are measured in minerals that give the amount of time that has passed since a rock passed through its particular closure temperature the point at which different radiometric isotopes stop diffusing into and out of the crystal lattice These are used in geochronologic and thermochronologic studies Common methods include uranium lead dating potassium argon dating argon argon dating and uranium thorium dating These methods are used for a variety of applications Dating of lava and volcanic ash layers found within a stratigraphic sequence can provide absolute age data for sedimentary rock units that do not contain radioactive isotopes and calibrate relative dating techniques These methods can also be used to determine ages of pluton emplacement Thermochemical techniques can be used to determine temperature profiles within the crust the uplift of mountain ranges and paleo topography Fractionation of the lanthanide series elements is used to compute ages since rocks were removed from the mantle Other methods are used for more recent events Optically stimulated luminescence and cosmogenic radionuclide dating are used to date surfaces and or erosion rates Dendrochronology can also be used for the dating of landscapes Radiocarbon dating is used for geologically young materials containing organic carbon Geological development of an areaAn originally horizontal sequence of sedimentary rocks in shades of tan are affected by igneous activity Deep below the surface is a magma chamber and large associated igneous bodies The magma chamber feeds the volcano and sends offshoots of magma that will later crystallize into dikes and sills Magma also advances upwards to form intrusive igneous bodies The diagram illustrates both a cinder cone volcano which releases ash and a composite volcano which releases both lava and ash An illustration of the three types of faults A Strike slip faults occur when rock units slide past one another B Normal faults occur when rocks are undergoing horizontal extension C Reverse or thrust faults occur when rocks are undergoing horizontal shortening The San Andreas Fault in California The geology of an area changes through time as rock units are deposited and inserted and deformational processes alter their shapes and locations Rock units are first emplaced either by deposition onto the surface or intrusion into the overlying rock Deposition can occur when sediments settle onto the surface of the Earth and later lithify into sedimentary rock or when as volcanic material such as volcanic ash or lava flows blanket the surface Igneous intrusions such as batholiths laccoliths dikes and sills push upwards into the overlying rock and crystallize as they intrude After the initial sequence of rocks has been deposited the rock units can be deformed and or metamorphosed Deformation typically occurs as a result of horizontal shortening horizontal extension or side to side strike slip motion These structural regimes broadly relate to convergent boundaries divergent boundaries and transform boundaries respectively between tectonic plates When rock units are placed under horizontal compression they shorten and become thicker Because rock units other than muds do not significantly change in volume this is accomplished in two primary ways through faulting and folding In the shallow crust where brittle deformation can occur thrust faults form which causes the deeper rock to move on top of the shallower rock Because deeper rock is often older as noted by the principle of superposition this can result in older rocks moving on top of younger ones Movement along faults can result in folding either because the faults are not planar or because rock layers are dragged along forming drag folds as slip occurs along the fault Deeper in the Earth rocks behave plastically and fold instead of faulting These folds can either be those where the material in the center of the fold buckles upwards creating antiforms or where it buckles downwards creating synforms If the tops of the rock units within the folds remain pointing upwards they are called anticlines and synclines respectively If some of the units in the fold are facing downward the structure is called an overturned anticline or syncline and if all of the rock units are overturned or the correct up direction is unknown they are simply called by the most general terms antiforms and synforms A diagram of folds indicating an anticline and a syncline Even higher pressures and temperatures during horizontal shortening can cause both folding and metamorphism of the rocks This metamorphism causes changes in the mineral composition of the rocks creates a foliation or planar surface that is related to mineral growth under stress This can remove signs of the original textures of the rocks such as bedding in sedimentary rocks flow features of lavas and crystal patterns in crystalline rocks Extension causes the rock units as a whole to become longer and thinner This is primarily accomplished through normal faulting and through the ductile stretching and thinning Normal faults drop rock units that are higher below those that are lower This typically results in younger units ending up below older units Stretching of units can result in their thinning In fact at one location within the Maria Fold and Thrust Belt the entire sedimentary sequence of the Grand Canyon appears over a length of less than a meter Rocks at the depth to be ductilely stretched are often also metamorphosed These stretched rocks can also pinch into lenses known as boudins after the French word for sausage because of their visual similarity Where rock units slide past one another strike slip faults develop in shallow regions and become shear zones at deeper depths where the rocks deform ductilely Geological cross section of Kittatinny Mountain This cross section shows metamorphic rocks overlain by younger sediments deposited after the metamorphic event These rock units were later folded and faulted during the uplift of the mountain The addition of new rock units both depositionally and intrusively often occurs during deformation Faulting and other deformational processes result in the creation of topographic gradients causing material on the rock unit that is increasing in elevation to be eroded by hillslopes and channels These sediments are deposited on the rock unit that is going down Continual motion along the fault maintains the topographic gradient in spite of the movement of sediment and continues to create accommodation space for the material to deposit Deformational events are often also associated with volcanism and igneous activity Volcanic ashes and lavas accumulate on the surface and igneous intrusions enter from below Dikes long planar igneous intrusions enter along cracks and therefore often form in large numbers in areas that are being actively deformed This can result in the emplacement of dike swarms such as those that are observable across the Canadian shield or rings of dikes around the lava tube of a volcano All of these processes do not necessarily occur in a single environment and do not necessarily occur in a single order The Hawaiian Islands for example consist almost entirely of layered basaltic lava flows The sedimentary sequences of the mid continental United States and the Grand Canyon in the southwestern United States contain almost undeformed stacks of sedimentary rocks that have remained in place since Cambrian time Other areas are much more geologically complex In the southwestern United States sedimentary volcanic and intrusive rocks have been metamorphosed faulted foliated and folded Even older rocks such as the Acasta gneiss of the Slave craton in northwestern Canada the oldest known rock in the world have been metamorphosed to the point where their origin is indiscernible without laboratory analysis In addition these processes can occur in stages In many places the Grand Canyon in the southwestern United States being a very visible example the lower rock units were metamorphosed and deformed and then deformation ended and the upper undeformed units were deposited Although any amount of rock emplacement and rock deformation can occur and they can occur any number of times these concepts provide a guide to understanding the geological history of an area Investigative methodsA standard Brunton Pocket Transit commonly used by geologists for mapping and surveying Geologists use a number of fields laboratory and numerical modeling methods to decipher Earth history and to understand the processes that occur on and inside the Earth In typical geological investigations geologists use primary information related to petrology the study of rocks stratigraphy the study of sedimentary layers and structural geology the study of positions of rock units and their deformation In many cases geologists also study modern soils rivers landscapes and glaciers investigate past and current life and biogeochemical pathways and use geophysical methods to investigate the subsurface Sub specialities of geology may distinguish endogenous and exogenous geology Field methods A typical USGS field mapping camp in the 1950sToday handheld computers with GPS and geographic information systems software are often used in geological field work digital geological mapping A petrified log in Petrified Forest National Park Arizona US Geological field work varies depending on the task at hand Typical fieldwork could consist of Geological mappingStructural mapping identifying the locations of major rock units and the faults and folds that led to their placement there Stratigraphic mapping pinpointing the locations of sedimentary facies lithofacies and biofacies or the mapping of isopachs of equal thickness of sedimentary rock Surficial mapping recording the locations of soils and surficial deposits Surveying of topographic features compilation of topographic maps Work to understand change across landscapes including Patterns of erosion and deposition River channel change through migration and avulsion Hillslope processes Subsurface mapping through geophysical methodsThese methods include Shallow seismic surveys Ground penetrating radar Aeromagnetic surveys Electrical resistivity tomography They aid in Hydrocarbon exploration Finding groundwater Locating buried archaeological artifacts High resolution stratigraphy Measuring and describing stratigraphic sections on the surface Well drilling and logging Biogeochemistry and geomicrobiologyCollecting samples to determine biochemical pathways identify new species of organisms identify new chemical compounds and to use these discoveries to understand early life on Earth and how it functioned and metabolized find important compounds for use in pharmaceuticals Paleontology excavation of fossil material For research into past life and evolution For museums and education Collection of samples for geochronology and thermochronology Glaciology measurement of characteristics of glaciers and their motionA petrographic microscopeA thin section in cross polarized lightIn optical mineralogy thin sections are used to study rocks The method is based on the distinct refractive indexes of different minerals Petrology In addition to identifying rocks in the field lithology petrologists identify rock samples in the laboratory Two of the primary methods for identifying rocks in the laboratory are through optical microscopy and by using an electron microprobe In an optical mineralogy analysis petrologists analyze thin sections of rock samples using a petrographic microscope where the minerals can be identified through their different properties in plane polarized and cross polarized light including their birefringence pleochroism twinning and interference properties with a conoscopic lens In the electron microprobe individual locations are analyzed for their exact chemical compositions and variation in composition within individual crystals Stable and radioactive isotope studies provide insight into the geochemical evolution of rock units Petrologists can also use fluid inclusion data and perform high temperature and pressure physical experiments to understand the temperatures and pressures at which different mineral phases appear and how they change through igneous and metamorphic processes This research can be extrapolated to the field to understand metamorphic processes and the conditions of crystallization of igneous rocks This work can also help to explain processes that occur within the Earth such as subduction and magma chamber evolution Folded rock strataStructural geology A diagram of an orogenic wedge The wedge grows through faulting in the interior and along the main basal fault called the decollement It builds its shape into a critical taper in which the angles within the wedge remain the same as failures inside the material balance failures along the decollement It is analogous to a bulldozer pushing a pile of dirt where the bulldozer is the overriding plate Structural geologists use microscopic analysis of oriented thin sections of geological samples to observe the fabric within the rocks which gives information about strain within the crystalline structure of the rocks They also plot and combine measurements of geological structures to better understand the orientations of faults and folds to reconstruct the history of rock deformation in the area In addition they perform analog and numerical experiments of rock deformation in large and small settings The analysis of structures is often accomplished by plotting the orientations of various features onto stereonets A stereonet is a stereographic projection of a sphere onto a plane in which planes are projected as lines and lines are projected as points These can be used to find the locations of fold axes relationships between faults and relationships between other geological structures Among the most well known experiments in structural geology are those involving orogenic wedges which are zones in which mountains are built along convergent tectonic plate boundaries In the analog versions of these experiments horizontal layers of sand are pulled along a lower surface into a back stop which results in realistic looking patterns of faulting and the growth of a critically tapered all angles remain the same orogenic wedge Numerical models work in the same way as these analog models though they are often more sophisticated and can include patterns of erosion and uplift in the mountain belt This helps to show the relationship between erosion and the shape of a mountain range These studies can also give useful information about pathways for metamorphism through pressure temperature space and time Stratigraphy Different colors caused by the different minerals in tilted layers of sedimentary rock in Zhangye National Geopark China In the laboratory stratigraphers analyze samples of stratigraphic sections that can be returned from the field such as those from drill cores Stratigraphers also analyze data from geophysical surveys that show the locations of stratigraphic units in the subsurface Geophysical data and well logs can be combined to produce a better view of the subsurface and stratigraphers often use computer programs to do this in three dimensions Stratigraphers can then use these data to reconstruct ancient processes occurring on the surface of the Earth interpret past environments and locate areas for water coal and hydrocarbon extraction In the laboratory biostratigraphers analyze rock samples from outcrop and drill cores for the fossils found in them These fossils help scientists to date the core and to understand the depositional environment in which the rock units formed Geochronologists precisely date rocks within the stratigraphic section to provide better absolute bounds on the timing and rates of deposition Magnetic stratigraphers look for signs of magnetic reversals in igneous rock units within the drill cores Other scientists perform stable isotope studies on the rocks to gain information about past climate Planetary geologySurface of Mars as photographed by the Viking 2 lander December 9 1977 With the advent of space exploration in the twentieth century geologists have begun to look at other planetary bodies in the same ways that have been developed to study the Earth This new field of study is called planetary geology sometimes known as astrogeology and relies on known geological principles to study other bodies of the solar system This is a major aspect of planetary science and largely focuses on the terrestrial planets icy moons asteroids comets and meteorites However some planetary geophysicists study the giant planets and exoplanets Although the Greek language origin prefix geo refers to Earth geology is often used in conjunction with the names of other planetary bodies when describing their composition and internal processes examples are the geology of Mars and Lunar geology Specialized terms such as selenology studies of the Moon areology of Mars etc are also in use Although planetary geologists are interested in studying all aspects of other planets a significant focus is to search for evidence of past or present life on other worlds This has led to many missions whose primary or ancillary purpose is to examine planetary bodies for evidence of life One of these is the Phoenix lander which analyzed Martian polar soil for water chemical and mineralogical constituents related to biological processes Applied geologyMan panning for gold on the Mokelumne Harper s Weekly How We Got Gold in California 1860Economic geology Economic geology is a branch of geology that deals with aspects of economic minerals that humankind uses to fulfill various needs Economic minerals are those extracted profitably for various practical uses Economic geologists help locate and manage the Earth s natural resources such as petroleum and coal as well as mineral resources which include metals such as iron copper and uranium Mining geology Mining geology consists of the extractions of mineral and ore resources from the Earth Some resources of economic interests include gemstones metals such as gold and copper and many minerals such as asbestos Magnesite perlite mica phosphates zeolites clay pumice quartz and silica as well as elements such as sulfur chlorine and helium Petroleum geology Mud log in process a common way to study the lithology when drilling oil wells Petroleum geologists study the locations of the subsurface of the Earth that can contain extractable hydrocarbons especially petroleum and natural gas Because many of these reservoirs are found in sedimentary basins they study the formation of these basins as well as their sedimentary and tectonic evolution and the present day positions of the rock units Engineering geology Engineering geology is the application of geological principles to engineering practice for the purpose of assuring that the geological factors affecting the location design construction operation and maintenance of engineering works are properly addressed Engineering geology is distinct from geological engineering particularly in North America A child drinks water from a well built as part of a hydrogeological humanitarian project in Kenya In the field of civil engineering geological principles and analyses are used in order to ascertain the mechanical principles of the material on which structures are built This allows tunnels to be built without collapsing bridges and skyscrapers to be built with sturdy foundations and buildings to be built that will not settle in clay and mud Hydrology Geology and geological principles can be applied to various environmental problems such as stream restoration the restoration of brownfields and the understanding of the interaction between natural habitat and the geological environment Groundwater hydrology or hydrogeology is used to locate groundwater which can often provide a ready supply of uncontaminated water and is especially important in arid regions and to monitor the spread of contaminants in groundwater wells Paleoclimatology Geologists also obtain data through stratigraphy boreholes core samples and ice cores Ice cores and sediment cores are used for paleoclimate reconstructions which tell geologists about past and present temperature precipitation and sea level across the globe These datasets are our primary source of information on global climate change outside of instrumental data Natural hazards Rockfall in the Grand Canyon Geologists and geophysicists study natural hazards in order to enact safe building codes and warning systems that are used to prevent loss of property and life Examples of important natural hazards that are pertinent to geology as opposed those that are mainly or only pertinent to meteorology are Avalanches Earthquakes Floods Landslides and debris flows River channel migration and avulsion Rockfalls Sinkholes Soil liquefaction Subsidence Tsunamis VolcanoesHistoryWilliam Smith s geological map of England Wales and southern Scotland Completed in 1815 it was the second national scale geologic map and by far the most accurate of its time failed verification The study of the physical material of the Earth dates back at least to ancient Greece when Theophrastus 372 287 BCE wrote the work Peri Lithon On Stones During the Roman period Pliny the Elder wrote in detail of the many minerals and metals then in practical use even correctly noting the origin of amber Additionally in the 4th century BCE Aristotle made critical observations of the slow rate of geological change He observed the composition of the land and formulated a theory where the Earth changes at a slow rate and that these changes cannot be observed during one person s lifetime Aristotle developed one of the first evidence based concepts connected to the geological realm regarding the rate at which the Earth physically changes Abu al Rayhan al Biruni 973 1048 CE was one of the earliest Persian geologists whose works included the earliest writings on the geology of India hypothesizing that the Indian subcontinent was once a sea Drawing from Greek and Indian scientific literature that were not destroyed by the Muslim conquests the Persian scholar Ibn Sina Avicenna 981 1037 proposed detailed explanations for the formation of mountains the origin of earthquakes and other topics central to modern geology which provided an essential foundation for the later development of the science In China the polymath Shen Kuo 1031 1095 formulated a hypothesis for the process of land formation based on his observation of fossil animal shells in a geological stratum in a mountain hundreds of miles from the ocean he inferred that the land was formed by the erosion of the mountains and by deposition of silt Georgius Agricola 1494 1555 published his groundbreaking work De Natura Fossilium in 1546 and is seen as the founder of geology as a scientific discipline Nicolas Steno 1638 1686 is credited with the law of superposition the principle of original horizontality and the principle of lateral continuity three defining principles of stratigraphy The word geology was first used by Ulisse Aldrovandi in 1603 then by Jean Andre Deluc in 1778 and introduced as a fixed term by Horace Benedict de Saussure in 1779 The word is derived from the Greek gῆ ge meaning earth and logos logos meaning speech But according to another source the word geology comes from a Norwegian Mikkel Pederson Escholt 1600 1669 who was a priest and scholar Escholt first used the definition in his book titled Geologia Norvegica 1657 William Smith 1769 1839 drew some of the first geological maps and began the process of ordering rock strata layers by examining the fossils contained in them In 1763 Mikhail Lomonosov published his treatise On the Strata of Earth His work was the first narrative of modern geology based on the unity of processes in time and explanation of the Earth s past from the present James Hutton 1726 1797 is often viewed as the first modern geologist In 1785 he presented a paper entitled Theory of the Earth to the Royal Society of Edinburgh In his paper he explained his theory that the Earth must be much older than had previously been supposed to allow enough time for mountains to be eroded and for sediments to form new rocks at the bottom of the sea which in turn were raised up to become dry land Hutton published a two volume version of his ideas in 1795 Followers of Hutton were known as Plutonists because they believed that some rocks were formed by vulcanism which is the deposition of lava from volcanoes as opposed to the Neptunists led by Abraham Werner who believed that all rocks had settled out of a large ocean whose level gradually dropped over time The first geological map of the U S was produced in 1809 by William Maclure In 1807 Maclure commenced the self imposed task of making a geological survey of the United States Almost every state in the Union was traversed and mapped by him the Allegheny Mountains being crossed and recrossed some 50 times The results of his unaided labours were submitted to the American Philosophical Society in a memoir entitled Observations on the Geology of the United States explanatory of a Geological Map and published in the Society s Transactions together with the nation s first geological map This antedates William Smith s geological map of England by six years although it was constructed using a different classification of rocks Sir Charles Lyell 1797 1875 first published his famous book Principles of Geology in 1830 This book which influenced the thought of Charles Darwin successfully promoted the doctrine of uniformitarianism This theory states that slow geological processes have occurred throughout the Earth s history and are still occurring today In contrast catastrophism is the theory that Earth s features formed in single catastrophic events and remained unchanged thereafter Though Hutton believed in uniformitarianism the idea was not widely accepted at the time Much of 19th century geology revolved around the question of the Earth s exact age Estimates varied from a few hundred thousand to billions of years By the early 20th century radiometric dating allowed the Earth s age to be estimated at two billion years The awareness of this vast amount of time opened the door to new theories about the processes that shaped the planet Some of the most significant advances in 20th century geology have been the development of the theory of plate tectonics in the 1960s and the refinement of estimates of the planet s age Plate tectonics theory arose from two separate geological observations seafloor spreading and continental drift The theory revolutionized the Earth sciences Today the Earth is known to be approximately 4 5 billion years old Georgius Agricola German mineralogist founder of geology as a scientific field Mikhail Lomonosov Russian polymath author of the first systematic treatise in scientific geology 1763 James Hutton Scottish geologist and father of modern geology John Tuzo Wilson Canadian geophysicist and father of plate tectonics The volcanologist David A Johnston 13 hours before his death at the 1980 eruption of Mount St HelensFields or related disciplinesEarth system science Economic geology Mining geology Petroleum geology Engineering geology Environmental geology Environmental science Geoarchaeology Geochemistry Biogeochemistry Isotope geochemistry Geochronology Geodetics Geography Physical geography Technical geography Geological engineering Geological modelling Geometallurgy Geomicrobiology Geomorphology Geomythology Geophysics Glaciology Historical geology Hydrogeology Meteorology Mineralogy Oceanography Marine geology Paleoclimatology Paleontology Micropaleontology Palynology Petrology Petrophysics Planetary geology Plate tectonics Regional geology Sedimentology Seismology Soil science Pedology soil study Speleology Stratigraphy Biostratigraphy Chronostratigraphy Lithostratigraphy Structural geology Systems geology Tectonics VolcanologySee alsoGeology portalEarth sciences portalGlossary of geology Geoprofessions Geotourism Tourism associated with geological attractions and destinations Index of geology articles Alphabetical listing of Wikipedia articles on Geology topics International Union of Geological Sciences IUGS International non governmental organization List of individual rocks Outline of geology Hierarchical outline list of articles related to geology Timeline of geology Chronological list of notable events in the history of the science of geologyReferencesHarper Douglas geology Online Etymology Dictionary gῆ Liddell Henry George Scott Robert A Greek English Lexicon at the Perseus Project What is geology The Geological Society Retrieved 31 May 2023 Gunten Hans R von 1995 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Hazards Gateway Archived 2010 09 23 at the Wayback Machine usgs gov Winchester Simon 2002 The map that changed the world William Smith and the birth of modern geology New York Perennial ISBN 978 0 06 093180 3 Moore Ruth The Earth We Live On New York Alfred A Knopf 1956 p 13 Aristotle Meteorology Book 1 Part 14 Asimov M S Bosworth Clifford Edmund eds 1992 The Age of Achievement A D 750 to the End of the Fifteenth Century The Achievements History of civilizations of Central Asia pp 211 214 ISBN 978 92 3 102719 2 Toulmin S and Goodfield J 1965 The Ancestry of science The Discovery of Time Hutchinson amp Company London England p 64 Al Rawi Munin M November 2002 The Contribution of Ibn Sina Avicenna to the development of Earth Sciences PDF Report Manchester UK Foundation for Science Technology and Civilisation Publication 4039 Archived PDF from the original on 2012 10 03 Retrieved 2008 07 22 Needham Joseph 1986 Science and Civilisation in China Vol 3 Taipei Caves Books Ltd pp 603 604 ISBN 978 0 521 31560 9 Georgius Agricola 1494 1555 From his will Testamento d Ullisse Aldrovandi of 1603 which is reproduced in Fantuzzi Giovanni Memorie della vita di Ulisse Aldrovandi medico e filosofo bolognese Bologna Italy Lelio dalla Volpe 1774 From p 81 Archived 2017 02 16 at the Wayback Machine amp anco la Giologia ovvero de Fossilibus and likewise geology or the study of things dug from the earth Vai Gian Battista Cavazza William 2003 Four centuries of the word geology Ulisse Aldrovandi 1603 in Bologna Minerva ISBN 978 88 7381 056 8 Archived from the original on 2016 04 20 Retrieved 2015 11 14 Deluc Jean Andre de Lettres physiques et morales sur les montagnes et sur l histoire de la terre et de l homme Physical and moral letters on mountains and on the history of the Earth and man vol 1 Paris France V Duchesne 1779 pp 4 5 and 7 From p 4 Archived 2018 11 22 at the Wayback Machine Entraine par les liaisons de cet objet avec la Geologie j entrepris dans un second voyage de les developper a SA MAJESTE Driven by the connections between this subject and geology I undertook a second voyage to develop them for Her Majesty viz Charlotte of Mecklenburg Strelitz Queen of Great Britain and Ireland From p 5 Archived 2018 11 22 at the Wayback Machine Je vis que je faisais un Traite et non une equisse deGeologie I see that I wrote a treatise and not a sketch of geology From the footnote on p 7 Archived 2018 11 22 at the Wayback Machine Je repete ici ce que j avois dit dans ma premierePreface sur la substitution de motCosmologiea celui deGeologie quoiqu il ne s agisse pas de l Univers mais seulement de laTerre I repeat here what I said in my first preface about the substitution of the word cosmology for that of geology although it is not a matter of the universe but only of the Earth Note A pirated edition of this book was published in 1778 Saussure Horace Benedict de Voyages dans les Alpes Neuchatel Switzerland Samuel Fauche 1779 From pp i ii Archived 2017 02 06 at the Wayback Machine La science qui rassemble les faits qui seuls peuvent servir de base a la Theorie de la Terre ou a laGeologie c est la Geographie physique ou la description de notre Globe The science that assembles the facts which alone can serve as the basis of the theory of the Earth or of geology is physical geography or the description of our globe On the controversy regarding whether Deluc or Saussure deserves priority in the use the term geology Zittel Karl Alfred von with Maria M Ogilvie Gordon trans History of Geology and Paleontology to the End of the Nineteenth Century London England Walter Scott 1901 p 76 Geikie Archibald The Founders of Geology 2nd ed London England Macmillan and Company 1905 p 186 Archived 2017 02 16 at the Wayback Machine Eastman Charles Rochester 12 August 1904 Letter to the Editor Variae Auctoritatis Archived 2017 02 07 at the Wayback Machine Science 2nd series 20 502 215 217 see p 216 Emmons Samuel Franklin 21 October 1904 Letter to the Editor Variae Auctoritatis Archived 2017 02 07 at the Wayback Machine Science 2nd series 20 512 537 Eastman C R 25 November 1904 Letter to the Editor Notes on the History of Scientific Nomenclature Archived 2017 02 07 at the Wayback Machine Science 2nd series 20 517 727 730 see p 728 Emmons S F 23 December 1904 Letter to the Editor The term geology Science 2nd series 20 521 886 887 Eastman C R 20 January 1905 Letter to the Editor Deluc s Geological Letters Archived 2017 02 16 at the Wayback Machine Science 2nd series 21 525 111 Emmons S F 17 February 1905 Letter to the Editor Deluc versus de Saussure Archived 2017 02 16 at the Wayback Machine Science 2nd series 21 529 274 275 Winchester Simon 2001 The Map that Changed the World HarperCollins Publishers p 25 ISBN 978 0 06 093180 3 Escholt Michel Pederson Geologia Norvegica det er En kort undervisning om det vitt begrebne jordskelff som her udi Norge skeedemesten ofuer alt Syndenfields den 24 aprilis udi naervaerende aar 1657 sampt physiske historiske oc theologiske fundament oc grundelige beretning om jordskellfs aarsager oc betydninger Archived 2017 02 16 at the Wayback Machine Norwegian geology that is a brief lesson about the widely perceived earthquake which happened here in Norway across all southern parts on the 24th of April in the present year 1657 together with physical historical and theological bases and a basic account of earthquakes causes and meanings Christiania now Oslo Norway Mickel Thomeson 1657 in Danish Reprinted in English as Escholt Michel Pederson with Daniel Collins trans Geologia Norvegica Archived 2017 02 16 at the Wayback Machine London England S Thomson 1663 Kermit H 2003 Niels Stensen 1638 1686 the scientist who was beatified Archived 2017 01 20 at the Wayback Machine Gracewing Publishing p 127 Lomonosov Mikhail 2012 On the Strata of the Earth Translation and commentary by S M Rowland and S Korolev The Geological Society of America Special Paper 485 ISBN 978 0 8137 2485 0 Archived from the original on 2021 06 24 Retrieved 2021 06 19 Vernadsky V 1911 Pamyati M V Lomonosova Zaprosy zhizni 5 257 262 in Russian In memory of M V Lomonosov James Hutton The Founder of Modern Geology Archived 2016 08 27 at the Wayback Machine American Museum of Natural History Gutenberg ebook links Vol 1 Theory of the Earth with Proofs and Illustrations Volume 1 Of 4 Archived from the original on 2020 09 14 Retrieved 2022 07 30 a href wiki Template Cite book title Template Cite book cite book a CS1 maint bot original URL status unknown link Vol 2 Theory of the Earth with Proofs and Illustrations Volume 2 Of 4 Archived from the original on 2020 08 09 Retrieved 2020 08 28 a href wiki Template Cite book title Template Cite book cite book a CS1 maint bot original URL status unknown link Maclure William 1817 Observations on the Geology of the United States of America With Some Remarks on the Effect Produced on the Nature and Fertility of Soils by the Decomposition of the Different Classes of Rocks and an Application to the Fertility of Every State in the Union in Reference to the Accompanying Geological Map Philadelphia Abraham Small Archived from the original on 2015 10 27 Retrieved 2015 11 14 Greene J C Burke J G 1978 The Science of Minerals in the Age of Jefferson Transactions of the American Philosophical Society New Series 68 4 1 113 39 doi 10 2307 1006294 JSTOR 1006294 Maclure s 1809 Geological Map Archived 2014 08 14 at the Wayback Machine davidrumsey com Lyell Charles 1991 Principles of geology Chicago University of Chicago Press ISBN 978 0 226 49797 6 England Philip Molnar Peter Richter Frank 2007 John Perry s neglected critique of Kelvin s age for the Earth A missed opportunity in geodynamics GSA Today 17 1 4 Bibcode 2007GSAT 17R 4E doi 10 1130 GSAT01701A 1 External linksWikimedia Commons has media related to Geology Wikisource has original works on the topic Geology At Wikiversity you can learn more and teach others about Geology at the School of Geology Wikibooks has a book on the topic of Historical Geology Wikiquote has quotations related to Geology One Geology This interactive geological map of the world is an international initiative of the geological surveys around the globe This groundbreaking project was launched in 2007 and contributed to the International Year of Planet Earth becoming one of their flagship projects Earth Science News Maps Dictionary Articles Jobs American Geophysical Union American Geosciences Institute European Geosciences Union European Federation of Geologists Geological Society of America Geological Society of London Video interviews with famous geologists Geology OpenTextbook Chronostratigraphy benchmarks The principles and objects of geology with special reference to the geology of Egypt 1911 W F Hume