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Meteorology

January 10, 2023

This article is about the study of weather. For the treatise by Aristotle, see Meteorology (Aristotle). For the science of measurement, see Metrology. For the study of meteors, see Meteoritics.

Meteorology is a branch of the atmospheric sciences (which include atmospheric chemistry and physics) with a major focus on weather forecasting. The study of meteorology dates back millennia, though significant progress in meteorology did not begin until the 18th century. The 19th century saw modest progress in the field after weather observation networks were formed across broad regions. Prior attempts at prediction of weather depended on historical data. It was not until after the elucidation of the laws of physics, and more particularly in the latter half of the 20th century the development of the computer (allowing for the automated solution of a great many modelling equations) that significant breakthroughs in weather forecasting were achieved. An important branch of weather forecasting is marine weather forecasting as it relates to maritime and coastal safety, in which weather effects also include atmospheric interactions with large bodies of water.

Meteorological phenomena are observable weather events that are explained by the science of meteorology. Meteorological phenomena are described and quantified by the variables of Earth's atmosphere: temperature, air pressure, water vapour, mass flow, and the variations and interactions of these variables, and how they change over time. Different spatial scales are used to describe and predict weather on local, regional, and global levels.

Meteorology, climatology, atmospheric physics, and atmospheric chemistry are sub-disciplines of the atmospheric sciences. Meteorology and hydrology compose the interdisciplinary field of hydrometeorology. The interactions between Earth's atmosphere and its oceans are part of a coupled ocean-atmosphere system. Meteorology has application in many diverse fields such as the military, energy production, transport, agriculture, and construction.

The word meteorology is from the Ancient Greek μετέωρος metéōros (meteor) and -λογία -logia (-(o)logy), meaning "the study of things high in the air."

History

Main article: Timeline of meteorology

Ancient meteorology up to the time of Aristotle

Early attempts at predicting weather were often related to prophecy and divining, and were sometimes based on astrological ideas. Ancient religions believed meteorological phenomena to be under the control of the gods.[1] The ability to predict rains and floods based on annual cycles was evidently used by humans at least from the time of agricultural settlement if not earlier. Early approaches to predicting weather were based on astrology and were practiced by priests. The Egyptians had rain-making rituals as early as 3500 BC.[1]

Ancient Indian Upanishads contain mentions of clouds and seasons.[2] The Samaveda mentions sacrifices to be performed when certain phenomena were noticed.[3] Varāhamihira's classical work Brihatsamhita, written about 500 AD,[2] provides evidence of weather observation.

Cuneiform inscriptions on Babylonian tablets included associations between thunder and rain. The Chaldeans differentiated the 22° and 46° halos.[3]

The ancient Greeks were the first to make theories about the weather. Many natural philosophers studied the weather. However, as meteorological instruments did not exist, the inquiry was largely qualitative, and could only be judged by more general theoretical speculations.[4] Herodotus states that Thales predicted the solar eclipse of 585 BC. He studied Babylonian equinox tables. [5] According to Seneca, he gave the explanation that the cause of the Nile's annual floods was due to northerly winds hindering its descent by the sea.[6] Anaximander and Anaximenes thought that thunder and lightning was caused by air smashing against the cloud, thus kindling the flame. Early meteorological theories generally considered that there was a fire-like substance in the atmosphere. Anaximander defined wind as a flowing of air, but this was not generally accepted for centuries. [7] A theory to explain summer hail was first proposed by Anaxagoras. He observed that air temperature decreased with increasing height and that clouds contain moisture. He also noted that heat caused objects to rise, and therefore the heat on a summer day would drive clouds to an altitude where the moisture would freeze.[8] Empledocles theorized on the change of the seasons. He believed that fire and water opposed each other in the atmosphere, and when fire gained the upper hand, the result was summer, and when water did, it was winter. Democritus also wrote about the flooding of the Nile. He said that during the summer solstice, snow in northern parts of the world melted. This would cause vapors to form clouds, which would cause storms when driven to the Nile by northerly winds, thus filling the lakes and the Nile.[9] Hippocrates inquired into the effect of weather on health. Eudoxus claimed that bad weather followed four-year periods, according to Pliny.[10]

These early observations would form the basis for Aristotle's Meteorology, written in 350 BC.[11][12] Aristotle is considered the founder of meteorology.[13] One of the most impressive achievements described in the Meteorology is the description of what is now known as the hydrologic cycle. His work would remain an authority on metereology for nearly 2,000 years.[14]

The book De Mundo (composed before 250 BC or between 350 and 200 BC) noted:[15]

If the flashing body is set on fire and rushes violently to the Earth it is called a thunderbolt; if it is only half of fire, but violent also and massive, it is called a meteor; if it is entirely free from fire, it is called a smoking bolt. They are all called 'swooping bolts' because they swoop down upon the Earth. Lightning is sometimes smoky, and is then called 'smoldering lightning"; sometimes it darts quickly along, and is then said to be vivid. At other times, it travels in crooked lines, and is called forked lightning. When it swoops down upon some object it is called 'swooping lightning'

Meteorology after Aristotle

After Aristotle, progress in meteorology stalled for a long time. Theophrastus compiled a book on weather forecasting, called the Book of Signs, as well as On Winds. He gave hundreds of signs for weather phenomena for a period up to a year.[16] His system was based on dividing the year by the setting and the rising of the Pleiad, halves into solstices and equinoxes, and the continuity of the weather for those periods. He also divided months into the new moon, fourth day, eighth day and full moon, in likelihood of a change in the weather occurring. The day was divided into sunrise, mid-morning, noon, mid-afternoon and sunset, with corresponding divisions of the night, with change being likely at one of these divisions.[17] Applying the divisions and a principle of balance in the yearly weather, he came up with forecasts like that if a lot of rain falls in the winter, the spring is usually dry. Rules based on actions of animals are also present in his work, like that if a dog rolls on the ground, it is a sign of a storm. Shooting stars and the Moon were also considered significant. However, he made no attempt to explain these phenomena, referring only to the Aristotelian method.[18] The work of Theophrastus remained a dominant influence in weather forecasting for nearly 2,000 years.[19]

Speculation on the cause of the flooding of the Nile ended when Erastothenes, according to Proclus, stated that it was known that man had gone to the sources of the Nile and observed the rains, although interest in its implications continued.[20]

During the era of Roman Greece and Europe, scientific interest in meteorology waned. In the 1st century BC, most natural philosophers claimed that the clouds and winds extended up to 111 miles, but Posidonius thought that they reached up to five miles, after which the air is clear, liquid and luminous. He closely followed Aristotle's theories. By the end of the second century BC, the center of science shifted from Athens to Alexandria, home to the ancient Library of Alexandria. In the 2nd century AD, Ptolemy's Almagest dealt with meteorology, because it was considered a subset of astronomy. He gave several astrological weather predictions.[21] He constructed a map of the world divided into climactic zones by their illumination, in which the length of the Summer solstice increased by half an hour per zone between the equator and the Arctic.[22] Ptolemy wrote on the atmospheric refraction of light in the context of astronomical observations.[23]

In 25 AD, Pomponius Mela, a Roman geographer, formalized the climatic zone system.[24] In 63-64 AD, Seneca wrote Naturales quaestiones. It was a compilation and synthesis of ancient Greek theories. However, theology was of foremost importance to Seneca, and he believed that phenomena such as lightning were tied to fate.[25] The second book(chapter) of Pliny's Natural History covers meteorology. He states that more than twenty ancient Greek authors studied meteorology. He didn't make any personal contributions, and the value of his work is in preserving earlier speculation, much like Seneca's work.[26]

 
Twilight at Baker Beach

From 400 to 1100, scientific learning in Europe was preserved by the clergy. Isidore of Seville devoted a considerable attention to meteorology in Etymologiae, De ordine creaturum and De natura rerum. Bede the Venerable was the first Englishman to write about the weather in De Natura Rerum in 703. The work was a summary of then extant classical sources. However, Aristotle's works were largely lost until the twelfth century, including Meteorologica. Isidore and Bede were scientifically minded, but they adhered to the letter of Scripture.[27]

Islamic civilization translated many ancient works into Arabic which were transmitted and translated in western Europe to Latin.[28]

In the 9th century, Al-Dinawari wrote the Kitab al-Nabat (Book of Plants), in which he deals with the application of meteorology to agriculture during the Arab Agricultural Revolution. He describes the meteorological character of the sky, the planets and constellations, the sun and moon, the lunar phases indicating seasons and rain, the anwa (heavenly bodies of rain), and atmospheric phenomena such as winds, thunder, lightning, snow, floods, valleys, rivers, lakes.[29][30]

In 1021, Alhazen showed that atmospheric refraction is also responsible for twilight in Opticae thesaurus; he estimated that twilight begins when the sun is 19 degrees below the horizon, and also used a geometric determination based on this to estimate the maximum possible height of the Earth's atmosphere as 52,000 passim (about 49 miles, or 79 km).[31]

Adelard of Bath was one of the early translators of the classics. He also discussed meteorological topics in his Quaestiones naturales. He thought dense air produced propulsion in the form of wind. He explained thunder by saying that it was due to ice colliding in clouds, and in Summer it melted. In the thirteenth century, Aristotelian theories reestablished dominance in meteorology. For the next four centuries, meteorological work by and large was mostly commentary. It has been estimated over 156 commentaries on the Meteorologica were written before 1650.[32]

Experimental evidence was less important than appeal to the classics and authority in medieval thought. In the thirteenth century, Roger Bacon advocated experimentation and the mathematical approach. In his Opus majus, he followed Aristotle's theory on the atmosphere being composed of water, air, and fire, supplemented by optics and geometric proofs. He noted that Ptolemy's climactic zones had to be adjusted for topography.[33]

St. Albert the Great was the first to propose that each drop of falling rain had the form of a small sphere, and that this form meant that the rainbow was produced by light interacting with each raindrop.[34] Roger Bacon was the first to calculate the angular size of the rainbow. He stated that a rainbow summit can not appear higher than 42 degrees above the horizon.[35]

In the late 13th century and early 14th century, Kamāl al-Dīn al-Fārisī and Theodoric of Freiberg were the first to give the correct explanations for the primary rainbow phenomenon. Theoderic went further and also explained the secondary rainbow.[36]

By the middle of the sixteenth century, meteorology had developed along two lines: theoretical science based on Meteorologica, and astrological weather forecasting. The pseudoscientific prediction by natural signs became popular and enjoyed protection of the church and princes. This was supported by scientists like Johannes Muller, Leonard Digges, and Johannes Kepler. However, there were skeptics. In the 14th century, Nicole Oresme believed that weather forecasting was possible, but that the rules for it were unknown at the time. Astrological influence in meteorology persisted until the eighteenth century.[37]

Gerolamo Cardano's De Subilitate (1550) was the first work to challenge fundamental aspects of Aristotelian theory. Cardano maintained that there were only three basic elements- earth, air, and water. He discounted fire because it needed material to spread and produced nothing. Cardano thought there were two kinds of air: free air and inclosed air. The former destroyed inanimate things and preserved animate things, while the latter had the opposite effect.[38]

The modern era and scientific meteorology

Rene Descartes's Discourse on the Method (1637) typifies the beginning of the scientific revolution in meteorology. His scientific method had four principles: to never accept anything unless one clearly knew it to be true; to divide every difficult problem into small problems to tackle; to proceed from the simple to the complex, always seeking relationships; to be as complete and thorough as possible with no prejudice.[39]

In the appendix Les Meteores, he applied these principles to meteorology. He discussed terrestrial bodies and vapors which arise from them, proceeding to explain the formation of clouds from drops of water, and winds, clouds then dissolving into rain, hail and snow. He also discussed the effects of light on the rainbow. Descartes hypothesized that all bodies were composed of small particles of different shapes and interwovenness. All of his theories was based on this hypothesis. He explained the rain as caused by clouds becoming too large for the air to hold, and that clouds became snow if the air was not warm enough to melt them, or hail if they met colder wind. Like his predecessors, Descartes's method was deductive, as meteorological instruments were not developed and extensively used yet. He introduced the Cartesian coordinate system to meteorology and stressed the importance of mathematics in natural science. His work established meteorology as a legitimate branch of physics.[40]

Instruments and classification scales

See also: Beaufort scale, Celsius, and Fahrenheit
 
A hemispherical cup anemometer

In 1441, King Sejong's son, Prince Munjong of Korea, invented the first standardized rain gauge.[41] These were sent throughout the Joseon dynasty of Korea as an official tool to assess land taxes based upon a farmer's potential harvest. In 1450, Leone Battista Alberti developed a swinging-plate anemometer, and was known as the first anemometer.[42] In 1607, Galileo Galilei constructed a thermoscope. In 1611, Johannes Kepler wrote the first scientific treatise on snow crystals: "Strena Seu de Nive Sexangula (A New Year's Gift of Hexagonal Snow)."[43] In 1643, Evangelista Torricelli invented the mercury barometer.[42] In 1662, Sir Christopher Wren invented the mechanical, self-emptying, tipping bucket rain gauge. In 1714, Gabriel Fahrenheit created a reliable scale for measuring temperature with a mercury-type thermometer.[44] In 1742, Anders Celsius, a Swedish astronomer, proposed the "centigrade" temperature scale, the predecessor of the current Celsius scale.[45] In 1783, the first hair hygrometer was demonstrated by Horace-Bénédict de Saussure. In 1802–1803, Luke Howard wrote On the Modification of Clouds, in which he assigns cloud types Latin names.[46] In 1806, Francis Beaufort introduced his system for classifying wind speeds.[47] Near the end of the 19th century the first cloud atlases were published, including the International Cloud Atlas, which has remained in print ever since. The April 1960 launch of the first successful weather satellite, TIROS-1, marked the beginning of the age where weather information became available globally.

Atmospheric composition research

In 1648, Blaise Pascal rediscovered that atmospheric pressure decreases with height, and deduced that there is a vacuum above the atmosphere.[48] In 1738, Daniel Bernoulli published Hydrodynamics, initiating the Kinetic theory of gases and established the basic laws for the theory of gases.[49] In 1761, Joseph Black discovered that ice absorbs heat without changing its temperature when melting. In 1772, Black's student Daniel Rutherford discovered nitrogen, which he called phlogisticated air, and together they developed the phlogiston theory.[50] In 1777, Antoine Lavoisier discovered oxygen and developed an explanation for combustion.[51] In 1783, in Lavoisier's essay "Reflexions sur le phlogistique,"[52] he deprecates the phlogiston theory and proposes a caloric theory.[53][54] In 1804, John Leslie observed that a matte black surface radiates heat more effectively than a polished surface, suggesting the importance of black-body radiation. In 1808, John Dalton defended caloric theory in A New System of Chemistry and described how it combines with matter, especially gases; he proposed that the heat capacity of gases varies inversely with atomic weight. In 1824, Sadi Carnot analyzed the efficiency of steam engines using caloric theory; he developed the notion of a reversible process and, in postulating that no such thing exists in nature, laid the foundation for the second law of thermodynamics. In 1716, Edmund Halley suggested that aurorae are caused by "magnetic effluvia" moving along the Earth's magnetic field lines.

Research into cyclones and air flow

 
General circulation of the Earth's atmosphere: The westerlies and trade winds are part of the Earth's atmospheric circulation.
Main articles: Coriolis effect and Prevailing winds

In 1494, Christopher Columbus experienced a tropical cyclone, which led to the first written European account of a hurricane.[55] In 1686, Edmund Halley presented a systematic study of the trade winds and monsoons and identified solar heating as the cause of atmospheric motions.[56] In 1735, an ideal explanation of global circulation through study of the trade winds was written by George Hadley.[57] In 1743, when Benjamin Franklin was prevented from seeing a lunar eclipse by a hurricane, he decided that cyclones move in a contrary manner to the winds at their periphery.[58] Understanding the kinematics of how exactly the rotation of the Earth affects airflow was partial at first. Gaspard-Gustave Coriolis published a paper in 1835 on the energy yield of machines with rotating parts, such as waterwheels.[59] In 1856, William Ferrel proposed the existence of a circulation cell in the mid-latitudes, and the air within deflected by the Coriolis force resulting in the prevailing westerly winds.[60] Late in the 19th century, the motion of air masses along isobars was understood to be the result of the large-scale interaction of the pressure gradient force and the deflecting force. By 1912, this deflecting force was named the Coriolis effect.[61] Just after World War I, a group of meteorologists in Norway led by Vilhelm Bjerknes developed the Norwegian cyclone model that explains the generation, intensification and ultimate decay (the life cycle) of mid-latitude cyclones, and introduced the idea of fronts, that is, sharply defined boundaries between air masses.[62] The group included Carl-Gustaf Rossby (who was the first to explain the large scale atmospheric flow in terms of fluid dynamics), Tor Bergeron (who first determined how rain forms) and Jacob Bjerknes.

Observation networks and weather forecasting

 
Cloud classification by altitude of occurrence
 
This "Hyetographic or Rain Map of the World " was first published 1848 by Alexander Keith Johnston.
 
This "Hyetographic or Rain Map of Europe" was also published in 1848 as part of "The Physical Atlas".
See also: History of surface weather analysis

In the late 16th century and first half of the 17th century a range of meteorological instruments were invented – the thermometer, barometer, hydrometer, as well as wind and rain gauges. In the 1650s natural philosophers started using these instruments to systematically record weather observations. Scientific academies established weather diaries and organised observational networks.[63] In 1654, Ferdinando II de Medici established the first weather observing network, that consisted of meteorological stations in Florence, Cutigliano, Vallombrosa, Bologna, Parma, Milan, Innsbruck, Osnabrück, Paris and Warsaw. The collected data were sent to Florence at regular time intervals.[64] In the 1660s Robert Hooke of the Royal Society of London sponsored networks of weather observers. Hippocrates' treatise Airs, Waters, and Places had linked weather to disease. Thus early meteorologists attempted to correlate weather patterns with epidemic outbreaks, and the climate with public health.[63]

During the Age of Enlightenment meteorology tried to rationalise traditional weather lore, including astrological meteorology. But there were also attempts to establish a theoretical understanding of weather phenomena. Edmond Halley and George Hadley tried to explain trade winds. They reasoned that the rising mass of heated equator air is replaced by an inflow of cooler air from high latitudes. A flow of warm air at high altitude from equator to poles in turn established an early picture of circulation. Frustration with the lack of discipline among weather observers, and the poor quality of the instruments, led the early modern nation states to organise large observation networks. Thus by the end of the 18th century, meteorologists had access to large quantities of reliable weather data.[63] In 1832, an electromagnetic telegraph was created by Baron Schilling.[65] The arrival of the electrical telegraph in 1837 afforded, for the first time, a practical method for quickly gathering surface weather observations from a wide area.[66]

This data could be used to produce maps of the state of the atmosphere for a region near the Earth's surface and to study how these states evolved through time. To make frequent weather forecasts based on these data required a reliable network of observations, but it was not until 1849 that the Smithsonian Institution began to establish an observation network across the United States under the leadership of Joseph Henry.[67] Similar observation networks were established in Europe at this time. The Reverend William Clement Ley was key in understanding of cirrus clouds and early understandings of Jet Streams.[68] Charles Kenneth Mackinnon Douglas, known as 'CKM' Douglas read Ley's papers after his death and carried on the early study of weather systems.[69] Nineteenth century researchers in meteorology were drawn from military or medical backgrounds, rather than trained as dedicated scientists.[70] In 1854, the United Kingdom government appointed Robert FitzRoy to the new office of Meteorological Statist to the Board of Trade with the task of gathering weather observations at sea. FitzRoy's office became the United Kingdom Meteorological Office in 1854, the second oldest national meteorological service in the world (the Central Institution for Meteorology and Geodynamics (ZAMG) in Austria was founded in 1851 and is the oldest weather service in the world). The first daily weather forecasts made by FitzRoy's Office were published in The Times newspaper in 1860. The following year a system was introduced of hoisting storm warning cones at principal ports when a gale was expected.

FitzRoy coined the term "weather forecast", and tried to separate scientific approaches from prophetic ones.[71]

Over the next 50 years, many countries established national meteorological services. The India Meteorological Department (1875) was established to follow tropical cyclone and monsoon.[72] The Finnish Meteorological Central Office (1881) was formed from part of Magnetic Observatory of Helsinki University.[73] Japan's Tokyo Meteorological Observatory, the forerunner of the Japan Meteorological Agency, began constructing surface weather maps in 1883.[74] The United States Weather Bureau (1890) was established under the United States Department of Agriculture. The Australian Bureau of Meteorology (1906) was established by a Meteorology Act to unify existing state meteorological services.[75][76]

Numerical weather prediction

Main article: Numerical weather prediction
 
A meteorologist at the console of the IBM 7090 in the Joint Numerical Weather Prediction Unit. c. 1965

In 1904, Norwegian scientist Vilhelm Bjerknes first argued in his paper Weather Forecasting as a Problem in Mechanics and Physics that it should be possible to forecast weather from calculations based upon natural laws.[77][78]

It was not until later in the 20th century that advances in the understanding of atmospheric physics led to the foundation of modern numerical weather prediction. In 1922, Lewis Fry Richardson published "Weather Prediction By Numerical Process,"[79] after finding notes and derivations he worked on as an ambulance driver in World War I. He described how small terms in the prognostic fluid dynamics equations that govern atmospheric flow could be neglected, and a numerical calculation scheme that could be devised to allow predictions. Richardson envisioned a large auditorium of thousands of people performing the calculations. However, the sheer number of calculations required was too large to complete without electronic computers, and the size of the grid and time steps used in the calculations led to unrealistic results. Though numerical analysis later found that this was due to numerical instability.

Starting in the 1950s, numerical forecasts with computers became feasible.[80] The first weather forecasts derived this way used barotropic (single-vertical-level) models, and could successfully predict the large-scale movement of midlatitude Rossby waves, that is, the pattern of atmospheric lows and highs.[81] In 1959, the UK Meteorological Office received its first computer, a Ferranti Mercury.[82]

In the 1960s, the chaotic nature of the atmosphere was first observed and mathematically described by Edward Lorenz, founding the field of chaos theory.[83] These advances have led to the current use of ensemble forecasting in most major forecasting centers, to take into account uncertainty arising from the chaotic nature of the atmosphere.[84] Mathematical models used to predict the long term weather of the Earth (climate models), have been developed that have a resolution today that are as coarse as the older weather prediction models. These climate models are used to investigate long-term climate shifts, such as what effects might be caused by human emission of greenhouse gases.

Meteorologists

Further information: Meteorologist

Meteorologists are scientists who study and work in the field of meteorology.[85] The American Meteorological Society publishes and continually updates an authoritative electronic Meteorology Glossary.[86] Meteorologists work in government agencies, private consulting and research services, industrial enterprises, utilities, radio and television stations, and in education. In the United States, meteorologists held about 10,000 jobs in 2018.[87]

Although weather forecasts and warnings are the best known products of meteorologists for the public, weather presenters on radio and television are not necessarily professional meteorologists. They are most often reporters with little formal meteorological training, using unregulated titles such as weather specialist or weatherman. The American Meteorological Society and National Weather Association issue "Seals of Approval" to weather broadcasters who meet certain requirements but this is not mandatory to be hired by the media.

Equipment

Main article: Meteorological instrumentation
 
Satellite image of Hurricane Hugo with a polar low visible at the top of the image

Each science has its own unique sets of laboratory equipment. In the atmosphere, there are many things or qualities of the atmosphere that can be measured. Rain, which can be observed, or seen anywhere and anytime was one of the first atmospheric qualities measured historically. Also, two other accurately measured qualities are wind and humidity. Neither of these can be seen but can be felt. The devices to measure these three sprang up in the mid-15th century and were respectively the rain gauge, the anemometer, and the hygrometer. Many attempts had been made prior to the 15th century to construct adequate equipment to measure the many atmospheric variables. Many were faulty in some way or were simply not reliable. Even Aristotle noted this in some of his work as the difficulty to measure the air.

Sets of surface measurements are important data to meteorologists. They give a snapshot of a variety of weather conditions at one single location and are usually at a weather station, a ship or a weather buoy. The measurements taken at a weather station can include any number of atmospheric observables. Usually, temperature, pressure, wind measurements, and humidity are the variables that are measured by a thermometer, barometer, anemometer, and hygrometer, respectively.[88] Professional stations may also include air quality sensors (carbon monoxide, carbon dioxide, methane, ozone, dust, and smoke), ceilometer (cloud ceiling), falling precipitation sensor, flood sensor, lightning sensor, microphone (explosions, sonic booms, thunder), pyranometer/pyrheliometer/spectroradiometer (IR/Vis/UV photodiodes), rain gauge/snow gauge, scintillation counter (background radiation, fallout, radon), seismometer (earthquakes and tremors), transmissometer (visibility), and a GPS clock for data logging. Upper air data are of crucial importance for weather forecasting. The most widely used technique is launches of radiosondes. Supplementing the radiosondes a network of aircraft collection is organized by the World Meteorological Organization.

Remote sensing, as used in meteorology, is the concept of collecting data from remote weather events and subsequently producing weather information. The common types of remote sensing are Radar, Lidar, and satellites (or photogrammetry). Each collects data about the atmosphere from a remote location and, usually, stores the data where the instrument is located. Radar and Lidar are not passive because both use EM radiation to illuminate a specific portion of the atmosphere.[89] Weather satellites along with more general-purpose Earth-observing satellites circling the earth at various altitudes have become an indispensable tool for studying a wide range of phenomena from forest fires to El Niño.

Spatial scales

The study of the atmosphere can be divided into distinct areas that depend on both time and spatial scales. At one extreme of this scale is climatology. In the timescales of hours to days, meteorology separates into micro-, meso-, and synoptic scale meteorology. Respectively, the geospatial size of each of these three scales relates directly with the appropriate timescale.

Other subclassifications are used to describe the unique, local, or broad effects within those subclasses.

Typical Scales of Atmospheric Motion Systems[90]
Type of motion Horizontal scale (meter)
Molecular mean free path 10−7
Minute turbulent eddies 10−2 – 10−1
Small eddies 10−1 – 1
Dust devils 1–10
Gusts 10 – 102
Tornadoes 102
Thunderclouds 103
Fronts, squall lines 104 – 105
Hurricanes 105
Synoptic Cyclones 106
Planetary waves 107
Atmospheric tides 107
Mean zonal wind 107

Microscale

Main article: Microscale meteorology

Microscale meteorology is the study of atmospheric phenomena on a scale of about 1 kilometre (0.62 mi) or less. Individual thunderstorms, clouds, and local turbulence caused by buildings and other obstacles (such as individual hills) are modeled on this scale.[91]

Mesoscale

Main article: Mesoscale meteorology

Mesoscale meteorology is the study of atmospheric phenomena that has horizontal scales ranging from 1 km to 1000 km and a vertical scale that starts at the Earth's surface and includes the atmospheric boundary layer, troposphere, tropopause, and the lower section of the stratosphere. Mesoscale timescales last from less than a day to multiple weeks. The events typically of interest are thunderstorms, squall lines, fronts, precipitation bands in tropical and extratropical cyclones, and topographically generated weather systems such as mountain waves and sea and land breezes.[92]

Synoptic scale

Main article: Synoptic scale meteorology
 
NOAA: Synoptic scale weather analysis.

Synoptic scale meteorology predicts atmospheric changes at scales up to 1000 km and 105 sec (28 days), in time and space. At the synoptic scale, the Coriolis acceleration acting on moving air masses (outside of the tropics) plays a dominant role in predictions. The phenomena typically described by synoptic meteorology include events such as extratropical cyclones, baroclinic troughs and ridges, frontal zones, and to some extent jet streams. All of these are typically given on weather maps for a specific time. The minimum horizontal scale of synoptic phenomena is limited to the spacing between surface observation stations.[93]

Global scale

 
Annual mean sea surface temperatures.

Global scale meteorology is the study of weather patterns related to the transport of heat from the tropics to the poles. Very large scale oscillations are of importance at this scale. These oscillations have time periods typically on the order of months, such as the Madden–Julian oscillation, or years, such as the El Niño–Southern Oscillation and the Pacific decadal oscillation. Global scale meteorology pushes into the range of climatology. The traditional definition of climate is pushed into larger timescales and with the understanding of the longer time scale global oscillations, their effect on climate and weather disturbances can be included in the synoptic and mesoscale timescales predictions.

Numerical Weather Prediction is a main focus in understanding air–sea interaction, tropical meteorology, atmospheric predictability, and tropospheric/stratospheric processes.[94] The Naval Research Laboratory in Monterey, California, developed a global atmospheric model called Navy Operational Global Atmospheric Prediction System (NOGAPS). NOGAPS is run operationally at Fleet Numerical Meteorology and Oceanography Center for the United States Military. Many other global atmospheric models are run by national meteorological agencies.

Some meteorological principles

Boundary layer meteorology

Boundary layer meteorology is the study of processes in the air layer directly above Earth's surface, known as the atmospheric boundary layer (ABL). The effects of the surface – heating, cooling, and friction – cause turbulent mixing within the air layer. Significant movement of heat, matter, or momentum on time scales of less than a day are caused by turbulent motions.[95] Boundary layer meteorology includes the study of all types of surface–atmosphere boundary, including ocean, lake, urban land and non-urban land for the study of meteorology.

Dynamic meteorology

Dynamic meteorology generally focuses on the fluid dynamics of the atmosphere. The idea of air parcel is used to define the smallest element of the atmosphere, while ignoring the discrete molecular and chemical nature of the atmosphere. An air parcel is defined as a point in the fluid continuum of the atmosphere. The fundamental laws of fluid dynamics, thermodynamics, and motion are used to study the atmosphere. The physical quantities that characterize the state of the atmosphere are temperature, density, pressure, etc. These variables have unique values in the continuum.[96]

Applications

Weather forecasting

Main article: Weather forecasting
 
Forecast of surface pressures five days into the future for the north Pacific, North America, and north Atlantic Ocean

Weather forecasting is the application of science and technology to predict the state of the atmosphere at a future time and given location. Humans have attempted to predict the weather informally for millennia and formally since at least the 19th century.[97][98] Weather forecasts are made by collecting quantitative data about the current state of the atmosphere and using scientific understanding of atmospheric processes to project how the atmosphere will evolve.[99]

Once an all-human endeavor based mainly upon changes in barometric pressure, current weather conditions, and sky condition,[100][101] forecast models are now used to determine future conditions. Human input is still required to pick the best possible forecast model to base the forecast upon, which involves pattern recognition skills, teleconnections, knowledge of model performance, and knowledge of model biases. The chaotic nature of the atmosphere, the massive computational power required to solve the equations that describe the atmosphere, error involved in measuring the initial conditions, and an incomplete understanding of atmospheric processes mean that forecasts become less accurate as the difference in current time and the time for which the forecast is being made (the range of the forecast) increases. The use of ensembles and model consensus help narrow the error and pick the most likely outcome.[102][103][104]

There are a variety of end uses to weather forecasts. Weather warnings are important forecasts because they are used to protect life and property.[105] Forecasts based on temperature and precipitation are important to agriculture,[106][107][108][109] and therefore to commodity traders within stock markets. Temperature forecasts are used by utility companies to estimate demand over coming days.[110][111][112] On an everyday basis, people use weather forecasts to determine what to wear. Since outdoor activities are severely curtailed by heavy rain, snow, and wind chill, forecasts can be used to plan activities around these events, and to plan ahead and survive them.

Aviation meteorology

Aviation meteorology deals with the impact of weather on air traffic management. It is important for air crews to understand the implications of weather on their flight plan as well as their aircraft, as noted by the Aeronautical Information Manual:[113]

The effects of ice on aircraft are cumulative—thrust is reduced, drag increases, lift lessens, and weight increases. The results are an increase in stall speed and a deterioration of aircraft performance. In extreme cases, 2 to 3 inches of ice can form on the leading edge of the airfoil in less than 5 minutes. It takes but 1/2 inch of ice to reduce the lifting power of some aircraft by 50 percent and increases the frictional drag by an equal percentage.[114]

Agricultural meteorology

Meteorologists, soil scientists, agricultural hydrologists, and agronomists are people concerned with studying the effects of weather and climate on plant distribution, crop yield, water-use efficiency, phenology of plant and animal development, and the energy balance of managed and natural ecosystems. Conversely, they are interested in the role of vegetation on climate and weather.[115]

Hydrometeorology

Hydrometeorology is the branch of meteorology that deals with the hydrologic cycle, the water budget, and the rainfall statistics of storms.[116] A hydrometeorologist prepares and issues forecasts of accumulating (quantitative) precipitation, heavy rain, heavy snow, and highlights areas with the potential for flash flooding. Typically the range of knowledge that is required overlaps with climatology, mesoscale and synoptic meteorology, and other geosciences.[117]

The multidisciplinary nature of the branch can result in technical challenges, since tools and solutions from each of the individual disciplines involved may behave slightly differently, be optimized for different hard- and software platforms and use different data formats. There are some initiatives – such as the DRIHM project[118] – that are trying to address this issue.[119]

Nuclear meteorology

Nuclear meteorology investigates the distribution of radioactive aerosols and gases in the atmosphere.[120]

Maritime meteorology

Maritime meteorology deals with air and wave forecasts for ships operating at sea. Organizations such as the Ocean Prediction Center, Honolulu National Weather Service forecast office, United Kingdom Met Office, KNMI and JMA prepare high seas forecasts for the world's oceans.

Military meteorology

Main article: Military meteorology

Military meteorology is the research and application of meteorology for military purposes. In the United States, the United States Navy's Commander, Naval Meteorology and Oceanography Command oversees meteorological efforts for the Navy and Marine Corps while the United States Air Force's Air Force Weather Agency is responsible for the Air Force and Army.

Environmental meteorology

Environmental meteorology mainly analyzes industrial pollution dispersion physically and chemically based on meteorological parameters such as temperature, humidity, wind, and various weather conditions.

Renewable energy

Meteorology applications in renewable energy includes basic research, "exploration," and potential mapping of wind power and solar radiation for wind and solar energy.

See also

Main articles: Outline of meteorology and Glossary of meteorology

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Further reading

  • Byers, Horace. General Meteorology. New York: McGraw-Hill, 1994.
  • Garret, J.R. (1992) [1992]. The atmospheric boundary layer. Cambridge University Press. ISBN 978-0-521-38052-2.
  • Glossary of Meteorology. American Meteorological Society (2nd ed.). Allen Press. 2000.{{cite book}}: CS1 maint: others (link)
  • Bluestein, H (1992) [1992]. Synoptic-Dynamic Meteorology in Midlatitudes: Principles of Kinematics and Dynamics, Vol. 1. Oxford University Press. ISBN 978-0-19-506267-0.
  • Bluestein, H (1993) [1993]. Synoptic-Dynamic Meteorology in Midlatitudes: Volume II: Observations and Theory of Weather Systems. Oxford University Press. ISBN 978-0-19-506268-7.
  • Reynolds, R (2005) [2005]. Guide to Weather. Buffalo, New York: Firefly Books Inc. p. 208. ISBN 978-1-55407-110-4.
  • Holton, J.R. (2004) [2004]. (4th ed.). Burlington, Md: Elsevier Inc. ISBN 978-0-12-354015-7. Archived from the original on 19 July 2013. Retrieved 21 May 2017.
  • Roulstone, Ian & Norbury, John (2013). Invisible in the Storm: the role of mathematics in understanding weather. Princeton University Press. ISBN 978-0691152721.

Dictionaries and encyclopedias

  • Glickman, Todd S. (June 2000). Meteorology Glossary (electronic) (2nd ed.). Cambridge, Massachusetts: American Meteorological Society.
  • Gustavo Herrera, Roberto; García-Herrera, Ricardo; Prieto, Luis; Gallego, David; Hernández, Emiliano; Gimeno, Luis; Können, Gunther; Koek, Frits; Wheeler, Dennis; Wilkinson, Clive; Del Rosario Prieto, Maria; Báez, Carlos; Woodruff, Scott. A Dictionary of Nautical Meteorological Terms: CLIWOC Multilingual Dictionary of Meteorological Terms; An English/Spanish/French/Dutch Dictionary of Windforce Terms Used by Mariners from 1750 to 1850 (PDF). CLIWOC.
  • . Central Weather Bureau. 6 December 2018. Archived from the original on 21 September 2014. Retrieved 14 September 2014.

History

  • Lawrence-Mathers, Anne (2020). Medieval Meteorology: Forecasting the Weather from Aristotle to the Almanac. Cambridge: Cambridge University Press. doi:10.1017/9781108289948. ISBN 978-1-108-40600-0. S2CID 211658964.

External links

 
Wikimedia Commons has media related to Meteorology.
 
Wikisource has original works on the topic: Meteorology
 
Wikiversity has learning resources about Meteorology

Please see weather forecasting for weather forecast sites.

  • Air Quality Meteorology – Online course that introduces the basic concepts of meteorology and air quality necessary to understand meteorological computer models. Written at a bachelor's degree level.
  • The GLOBE Program – (Global Learning and Observations to Benefit the Environment) An international environmental science and education program that links students, teachers, and the scientific research community in an effort to learn more about the environment through student data collection and observation.
  • Glossary of Meteorology – From the American Meteorological Society, an excellent reference of nomenclature, equations, and concepts for the more advanced reader.
  • JetStream – An Online School for Weather – National Weather Service
  • Learn About Meteorology – Australian Bureau of Meteorology
  • The Weather Guide – Weather Tutorials and News at About.com
  • Meteorology Education and Training (MetEd) – The COMET Program
  • – National Oceanic & Atmospheric Administration
  • The World Weather 2010 Project 19 August 2008 at the Wayback Machine The University of Illinois at Urbana–Champaign
  • Ogimet – online data from meteorological stations of the world, obtained through NOAA free services
  • Weather forecasting and Climate science – United Kingdom Meteorological Office
  • Meteorology, BBC Radio 4 discussion with Vladimir Janković, Richard Hambyn and Iba Taub (In Our Time, 6 March 2003)
  • Virtual exhibition about meteorology on the digital library of Paris Observatory

January 10, 2023
meteorology, this, article, about, study, weather, treatise, aristotle, aristotle, science, measurement, metrology, study, meteors, meteoritics, branch, atmospheric, sciences, which, include, atmospheric, chemistry, physics, with, major, focus, weather, foreca. This article is about the study of weather For the treatise by Aristotle see Meteorology Aristotle For the science of measurement see Metrology For the study of meteors see Meteoritics Meteorology is a branch of the atmospheric sciences which include atmospheric chemistry and physics with a major focus on weather forecasting The study of meteorology dates back millennia though significant progress in meteorology did not begin until the 18th century The 19th century saw modest progress in the field after weather observation networks were formed across broad regions Prior attempts at prediction of weather depended on historical data It was not until after the elucidation of the laws of physics and more particularly in the latter half of the 20th century the development of the computer allowing for the automated solution of a great many modelling equations that significant breakthroughs in weather forecasting were achieved An important branch of weather forecasting is marine weather forecasting as it relates to maritime and coastal safety in which weather effects also include atmospheric interactions with large bodies of water Meteorological phenomena are observable weather events that are explained by the science of meteorology Meteorological phenomena are described and quantified by the variables of Earth s atmosphere temperature air pressure water vapour mass flow and the variations and interactions of these variables and how they change over time Different spatial scales are used to describe and predict weather on local regional and global levels Meteorology climatology atmospheric physics and atmospheric chemistry are sub disciplines of the atmospheric sciences Meteorology and hydrology compose the interdisciplinary field of hydrometeorology The interactions between Earth s atmosphere and its oceans are part of a coupled ocean atmosphere system Meteorology has application in many diverse fields such as the military energy production transport agriculture and construction The word meteorology is from the Ancient Greek metewros meteōros meteor and logia logia o logy meaning the study of things high in the air Contents 1 History 1 1 Ancient meteorology up to the time of Aristotle 1 2 Meteorology after Aristotle 1 3 The modern era and scientific meteorology 1 4 Instruments and classification scales 1 5 Atmospheric composition research 1 6 Research into cyclones and air flow 1 7 Observation networks and weather forecasting 1 8 Numerical weather prediction 2 Meteorologists 3 Equipment 4 Spatial scales 4 1 Microscale 4 2 Mesoscale 4 3 Synoptic scale 4 4 Global scale 5 Some meteorological principles 5 1 Boundary layer meteorology 5 2 Dynamic meteorology 6 Applications 6 1 Weather forecasting 6 2 Aviation meteorology 6 3 Agricultural meteorology 6 4 Hydrometeorology 6 5 Nuclear meteorology 6 6 Maritime meteorology 6 7 Military meteorology 6 8 Environmental meteorology 6 9 Renewable energy 7 See also 8 References 9 Further reading 9 1 Dictionaries and encyclopedias 9 2 History 10 External linksHistory EditMain article Timeline of meteorology Ancient meteorology up to the time of Aristotle Edit Parhelion sundog in Savoie Early attempts at predicting weather were often related to prophecy and divining and were sometimes based on astrological ideas Ancient religions believed meteorological phenomena to be under the control of the gods 1 The ability to predict rains and floods based on annual cycles was evidently used by humans at least from the time of agricultural settlement if not earlier Early approaches to predicting weather were based on astrology and were practiced by priests The Egyptians had rain making rituals as early as 3500 BC 1 Ancient Indian Upanishads contain mentions of clouds and seasons 2 The Samaveda mentions sacrifices to be performed when certain phenomena were noticed 3 Varahamihira s classical work Brihatsamhita written about 500 AD 2 provides evidence of weather observation Cuneiform inscriptions on Babylonian tablets included associations between thunder and rain The Chaldeans differentiated the 22 and 46 halos 3 The ancient Greeks were the first to make theories about the weather Many natural philosophers studied the weather However as meteorological instruments did not exist the inquiry was largely qualitative and could only be judged by more general theoretical speculations 4 Herodotus states that Thales predicted the solar eclipse of 585 BC He studied Babylonian equinox tables 5 According to Seneca he gave the explanation that the cause of the Nile s annual floods was due to northerly winds hindering its descent by the sea 6 Anaximander and Anaximenes thought that thunder and lightning was caused by air smashing against the cloud thus kindling the flame Early meteorological theories generally considered that there was a fire like substance in the atmosphere Anaximander defined wind as a flowing of air but this was not generally accepted for centuries 7 A theory to explain summer hail was first proposed by Anaxagoras He observed that air temperature decreased with increasing height and that clouds contain moisture He also noted that heat caused objects to rise and therefore the heat on a summer day would drive clouds to an altitude where the moisture would freeze 8 Empledocles theorized on the change of the seasons He believed that fire and water opposed each other in the atmosphere and when fire gained the upper hand the result was summer and when water did it was winter Democritus also wrote about the flooding of the Nile He said that during the summer solstice snow in northern parts of the world melted This would cause vapors to form clouds which would cause storms when driven to the Nile by northerly winds thus filling the lakes and the Nile 9 Hippocrates inquired into the effect of weather on health Eudoxus claimed that bad weather followed four year periods according to Pliny 10 These early observations would form the basis for Aristotle s Meteorology written in 350 BC 11 12 Aristotle is considered the founder of meteorology 13 One of the most impressive achievements described in the Meteorology is the description of what is now known as the hydrologic cycle His work would remain an authority on metereology for nearly 2 000 years 14 The book De Mundo composed before 250 BC or between 350 and 200 BC noted 15 If the flashing body is set on fire and rushes violently to the Earth it is called a thunderbolt if it is only half of fire but violent also and massive it is called a meteor if it is entirely free from fire it is called a smoking bolt They are all called swooping bolts because they swoop down upon the Earth Lightning is sometimes smoky and is then called smoldering lightning sometimes it darts quickly along and is then said to be vivid At other times it travels in crooked lines and is called forked lightning When it swoops down upon some object it is called swooping lightning Meteorology after Aristotle Edit This section needs expansion with Extend History from AD 25 to current redact following Medieval subsection into this subsection You can help by adding to it October 2022 After Aristotle progress in meteorology stalled for a long time Theophrastus compiled a book on weather forecasting called the Book of Signs as well as On Winds He gave hundreds of signs for weather phenomena for a period up to a year 16 His system was based on dividing the year by the setting and the rising of the Pleiad halves into solstices and equinoxes and the continuity of the weather for those periods He also divided months into the new moon fourth day eighth day and full moon in likelihood of a change in the weather occurring The day was divided into sunrise mid morning noon mid afternoon and sunset with corresponding divisions of the night with change being likely at one of these divisions 17 Applying the divisions and a principle of balance in the yearly weather he came up with forecasts like that if a lot of rain falls in the winter the spring is usually dry Rules based on actions of animals are also present in his work like that if a dog rolls on the ground it is a sign of a storm Shooting stars and the Moon were also considered significant However he made no attempt to explain these phenomena referring only to the Aristotelian method 18 The work of Theophrastus remained a dominant influence in weather forecasting for nearly 2 000 years 19 Speculation on the cause of the flooding of the Nile ended when Erastothenes according to Proclus stated that it was known that man had gone to the sources of the Nile and observed the rains although interest in its implications continued 20 During the era of Roman Greece and Europe scientific interest in meteorology waned In the 1st century BC most natural philosophers claimed that the clouds and winds extended up to 111 miles but Posidonius thought that they reached up to five miles after which the air is clear liquid and luminous He closely followed Aristotle s theories By the end of the second century BC the center of science shifted from Athens to Alexandria home to the ancient Library of Alexandria In the 2nd century AD Ptolemy s Almagest dealt with meteorology because it was considered a subset of astronomy He gave several astrological weather predictions 21 He constructed a map of the world divided into climactic zones by their illumination in which the length of the Summer solstice increased by half an hour per zone between the equator and the Arctic 22 Ptolemy wrote on the atmospheric refraction of light in the context of astronomical observations 23 In 25 AD Pomponius Mela a Roman geographer formalized the climatic zone system 24 In 63 64 AD Seneca wrote Naturales quaestiones It was a compilation and synthesis of ancient Greek theories However theology was of foremost importance to Seneca and he believed that phenomena such as lightning were tied to fate 25 The second book chapter of Pliny s Natural History covers meteorology He states that more than twenty ancient Greek authors studied meteorology He didn t make any personal contributions and the value of his work is in preserving earlier speculation much like Seneca s work 26 Twilight at Baker Beach From 400 to 1100 scientific learning in Europe was preserved by the clergy Isidore of Seville devoted a considerable attention to meteorology in Etymologiae De ordine creaturum and De natura rerum Bede the Venerable was the first Englishman to write about the weather in De Natura Rerum in 703 The work was a summary of then extant classical sources However Aristotle s works were largely lost until the twelfth century including Meteorologica Isidore and Bede were scientifically minded but they adhered to the letter of Scripture 27 Islamic civilization translated many ancient works into Arabic which were transmitted and translated in western Europe to Latin 28 In the 9th century Al Dinawari wrote the Kitab al Nabat Book of Plants in which he deals with the application of meteorology to agriculture during the Arab Agricultural Revolution He describes the meteorological character of the sky the planets and constellations the sun and moon the lunar phases indicating seasons and rain the anwa heavenly bodies of rain and atmospheric phenomena such as winds thunder lightning snow floods valleys rivers lakes 29 30 In 1021 Alhazen showed that atmospheric refraction is also responsible for twilight in Opticae thesaurus he estimated that twilight begins when the sun is 19 degrees below the horizon and also used a geometric determination based on this to estimate the maximum possible height of the Earth s atmosphere as 52 000 passim about 49 miles or 79 km 31 Adelard of Bath was one of the early translators of the classics He also discussed meteorological topics in his Quaestiones naturales He thought dense air produced propulsion in the form of wind He explained thunder by saying that it was due to ice colliding in clouds and in Summer it melted In the thirteenth century Aristotelian theories reestablished dominance in meteorology For the next four centuries meteorological work by and large was mostly commentary It has been estimated over 156 commentaries on the Meteorologica were written before 1650 32 Experimental evidence was less important than appeal to the classics and authority in medieval thought In the thirteenth century Roger Bacon advocated experimentation and the mathematical approach In his Opus majus he followed Aristotle s theory on the atmosphere being composed of water air and fire supplemented by optics and geometric proofs He noted that Ptolemy s climactic zones had to be adjusted for topography 33 St Albert the Great was the first to propose that each drop of falling rain had the form of a small sphere and that this form meant that the rainbow was produced by light interacting with each raindrop 34 Roger Bacon was the first to calculate the angular size of the rainbow He stated that a rainbow summit can not appear higher than 42 degrees above the horizon 35 In the late 13th century and early 14th century Kamal al Din al Farisi and Theodoric of Freiberg were the first to give the correct explanations for the primary rainbow phenomenon Theoderic went further and also explained the secondary rainbow 36 By the middle of the sixteenth century meteorology had developed along two lines theoretical science based on Meteorologica and astrological weather forecasting The pseudoscientific prediction by natural signs became popular and enjoyed protection of the church and princes This was supported by scientists like Johannes Muller Leonard Digges and Johannes Kepler However there were skeptics In the 14th century Nicole Oresme believed that weather forecasting was possible but that the rules for it were unknown at the time Astrological influence in meteorology persisted until the eighteenth century 37 Gerolamo Cardano s De Subilitate 1550 was the first work to challenge fundamental aspects of Aristotelian theory Cardano maintained that there were only three basic elements earth air and water He discounted fire because it needed material to spread and produced nothing Cardano thought there were two kinds of air free air and inclosed air The former destroyed inanimate things and preserved animate things while the latter had the opposite effect 38 The modern era and scientific meteorology Edit This section needs expansion with Brief summary of developments post Medieval the following subsections could be redacted into this subsection and details moved to subordinate articles You can help by adding to it October 2022 Rene Descartes s Discourse on the Method 1637 typifies the beginning of the scientific revolution in meteorology His scientific method had four principles to never accept anything unless one clearly knew it to be true to divide every difficult problem into small problems to tackle to proceed from the simple to the complex always seeking relationships to be as complete and thorough as possible with no prejudice 39 In the appendix Les Meteores he applied these principles to meteorology He discussed terrestrial bodies and vapors which arise from them proceeding to explain the formation of clouds from drops of water and winds clouds then dissolving into rain hail and snow He also discussed the effects of light on the rainbow Descartes hypothesized that all bodies were composed of small particles of different shapes and interwovenness All of his theories was based on this hypothesis He explained the rain as caused by clouds becoming too large for the air to hold and that clouds became snow if the air was not warm enough to melt them or hail if they met colder wind Like his predecessors Descartes s method was deductive as meteorological instruments were not developed and extensively used yet He introduced the Cartesian coordinate system to meteorology and stressed the importance of mathematics in natural science His work established meteorology as a legitimate branch of physics 40 Instruments and classification scales Edit See also Beaufort scale Celsius and Fahrenheit A hemispherical cup anemometer In 1441 King Sejong s son Prince Munjong of Korea invented the first standardized rain gauge 41 These were sent throughout the Joseon dynasty of Korea as an official tool to assess land taxes based upon a farmer s potential harvest In 1450 Leone Battista Alberti developed a swinging plate anemometer and was known as the first anemometer 42 In 1607 Galileo Galilei constructed a thermoscope In 1611 Johannes Kepler wrote the first scientific treatise on snow crystals Strena Seu de Nive Sexangula A New Year s Gift of Hexagonal Snow 43 In 1643 Evangelista Torricelli invented the mercury barometer 42 In 1662 Sir Christopher Wren invented the mechanical self emptying tipping bucket rain gauge In 1714 Gabriel Fahrenheit created a reliable scale for measuring temperature with a mercury type thermometer 44 In 1742 Anders Celsius a Swedish astronomer proposed the centigrade temperature scale the predecessor of the current Celsius scale 45 In 1783 the first hair hygrometer was demonstrated by Horace Benedict de Saussure In 1802 1803 Luke Howard wrote On the Modification of Clouds in which he assigns cloud types Latin names 46 In 1806 Francis Beaufort introduced his system for classifying wind speeds 47 Near the end of the 19th century the first cloud atlases were published including the International Cloud Atlas which has remained in print ever since The April 1960 launch of the first successful weather satellite TIROS 1 marked the beginning of the age where weather information became available globally Atmospheric composition research Edit In 1648 Blaise Pascal rediscovered that atmospheric pressure decreases with height and deduced that there is a vacuum above the atmosphere 48 In 1738 Daniel Bernoulli published Hydrodynamics initiating the Kinetic theory of gases and established the basic laws for the theory of gases 49 In 1761 Joseph Black discovered that ice absorbs heat without changing its temperature when melting In 1772 Black s student Daniel Rutherford discovered nitrogen which he called phlogisticated air and together they developed the phlogiston theory 50 In 1777 Antoine Lavoisier discovered oxygen and developed an explanation for combustion 51 In 1783 in Lavoisier s essay Reflexions sur le phlogistique 52 he deprecates the phlogiston theory and proposes a caloric theory 53 54 In 1804 John Leslie observed that a matte black surface radiates heat more effectively than a polished surface suggesting the importance of black body radiation In 1808 John Dalton defended caloric theory in A New System of Chemistry and described how it combines with matter especially gases he proposed that the heat capacity of gases varies inversely with atomic weight In 1824 Sadi Carnot analyzed the efficiency of steam engines using caloric theory he developed the notion of a reversible process and in postulating that no such thing exists in nature laid the foundation for the second law of thermodynamics In 1716 Edmund Halley suggested that aurorae are caused by magnetic effluvia moving along the Earth s magnetic field lines Research into cyclones and air flow Edit General circulation of the Earth s atmosphere The westerlies and trade winds are part of the Earth s atmospheric circulation Main articles Coriolis effect and Prevailing winds In 1494 Christopher Columbus experienced a tropical cyclone which led to the first written European account of a hurricane 55 In 1686 Edmund Halley presented a systematic study of the trade winds and monsoons and identified solar heating as the cause of atmospheric motions 56 In 1735 an ideal explanation of global circulation through study of the trade winds was written by George Hadley 57 In 1743 when Benjamin Franklin was prevented from seeing a lunar eclipse by a hurricane he decided that cyclones move in a contrary manner to the winds at their periphery 58 Understanding the kinematics of how exactly the rotation of the Earth affects airflow was partial at first Gaspard Gustave Coriolis published a paper in 1835 on the energy yield of machines with rotating parts such as waterwheels 59 In 1856 William Ferrel proposed the existence of a circulation cell in the mid latitudes and the air within deflected by the Coriolis force resulting in the prevailing westerly winds 60 Late in the 19th century the motion of air masses along isobars was understood to be the result of the large scale interaction of the pressure gradient force and the deflecting force By 1912 this deflecting force was named the Coriolis effect 61 Just after World War I a group of meteorologists in Norway led by Vilhelm Bjerknes developed the Norwegian cyclone model that explains the generation intensification and ultimate decay the life cycle of mid latitude cyclones and introduced the idea of fronts that is sharply defined boundaries between air masses 62 The group included Carl Gustaf Rossby who was the first to explain the large scale atmospheric flow in terms of fluid dynamics Tor Bergeron who first determined how rain forms and Jacob Bjerknes Observation networks and weather forecasting Edit Cloud classification by altitude of occurrence This Hyetographic or Rain Map of the World was first published 1848 by Alexander Keith Johnston This Hyetographic or Rain Map of Europe was also published in 1848 as part of The Physical Atlas See also History of surface weather analysis In the late 16th century and first half of the 17th century a range of meteorological instruments were invented the thermometer barometer hydrometer as well as wind and rain gauges In the 1650s natural philosophers started using these instruments to systematically record weather observations Scientific academies established weather diaries and organised observational networks 63 In 1654 Ferdinando II de Medici established the first weather observing network that consisted of meteorological stations in Florence Cutigliano Vallombrosa Bologna Parma Milan Innsbruck Osnabruck Paris and Warsaw The collected data were sent to Florence at regular time intervals 64 In the 1660s Robert Hooke of the Royal Society of London sponsored networks of weather observers Hippocrates treatise Airs Waters and Places had linked weather to disease Thus early meteorologists attempted to correlate weather patterns with epidemic outbreaks and the climate with public health 63 During the Age of Enlightenment meteorology tried to rationalise traditional weather lore including astrological meteorology But there were also attempts to establish a theoretical understanding of weather phenomena Edmond Halley and George Hadley tried to explain trade winds They reasoned that the rising mass of heated equator air is replaced by an inflow of cooler air from high latitudes A flow of warm air at high altitude from equator to poles in turn established an early picture of circulation Frustration with the lack of discipline among weather observers and the poor quality of the instruments led the early modern nation states to organise large observation networks Thus by the end of the 18th century meteorologists had access to large quantities of reliable weather data 63 In 1832 an electromagnetic telegraph was created by Baron Schilling 65 The arrival of the electrical telegraph in 1837 afforded for the first time a practical method for quickly gathering surface weather observations from a wide area 66 This data could be used to produce maps of the state of the atmosphere for a region near the Earth s surface and to study how these states evolved through time To make frequent weather forecasts based on these data required a reliable network of observations but it was not until 1849 that the Smithsonian Institution began to establish an observation network across the United States under the leadership of Joseph Henry 67 Similar observation networks were established in Europe at this time The Reverend William Clement Ley was key in understanding of cirrus clouds and early understandings of Jet Streams 68 Charles Kenneth Mackinnon Douglas known as CKM Douglas read Ley s papers after his death and carried on the early study of weather systems 69 Nineteenth century researchers in meteorology were drawn from military or medical backgrounds rather than trained as dedicated scientists 70 In 1854 the United Kingdom government appointed Robert FitzRoy to the new office of Meteorological Statist to the Board of Trade with the task of gathering weather observations at sea FitzRoy s office became the United Kingdom Meteorological Office in 1854 the second oldest national meteorological service in the world the Central Institution for Meteorology and Geodynamics ZAMG in Austria was founded in 1851 and is the oldest weather service in the world The first daily weather forecasts made by FitzRoy s Office were published in The Times newspaper in 1860 The following year a system was introduced of hoisting storm warning cones at principal ports when a gale was expected FitzRoy coined the term weather forecast and tried to separate scientific approaches from prophetic ones 71 Over the next 50 years many countries established national meteorological services The India Meteorological Department 1875 was established to follow tropical cyclone and monsoon 72 The Finnish Meteorological Central Office 1881 was formed from part of Magnetic Observatory of Helsinki University 73 Japan s Tokyo Meteorological Observatory the forerunner of the Japan Meteorological Agency began constructing surface weather maps in 1883 74 The United States Weather Bureau 1890 was established under the United States Department of Agriculture The Australian Bureau of Meteorology 1906 was established by a Meteorology Act to unify existing state meteorological services 75 76 Numerical weather prediction Edit Main article Numerical weather prediction A meteorologist at the console of the IBM 7090 in the Joint Numerical Weather Prediction Unit c 1965 In 1904 Norwegian scientist Vilhelm Bjerknes first argued in his paper Weather Forecasting as a Problem in Mechanics and Physics that it should be possible to forecast weather from calculations based upon natural laws 77 78 It was not until later in the 20th century that advances in the understanding of atmospheric physics led to the foundation of modern numerical weather prediction In 1922 Lewis Fry Richardson published Weather Prediction By Numerical Process 79 after finding notes and derivations he worked on as an ambulance driver in World War I He described how small terms in the prognostic fluid dynamics equations that govern atmospheric flow could be neglected and a numerical calculation scheme that could be devised to allow predictions Richardson envisioned a large auditorium of thousands of people performing the calculations However the sheer number of calculations required was too large to complete without electronic computers and the size of the grid and time steps used in the calculations led to unrealistic results Though numerical analysis later found that this was due to numerical instability Starting in the 1950s numerical forecasts with computers became feasible 80 The first weather forecasts derived this way used barotropic single vertical level models and could successfully predict the large scale movement of midlatitude Rossby waves that is the pattern of atmospheric lows and highs 81 In 1959 the UK Meteorological Office received its first computer a Ferranti Mercury 82 In the 1960s the chaotic nature of the atmosphere was first observed and mathematically described by Edward Lorenz founding the field of chaos theory 83 These advances have led to the current use of ensemble forecasting in most major forecasting centers to take into account uncertainty arising from the chaotic nature of the atmosphere 84 Mathematical models used to predict the long term weather of the Earth climate models have been developed that have a resolution today that are as coarse as the older weather prediction models These climate models are used to investigate long term climate shifts such as what effects might be caused by human emission of greenhouse gases Meteorologists EditFurther information Meteorologist Meteorologists are scientists who study and work in the field of meteorology 85 The American Meteorological Society publishes and continually updates an authoritative electronic Meteorology Glossary 86 Meteorologists work in government agencies private consulting and research services industrial enterprises utilities radio and television stations and in education In the United States meteorologists held about 10 000 jobs in 2018 87 Although weather forecasts and warnings are the best known products of meteorologists for the public weather presenters on radio and television are not necessarily professional meteorologists They are most often reporters with little formal meteorological training using unregulated titles such as weather specialist or weatherman The American Meteorological Society and National Weather Association issue Seals of Approval to weather broadcasters who meet certain requirements but this is not mandatory to be hired by the media Equipment EditMain article Meteorological instrumentation Satellite image of Hurricane Hugo with a polar low visible at the top of the image Each science has its own unique sets of laboratory equipment In the atmosphere there are many things or qualities of the atmosphere that can be measured Rain which can be observed or seen anywhere and anytime was one of the first atmospheric qualities measured historically Also two other accurately measured qualities are wind and humidity Neither of these can be seen but can be felt The devices to measure these three sprang up in the mid 15th century and were respectively the rain gauge the anemometer and the hygrometer Many attempts had been made prior to the 15th century to construct adequate equipment to measure the many atmospheric variables Many were faulty in some way or were simply not reliable Even Aristotle noted this in some of his work as the difficulty to measure the air Sets of surface measurements are important data to meteorologists They give a snapshot of a variety of weather conditions at one single location and are usually at a weather station a ship or a weather buoy The measurements taken at a weather station can include any number of atmospheric observables Usually temperature pressure wind measurements and humidity are the variables that are measured by a thermometer barometer anemometer and hygrometer respectively 88 Professional stations may also include air quality sensors carbon monoxide carbon dioxide methane ozone dust and smoke ceilometer cloud ceiling falling precipitation sensor flood sensor lightning sensor microphone explosions sonic booms thunder pyranometer pyrheliometer spectroradiometer IR Vis UV photodiodes rain gauge snow gauge scintillation counter background radiation fallout radon seismometer earthquakes and tremors transmissometer visibility and a GPS clock for data logging Upper air data are of crucial importance for weather forecasting The most widely used technique is launches of radiosondes Supplementing the radiosondes a network of aircraft collection is organized by the World Meteorological Organization Remote sensing as used in meteorology is the concept of collecting data from remote weather events and subsequently producing weather information The common types of remote sensing are Radar Lidar and satellites or photogrammetry Each collects data about the atmosphere from a remote location and usually stores the data where the instrument is located Radar and Lidar are not passive because both use EM radiation to illuminate a specific portion of the atmosphere 89 Weather satellites along with more general purpose Earth observing satellites circling the earth at various altitudes have become an indispensable tool for studying a wide range of phenomena from forest fires to El Nino Spatial scales EditThe study of the atmosphere can be divided into distinct areas that depend on both time and spatial scales At one extreme of this scale is climatology In the timescales of hours to days meteorology separates into micro meso and synoptic scale meteorology Respectively the geospatial size of each of these three scales relates directly with the appropriate timescale Other subclassifications are used to describe the unique local or broad effects within those subclasses Typical Scales of Atmospheric Motion Systems 90 Type of motion Horizontal scale meter Molecular mean free path 10 7Minute turbulent eddies 10 2 10 1Small eddies 10 1 1Dust devils 1 10Gusts 10 102Tornadoes 102Thunderclouds 103Fronts squall lines 104 105Hurricanes 105Synoptic Cyclones 106Planetary waves 107Atmospheric tides 107Mean zonal wind 107Microscale Edit Main article Microscale meteorology Microscale meteorology is the study of atmospheric phenomena on a scale of about 1 kilometre 0 62 mi or less Individual thunderstorms clouds and local turbulence caused by buildings and other obstacles such as individual hills are modeled on this scale 91 Mesoscale Edit Main article Mesoscale meteorology Mesoscale meteorology is the study of atmospheric phenomena that has horizontal scales ranging from 1 km to 1000 km and a vertical scale that starts at the Earth s surface and includes the atmospheric boundary layer troposphere tropopause and the lower section of the stratosphere Mesoscale timescales last from less than a day to multiple weeks The events typically of interest are thunderstorms squall lines fronts precipitation bands in tropical and extratropical cyclones and topographically generated weather systems such as mountain waves and sea and land breezes 92 Synoptic scale Edit Main article Synoptic scale meteorology NOAA Synoptic scale weather analysis Synoptic scale meteorology predicts atmospheric changes at scales up to 1000 km and 105 sec 28 days in time and space At the synoptic scale the Coriolis acceleration acting on moving air masses outside of the tropics plays a dominant role in predictions The phenomena typically described by synoptic meteorology include events such as extratropical cyclones baroclinic troughs and ridges frontal zones and to some extent jet streams All of these are typically given on weather maps for a specific time The minimum horizontal scale of synoptic phenomena is limited to the spacing between surface observation stations 93 Global scale Edit Annual mean sea surface temperatures Global scale meteorology is the study of weather patterns related to the transport of heat from the tropics to the poles Very large scale oscillations are of importance at this scale These oscillations have time periods typically on the order of months such as the Madden Julian oscillation or years such as the El Nino Southern Oscillation and the Pacific decadal oscillation Global scale meteorology pushes into the range of climatology The traditional definition of climate is pushed into larger timescales and with the understanding of the longer time scale global oscillations their effect on climate and weather disturbances can be included in the synoptic and mesoscale timescales predictions Numerical Weather Prediction is a main focus in understanding air sea interaction tropical meteorology atmospheric predictability and tropospheric stratospheric processes 94 The Naval Research Laboratory in Monterey California developed a global atmospheric model called Navy Operational Global Atmospheric Prediction System NOGAPS NOGAPS is run operationally at Fleet Numerical Meteorology and Oceanography Center for the United States Military Many other global atmospheric models are run by national meteorological agencies Some meteorological principles EditBoundary layer meteorology Edit Boundary layer meteorology is the study of processes in the air layer directly above Earth s surface known as the atmospheric boundary layer ABL The effects of the surface heating cooling and friction cause turbulent mixing within the air layer Significant movement of heat matter or momentum on time scales of less than a day are caused by turbulent motions 95 Boundary layer meteorology includes the study of all types of surface atmosphere boundary including ocean lake urban land and non urban land for the study of meteorology Dynamic meteorology Edit Dynamic meteorology generally focuses on the fluid dynamics of the atmosphere The idea of air parcel is used to define the smallest element of the atmosphere while ignoring the discrete molecular and chemical nature of the atmosphere An air parcel is defined as a point in the fluid continuum of the atmosphere The fundamental laws of fluid dynamics thermodynamics and motion are used to study the atmosphere The physical quantities that characterize the state of the atmosphere are temperature density pressure etc These variables have unique values in the continuum 96 Applications EditWeather forecasting Edit Main article Weather forecasting Forecast of surface pressures five days into the future for the north Pacific North America and north Atlantic Ocean Weather forecasting is the application of science and technology to predict the state of the atmosphere at a future time and given location Humans have attempted to predict the weather informally for millennia and formally since at least the 19th century 97 98 Weather forecasts are made by collecting quantitative data about the current state of the atmosphere and using scientific understanding of atmospheric processes to project how the atmosphere will evolve 99 Once an all human endeavor based mainly upon changes in barometric pressure current weather conditions and sky condition 100 101 forecast models are now used to determine future conditions Human input is still required to pick the best possible forecast model to base the forecast upon which involves pattern recognition skills teleconnections knowledge of model performance and knowledge of model biases The chaotic nature of the atmosphere the massive computational power required to solve the equations that describe the atmosphere error involved in measuring the initial conditions and an incomplete understanding of atmospheric processes mean that forecasts become less accurate as the difference in current time and the time for which the forecast is being made the range of the forecast increases The use of ensembles and model consensus help narrow the error and pick the most likely outcome 102 103 104 There are a variety of end uses to weather forecasts Weather warnings are important forecasts because they are used to protect life and property 105 Forecasts based on temperature and precipitation are important to agriculture 106 107 108 109 and therefore to commodity traders within stock markets Temperature forecasts are used by utility companies to estimate demand over coming days 110 111 112 On an everyday basis people use weather forecasts to determine what to wear Since outdoor activities are severely curtailed by heavy rain snow and wind chill forecasts can be used to plan activities around these events and to plan ahead and survive them Aviation meteorology Edit Aviation meteorology deals with the impact of weather on air traffic management It is important for air crews to understand the implications of weather on their flight plan as well as their aircraft as noted by the Aeronautical Information Manual 113 The effects of ice on aircraft are cumulative thrust is reduced drag increases lift lessens and weight increases The results are an increase in stall speed and a deterioration of aircraft performance In extreme cases 2 to 3 inches of ice can form on the leading edge of the airfoil in less than 5 minutes It takes but 1 2 inch of ice to reduce the lifting power of some aircraft by 50 percent and increases the frictional drag by an equal percentage 114 Agricultural meteorology Edit Meteorologists soil scientists agricultural hydrologists and agronomists are people concerned with studying the effects of weather and climate on plant distribution crop yield water use efficiency phenology of plant and animal development and the energy balance of managed and natural ecosystems Conversely they are interested in the role of vegetation on climate and weather 115 Hydrometeorology Edit Hydrometeorology is the branch of meteorology that deals with the hydrologic cycle the water budget and the rainfall statistics of storms 116 A hydrometeorologist prepares and issues forecasts of accumulating quantitative precipitation heavy rain heavy snow and highlights areas with the potential for flash flooding Typically the range of knowledge that is required overlaps with climatology mesoscale and synoptic meteorology and other geosciences 117 The multidisciplinary nature of the branch can result in technical challenges since tools and solutions from each of the individual disciplines involved may behave slightly differently be optimized for different hard and software platforms and use different data formats There are some initiatives such as the DRIHM project 118 that are trying to address this issue 119 Nuclear meteorology Edit Nuclear meteorology investigates the distribution of radioactive aerosols and gases in the atmosphere 120 Maritime meteorology Edit Maritime meteorology deals with air and wave forecasts for ships operating at sea Organizations such as the Ocean Prediction Center Honolulu National Weather Service forecast office United Kingdom Met Office KNMI and JMA prepare high seas forecasts for the world s oceans Military meteorology Edit Main article Military meteorology Military meteorology is the research and application of meteorology for military purposes In the United States the United States Navy s Commander Naval Meteorology and Oceanography Command oversees meteorological efforts for the Navy and Marine Corps while the United States Air Force s Air Force Weather Agency is responsible for the Air Force and Army Environmental meteorology Edit Environmental meteorology mainly analyzes industrial pollution dispersion physically and chemically based on meteorological parameters such as temperature humidity wind and various weather conditions Renewable energy Edit Meteorology applications in renewable energy includes basic research exploration and potential mapping of wind power and solar radiation for wind and solar energy See also EditMain articles Outline of meteorology and Glossary of meteorology Aerography American Practical Navigator Atmospheric circulation Atmospheric layers Atmospheric models Atmospheric pressure Atmospheric thermodynamics Automated airport weather station Cloud Eddy covariance flux eddy correlation eddy flux El Nino Southern Oscillation Index of meteorology articles Indigenous Australian seasons List of cloud types List of meteorology institutions List of Russian meteorologists List of weather instruments Madden Julian oscillation Meteorological winter National Weatherperson s Day Precipitation ROFOR Space weather Walker circulation Weather stationReferences Edit a b Frisinge H Howard 1983 The History of Meteorology to 1800 American Meteorological Society p 1 ISBN 978 1 940033 91 4 a b NS nsimd ymail com History of Meteorology in India Imd gov in Archived from the original on 30 March 2012 Retrieved 25 March 2012 a b Hellmann G 1 October 1908 The dawn of meteorology Quarterly Journal of the Royal Meteorological Society 34 148 221 232 Bibcode 1908QJRMS 34 221H doi 10 1002 qj 49703414802 ISSN 1477 870X Frisinge H Howard 1983 The History of Meteorology to 1800 American Meteorological Society p 8 ISBN 978 1 940033 91 4 Frisinge H Howard 1983 The History of Meteorology to 1800 American Meteorological Society p 11 ISBN 978 1 940033 91 4 Frisinge H Howard 1983 The History of Meteorology to 1800 American Meteorological Society p 4 ISBN 978 1 940033 91 4 Frisinge H Howard 1983 The History of Meteorology to 1800 American Meteorological Society p 5 ISBN 978 1 940033 91 4 Frisinge H Howard 1983 The History of Meteorology to 1800 American Meteorological Society p 6 ISBN 978 1 940033 91 4 Frisinge H Howard 1983 The History of Meteorology to 1800 American Meteorological Society p 8 ISBN 978 1 940033 91 4 Frisinge H Howard 1983 The History of Meteorology to 1800 American Meteorological Society pp 9 10 ISBN 978 1 940033 91 4 Frisinge H Howard 1983 The History of Meteorology to 1800 American Meteorological Society p 11 ISBN 978 1 940033 91 4 Meteorology Introduction Infoplease 94 05 01 Meteorology Archived from the original on 21 July 2016 Retrieved 16 June 2015 Aristotle 2004 350 BCE Meteorology The University of Adelaide Library University of Adelaide South Australia 5005 eBooks Adelaide Archived from the original on 17 February 2007 Translated by E W Webster a href Template Cite book html title Template Cite book cite book a CS1 maint location link Aristotle Forster E S Edward Seymour 1879 1950 Dobson J F John Frederic 1875 1947 1914 De Mundo Oxford The Clarendon Press p Chapter 4 a href Template Cite book html title Template Cite book cite book a CS1 maint multiple names authors list link Frisinge H Howard 1983 The History of Meteorology to 1800 American Meteorological Society p 25 ISBN 978 1 940033 91 4 Frisinge H Howard 1983 The History of Meteorology to 1800 American Meteorological Society pp 25 26 ISBN 978 1 940033 91 4 Frisinge H Howard 1983 The History of Meteorology to 1800 American Meteorological Society p 26 ISBN 978 1 940033 91 4 Weather Forecasting from the Beginning Infoplease Frisinge H Howard 1983 The History of Meteorology to 1800 American Meteorological Society p 26 ISBN 978 1 940033 91 4 Frisinge H Howard 1983 The History of Meteorology to 1800 American Meteorological Society p 27 ISBN 978 1 940033 91 4 Frisinge H Howard 1983 The History of Meteorology 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on 22 July 2009 Thornes John E 1999 John Constable s Skies The University of Birmingham Press pp 189 ISBN 1 902459 02 4 Giles Bill Beaufort Scale BBC Weather Archived from the original on 15 October 2010 Retrieved 12 May 2009 Florin to Pascal September 1647 Œuves completes de Pascal 2 682 O Connor John J Robertson Edmund F Meteorology MacTutor History of Mathematics archive University of St Andrews Biographical note at Lectures and Papers of Professor Daniel Rutherford 1749 1819 and Diary of Mrs Harriet Rutherford Archived 7 February 2012 at the Wayback Machine Sur la combustion en general On Combustion in general 1777 and Considerations Generales sur la Nature des Acides General Considerations on the Nature of Acids 1778 Nicholas W Best Lavoisier s Reflections on Phlogiston I Against Phlogiston Theory Foundations of Chemistry 2015 17 137 151 Nicholas W Best Lavoisier s Reflections on Phlogiston II On the Nature of Heat Foundations of Chemistry 2015 17 In this early work Lavoisier 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BOM celebrates 100 years Australian Broadcasting Corporation 31 December 2007 Collections in Perth 20 Meteorology National Archives of Australia Archived from the original on 12 February 2012 Retrieved 24 May 2008 Berknes V 1904 Das Problem der Wettervorhersage betrachtet vom Standpunkte der Mechanik und der Physik The problem of weather prediction considered from the viewpoints of mechanics and physics Meteorologische Zeitschrift 21 1 7 Available in English on line at Schweizerbart science publishers Pioneers in Modern Meteorology and Climatology Vilhelm and Jacob Bjerknes PDF Retrieved 13 October 2008 Richardson Lewis Fry Weather Prediction by Numerical Process Cambridge England Cambridge University Press 1922 Available on line at Internet Archive org Edwards Paul N Atmospheric General Circulation Modeling aip org American Institute of Physics Archived from the original on 25 March 2008 Retrieved 13 January 2008 Cox John D 2002 Storm Watchers John Wiley amp Sons Inc p 208 ISBN 978 0 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on 20 April 1999 Retrieved 2 January 2009 Peebles Peyton 1998 Radar Principles John Wiley amp Sons Inc New York ISBN 0 471 25205 0 Holton James An Introduction to Dynamic Meteorology PDF Elsevier Academic Press p 5 Retrieved 5 March 2016 AMS Glossary of Meteorology American Meteorological Society Archived from the original on 6 June 2011 Retrieved 12 April 2008 Online Glossary of Meteorology American Meteorological Society 1 2nd Ed 2000 Allen Press Bluestein H Synoptic Dynamic Meteorology in Midlatitudes Principles of Kinematics and Dynamics Vol 1 Oxford University Press 1992 ISBN 0 19 506267 1 Global Modelling Archived 21 August 2007 at the Wayback Machine US Naval Research Laboratory Monterey Ca Garratt J R The atmospheric boundary layer Cambridge University Press 1992 ISBN 0 521 38052 9 Holton J R 2004 An Introduction to Dynamic Meteorology 4th Ed Burlington Md Elsevier Inc ISBN 0 12 354015 1 Astrology Lessons Mistic House Archived from the original on 8 June 2008 Retrieved 12 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OF THE NCEP PRODUCTION SUITE FOR 2006 permanent dead link Retrieved on 5 May 2008 National Weather Service Mission Statement weather gov NOAA Archived from the original on 12 June 2008 Retrieved 25 May 2008 Fannin Blair 14 June 2006 Dry weather conditions continue for Texas Southwest Farm Press Archived from the original on 3 July 2009 Retrieved 26 May 2008 Mader Terry 3 April 2000 Drought Corn Silage beef unl edu University of Nebraska Lincoln Archived from the original on 5 October 2011 Retrieved 26 May 2008 Taylor Kathryn C March 2005 Peach Orchard Establishment and Young Tree Care pubs caes uga edu University of Georgia Archived from the original on 24 December 2008 Retrieved 26 May 2008 After Freeze Counting Losses to Orange Crop The New York Times Associated Press 14 January 1991 Archived from the original on 15 June 2018 Retrieved 26 May 2008 FUTURES OPTIONS Cold Weather Brings Surge In Prices of Heating Fuels The New York Times Reuters 26 February 1993 Archived from the original on 15 June 2018 Retrieved 25 May 2008 Heatwave causes electricity surge BBC News 25 July 2006 Archived from the original on 20 May 2009 Retrieved 25 May 2008 The seven key messages of the Energy Drill program PDF tcdsb org environment energydrill Toronto Catholic District School Board Archived from the original PDF on 17 February 2012 Retrieved 25 May 2008 An international version called the Aeronautical Information Publication contains parallel information as well as specific information on the international airports for use by the international community Aeronautical Information Manual Section 1 Meteorology 7 1 21 PIREPs Relating to Airframe Icing AIM Online Federal Aviation Administration Dept of Transportation 16 July 2020 Retrieved 17 August 2020 Agricultural and Forest Meteorology Elsevier ISSN 0168 1923 Encyclopaedia Britannica 2007 About the HPC NOAA National Weather Service National Centers for Environmental Prediction Hydrometeorological Prediction Center Camp Springs Maryland 2007 Home Retrieved 16 June 2015 DRIHM News number 1 March 2012 p2 An ideal environment for hydro meteorology research at the European level Tsitskishvili M S Trusov A G February 1974 Modern research in nuclear meteorology Atomic Energy 36 2 197 198 doi 10 1007 BF01117823 S2CID 96128061 Further reading EditByers Horace General Meteorology New York McGraw Hill 1994 Garret J R 1992 1992 The atmospheric boundary layer Cambridge University Press ISBN 978 0 521 38052 2 Glossary of Meteorology American Meteorological Society 2nd ed Allen Press 2000 a href Template Cite book html title Template Cite book cite book a CS1 maint others link Bluestein H 1992 1992 Synoptic Dynamic Meteorology in Midlatitudes Principles of Kinematics and Dynamics Vol 1 Oxford University Press ISBN 978 0 19 506267 0 Bluestein H 1993 1993 Synoptic Dynamic Meteorology in Midlatitudes Volume II Observations and Theory of Weather Systems Oxford University Press ISBN 978 0 19 506268 7 Reynolds R 2005 2005 Guide to Weather Buffalo New York Firefly Books Inc p 208 ISBN 978 1 55407 110 4 Holton J R 2004 2004 An Introduction to Dynamic Meteorology 4th ed Burlington Md Elsevier Inc ISBN 978 0 12 354015 7 Archived from the original on 19 July 2013 Retrieved 21 May 2017 Roulstone Ian amp Norbury John 2013 Invisible in the Storm the role of mathematics in understanding weather Princeton University Press ISBN 978 0691152721 Dictionaries and encyclopedias Edit Glickman Todd S June 2000 Meteorology Glossary electronic 2nd ed Cambridge Massachusetts American Meteorological Society Gustavo Herrera Roberto Garcia Herrera Ricardo Prieto Luis Gallego David Hernandez Emiliano Gimeno Luis Konnen Gunther Koek Frits Wheeler Dennis Wilkinson Clive Del Rosario Prieto Maria Baez Carlos Woodruff Scott A Dictionary of Nautical Meteorological Terms CLIWOC Multilingual Dictionary of Meteorological Terms An English Spanish French Dutch Dictionary of Windforce Terms Used by Mariners from 1750 to 1850 PDF CLIWOC Meteorology Encyclopedia Central Weather Bureau 6 December 2018 Archived from the original on 21 September 2014 Retrieved 14 September 2014 History Edit Lawrence Mathers Anne 2020 Medieval Meteorology Forecasting the Weather from Aristotle to the Almanac Cambridge Cambridge University Press doi 10 1017 9781108289948 ISBN 978 1 108 40600 0 S2CID 211658964 External links Edit Wikimedia Commons has media related to Meteorology Wikisource has original works on the topic Meteorology Wikiversity has learning resources about Meteorology Please see weather forecasting for weather forecast sites Air Quality Meteorology Online course that introduces the basic concepts of meteorology and air quality necessary to understand meteorological computer models Written at a bachelor s degree level The GLOBE Program Global Learning and Observations to Benefit the Environment An international environmental science and education program that links students teachers and the scientific research community in an effort to learn more about the environment through student data collection and observation Glossary of Meteorology From the American Meteorological Society an excellent reference of nomenclature equations and concepts for the more advanced reader JetStream An Online School for Weather National Weather Service Learn About Meteorology Australian Bureau of Meteorology The Weather Guide Weather Tutorials and News at About com Meteorology Education and Training MetEd The COMET Program NOAA Central Library National Oceanic amp Atmospheric Administration The World Weather 2010 Project Archived 19 August 2008 at the Wayback Machine The University of Illinois at Urbana Champaign Ogimet online data from meteorological stations of the world obtained through NOAA free services National Center for Atmospheric Research Archives documents the history of meteorology Weather forecasting and Climate science United Kingdom Meteorological Office Meteorology BBC Radio 4 discussion with Vladimir Jankovic Richard Hambyn and Iba Taub In Our Time 6 March 2003 Virtual exhibition about meteorology on the digital library of Paris Observatory Portal Weather Retrieved from https en wikipedia org w index php title Meteorology amp oldid 1126855103, wikipedia, wiki, book, books, library,

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