Antoine-Laurent de Lavoisier was a French nobleman and chemist, central to the 18th-century chemical revolution and who had a large influence on both the history of chemistry and the history of biology. He is considered in popular literature as the "father of modern chemistry", it is accepted that Lavoisier's great accomplishments in chemistry stem from his changing the science from a qualitative to a quantitative one. Lavoisier is most noted, he opposed the phlogiston theory. Lavoisier helped construct the metric system, wrote the first extensive list of elements, helped to reform chemical nomenclature, he predicted the existence of silicon and was the first to establish that sulfur was an element rather than a compound. He discovered that, although matter may change its shape, its mass always remains the same. Lavoisier was a powerful member of a number of aristocratic councils, an administrator of the Ferme générale; the Ferme générale was one of the most hated components of the Ancien Régime because of the profits it took at the expense of the state, the secrecy of the terms of its contracts, the violence of its armed agents.
All of these political and economic activities enabled him to fund his scientific research. At the height of the French Revolution, he was charged with tax fraud and selling adulterated tobacco, was guillotined. Antoine-Laurent Lavoisier was born to a wealthy family of the nobility in Paris on 26 August 1743; the son of an attorney at the Parliament of Paris, he inherited a large fortune at the age of five upon the death of his mother. Lavoisier began his schooling at the Collège des Quatre-Nations, University of Paris in Paris in 1754 at the age of 11. In his last two years at the school, his scientific interests were aroused, he studied chemistry, botany and mathematics. In the philosophy class he came under the tutelage of Abbé Nicolas Louis de Lacaille, a distinguished mathematician and observational astronomer who imbued the young Lavoisier with an interest in meteorological observation, an enthusiasm which never left him. Lavoisier entered the school of law, where he received a bachelor's degree in 1763 and a licentiate in 1764.
Lavoisier was admitted to the bar, but never practiced as a lawyer. However, he continued his scientific education in his spare time. Lavoisier's education was filled with the ideals of the French Enlightenment of the time, he was fascinated by Pierre Macquer's dictionary of chemistry, he attended. Lavoisier's devotion and passion for chemistry were influenced by Étienne Condillac, a prominent French scholar of the 18th century, his first chemical publication appeared in 1764. From 1763 to 1767, he studied geology under Jean-Étienne Guettard. In collaboration with Guettard, Lavoisier worked on a geological survey of Alsace-Lorraine in June 1767. In 1764 he read his first paper to the French Academy of Sciences, France's most elite scientific society, on the chemical and physical properties of gypsum, in 1766 he was awarded a gold medal by the King for an essay on the problems of urban street lighting. In 1768 Lavoisier received a provisional appointment to the Academy of Sciences. In 1769, he worked on the first geological map of France.
While Lavoisier is known for his contributions to the sciences, he dedicated a significant portion of his fortune and work toward benefitting the public. Lavoisier was a humanitarian—he cared about the people in his country and concerned himself with improving the livelihood of the population by agriculture and the sciences; the first instance of this occurred in 1765, when he submitted an essay on improving urban street lighting to the French Academy of Sciences. Three years in 1768, he focused on a new project to design an aqueduct; the goal was to bring in water from the river Yvette into Paris so that the citizens could have clean drinking water. But, since the construction never commenced, he instead turned his focus to purifying the water from the Seine; this was the project that interested Lavoisier in the chemistry of water and public sanitation duties. He additionally was interested in air quality, spent some time studying the health risks associated with gunpowder's effect on the air.
In 1772, he performed a study on how to reconstruct the Hôtel-Dieu hospital, after it had been damaged by fire, in a way that would allow proper ventilation and clean air throughout. At the time, the prisons in Paris were known to be unlivable and the prisoners’ treatment inhumane. Lavoisier took part in investigations in 1780 on the hygiene in prisons and had made suggestions to improve living conditions, which were ignored. Once a part of the Academy, Lavoisier held his own competitions to push the direction of research towards bettering the public and his own work. One such project he proposed in 1793 was to better public health on the “insalubrious arts.” Lavoisier had a vision of public education having roots in “scientific sociability” and philanthropy. Lavoisier gained a vast majority of his income through buying stock in the General Farm, which allowed him to work on science full-time, live comfortably, allowed him to contribute financially to better the community, it was difficult to secure public funding for the sciences at the time, additionally not ver
The kilometre, or kilometer is a unit of length in the metric system, equal to one thousand metres. It is now the measurement unit used for expressing distances between geographical places on land in most of the world. K is used in some English-speaking countries as an alternative for the word kilometre in colloquial writing and speech. A slang term for the kilometre in the US and UK military is klick. There are two common pronunciations for the word; the former follows a pattern in English whereby metric units are pronounced with the stress on the first syllable and the pronunciation of the actual base unit does not change irrespective of the prefix. It is preferred by the British Broadcasting Corporation and the Australian Broadcasting Corporation. Many scientists and other users in countries where the metric system is not used, use the pronunciation with stress on the second syllable; the latter pronunciation follows the stress pattern used for the names of measuring instruments. The problem with this reasoning, however, is that the word meter in those usages refers to a measuring device, not a unit of length.
The contrast is more obvious in countries using the British rather than American spelling of the word metre. When Australia introduced the metric system in 1975, the first pronunciation was declared official by the government's Metric Conversion Board. However, the Australian prime minister at the time, Gough Whitlam, insisted that the second pronunciation was the correct one because of the Greek origins of the two parts of the word. By the 8 May 1790 decree, the Constituent assembly ordered the French Academy of Sciences to develop a new measurement system. In August 1793, the French National Convention decreed the metre as the sole length measurement system in the French Republic; the first name of the kilometre was "Millaire". Although the metre was formally defined in 1799, the myriametre was preferred to the "kilometre" for everyday use; the term "myriamètre" appeared a number of times in the text of Develey's book Physique d'Emile: ou, Principes de la science de la nature, while the term kilometre only appeared in an appendix.
French maps published in 1835 had scales showing myriametres and "lieues de Poste". The Dutch gave it the local name of the mijl, it was only in 1867 that the term "kilometer" became the only official unit of measure in the Netherlands to represent 1000 metres. Two German textbooks dated 1842 and 1848 give a snapshot of the use of the kilometre across Europe - the kilometre was in use in the Netherlands and in Italy and the myriametre was in use in France. In 1935, the International Committee for Weights and Measures abolished the prefix "myria-" and with it the "myriametre", leaving the kilometre as the recognised unit of length for measurements of that magnitude. In the United Kingdom, road signs show distances in miles and location marker posts that are used for reference purposes by road engineers and emergency services show distance references in unspecified units which are kilometre-based; the advent of the mobile phone has been instrumental in the British Department for Transport authorising the use of driver location signs to convey the distance reference information of location marker posts to road users should they need to contact the emergency services.
In the US, the National Highway System Designation Act of 1995 prohibits the use of federal-aid highway funds to convert existing signs or purchase new signs with metric units. The Executive Director of the US Federal Highway Administration, Jeffrey Paniati, wrote in a 2008 memo: "Section 205 of the National Highway System Designation Act of 1995 prohibited us from requiring any State DOT to use the metric system during project development activities. Although the State DOT's had the option of using metric measurements or dual units, all of them abandoned metric measurements and reverted to sole use of inch-pound values." The Manual on Uniform Traffic Control Devices since 2000 is published in both metric and American Customary Units. Some sporting disciplines feature 1000 m races in major events, but in other disciplines though world records are catalogued, the one kilometre event remains a minority event; the world records for various sporting disciplines are: Conversion of units, for comparison with other units of length Cubic metre Metric prefix Mileage Odometer Orders of magnitude Square kilometre Media related to Distance indicators at Wikimedia Commons
International System of Units
The International System of Units is the modern form of the metric system, is the most used system of measurement. It comprises a coherent system of units of measurement built on seven base units, which are the ampere, second, kilogram, mole, a set of twenty prefixes to the unit names and unit symbols that may be used when specifying multiples and fractions of the units; the system specifies names for 22 derived units, such as lumen and watt, for other common physical quantities. The base units are derived from invariant constants of nature, such as the speed of light in vacuum and the triple point of water, which can be observed and measured with great accuracy, one physical artefact; the artefact is the international prototype kilogram, certified in 1889, consisting of a cylinder of platinum-iridium, which nominally has the same mass as one litre of water at the freezing point. Its stability has been a matter of significant concern, culminating in a revision of the definition of the base units in terms of constants of nature, scheduled to be put into effect on 20 May 2019.
Derived units may be defined in terms of other derived units. They are adopted to facilitate measurement of diverse quantities; the SI is intended to be an evolving system. The most recent derived unit, the katal, was defined in 1999; the reliability of the SI depends not only on the precise measurement of standards for the base units in terms of various physical constants of nature, but on precise definition of those constants. The set of underlying constants is modified as more stable constants are found, or may be more measured. For example, in 1983 the metre was redefined as the distance that light propagates in vacuum in a given fraction of a second, thus making the value of the speed of light in terms of the defined units exact; the motivation for the development of the SI was the diversity of units that had sprung up within the centimetre–gram–second systems and the lack of coordination between the various disciplines that used them. The General Conference on Weights and Measures, established by the Metre Convention of 1875, brought together many international organisations to establish the definitions and standards of a new system and standardise the rules for writing and presenting measurements.
The system was published in 1960 as a result of an initiative that began in 1948. It is based on the metre–kilogram–second system of units rather than any variant of the CGS. Since the SI has been adopted by all countries except the United States and Myanmar; the International System of Units consists of a set of base units, derived units, a set of decimal-based multipliers that are used as prefixes. The units, excluding prefixed units, form a coherent system of units, based on a system of quantities in such a way that the equations between the numerical values expressed in coherent units have the same form, including numerical factors, as the corresponding equations between the quantities. For example, 1 N = 1 kg × 1 m/s2 says that one newton is the force required to accelerate a mass of one kilogram at one metre per second squared, as related through the principle of coherence to the equation relating the corresponding quantities: F = m × a. Derived units apply to derived quantities, which may by definition be expressed in terms of base quantities, thus are not independent.
Other useful derived quantities can be specified in terms of the SI base and derived units that have no named units in the SI system, such as acceleration, defined in SI units as m/s2. The SI base units are the building blocks of the system and all the other units are derived from them; when Maxwell first introduced the concept of a coherent system, he identified three quantities that could be used as base units: mass and time. Giorgi identified the need for an electrical base unit, for which the unit of electric current was chosen for SI. Another three base units were added later; the early metric systems defined a unit of weight as a base unit, while the SI defines an analogous unit of mass. In everyday use, these are interchangeable, but in scientific contexts the difference matters. Mass the inertial mass, represents a quantity of matter, it relates the acceleration of a body to the applied force via Newton's law, F = m × a: force equals mass times acceleration. A force of 1 N applied to a mass of 1 kg will accelerate it at 1 m/s2.
This is true whether the object is floating in space or in a gravity field e.g. at the Earth's surface. Weight is the force exerted on a body by a gravitational field, hence its weight depends on the strength of the gravitational field. Weight of a 1 kg mass at the Earth's surface is m × g. Since the acceleration due to gravity is local and varies by location and altitude on the Earth, weight is unsuitable for precision
A metric prefix is a unit prefix that precedes a basic unit of measure to indicate a multiple or fraction of the unit. While all metric prefixes in common use today are decadic there have been a number of binary metric prefixes as well; each prefix has a unique symbol, prepended to the unit symbol. The prefix kilo-, for example, may be added to gram to indicate multiplication by one thousand: one kilogram is equal to one thousand grams; the prefix milli- may be added to metre to indicate division by one thousand. Decimal multiplicative prefixes have been a feature of all forms of the metric system, with six of these dating back to the system's introduction in the 1790s. Metric prefixes have been used with some non-metric units; the SI prefixes are standardized for use in the International System of Units by the International Bureau of Weights and Measures in resolutions dating from 1960 to 1991. Since 2009, they have formed part of the International System of Quantities; the BIPM specifies twenty prefixes for the International System of Units.
Each prefix name has a symbol, used in combination with the symbols for units of measure. For example, the symbol for'kilo-' is'k', is used to produce'km','kg', and'kW', which are the SI symbols for kilometre and kilowatt, respectively. Where the Greek letter'μ' is unavailable, the symbol for micro'µ' may be used. Where both variants are unavailable, the micro prefix is written as the lowercase Latin letter'u'. Prefixes corresponding to an integer power of one thousand are preferred. Hence'100 m' is preferred over'1 hm' or'10 dam'; the prefixes hecto, deca and centi are used for everyday purposes, the centimetre is common. However, some modern building codes require that the millimetre be used in preference to the centimetre, because "use of centimetres leads to extensive usage of decimal points and confusion". Prefixes may not be used in combination; this applies to mass, for which the SI base unit contains a prefix. For example, milligram is used instead of microkilogram. In the arithmetic of measurements having units, the units are treated as multiplicative factors to values.
If they have prefixes, all but one of the prefixes must be expanded to their numeric multiplier, except when combining values with identical units. Hence, 5 mV × 5 mA = 5×10−3 V × 5×10−3 A = 25×10−6 V⋅A = 25 μW 5.00 mV + 10 μV = 5.00 mV + 0.01 mV = 5.01 mVWhen powers of units occur, for example, squared or cubed, the multiplication prefix must be considered part of the unit, thus included in the exponentiation. 1 km2 means one square kilometre, or the area of a square of 1000 m by 1000 m and not 1000 square metres. 2 Mm3 means two cubic megametres, or the volume of two cubes of 1000000 m by 1000000 m by 1000000 m or 2×1018 m3, not 2000000 cubic metres. Examples5 cm = 5×10−2 m = 5 × 0.01 m = 0.05 m 9 km2 = 9 × 2 = 9 × 2 × m2 = 9×106 m2 = 9 × 1000000 m2 = 9000000 m2 3 MW = 3×106 W = 3 × 1000000 W = 3000000 W The use of prefixes can be traced back to the introduction of the metric system in the 1790s, long before the 1960 introduction of the SI. The prefixes, including those introduced after 1960, are used with any metric unit, whether included in the SI or not.
Metric prefixes may be used with non-metric units. The choice of prefixes with a given unit is dictated by convenience of use. Unit prefixes for amounts that are much larger or smaller than those encountered are used; the units kilogram, milligram and smaller are used for measurement of mass. However, megagram and larger are used. Megagram and teragram are used to disambiguate the metric tonne from other units with the name'ton'; the kilogram is the only base unit of the International System of Units that includes a metric prefix. The litre, millilitre and smaller are common. In Europe, the centilitre is used for packaged products such as wine and the decilitre is less frequently; the latter two items include prefixes corresponding to an exponent, not divisible by three. Larger volumes are denoted in kilolitres, megalitres or gigalitres, or else in cubic metres or cubic kilometres. For scientific purposes, the cubic metre is used; the kilometre, centimetre and smaller are common. The micrometre is referred to by the non-SI term micron.
In some fields, such as chemistry, the ångström competed with the nanometre. The femtometre, used in particle physics, is sometimes called a fermi. For large scales, megametre and larger are used. Instead, non-metric units are used, such as astronomical units, light years, parsecs; the second, millisecond and shorter are common. The kilosecond and megasecond have some use, though for these and longer times one uses either scientific notation or minutes, so on; the SI unit of angle is the radian, but degrees and seconds see some scientific use. Official policy varies from common practice for the degree Celsius. NIST states: "Prefix symbols may be used with the unit symbol °C and prefix names may be used with the unit name'degree Celsius'. For example, 12 m°C (12 millidegr
The gram is a metric system unit of mass. Defined as "the absolute weight of a volume of pure water equal to the cube of the hundredth part of a metre, at the temperature of melting ice". However, in a reversal of reference and defined units, a gram is now defined as one thousandth of the SI base unit, the kilogram, or 1×10−3 kg, which itself is now defined by the International Bureau of Weights and Measures, not in terms of grams, but by "the amount of electricity needed to counteract its force" The only unit symbol for gram, recognised by the International System of Units is "g" following the numeric value with a space, as in "640 g" to stand for "640 grams" in the English language; the SI does not support the use of abbreviations such as "gr", "gm" or "Gm". The word gramme was adopted by the French National Convention in its 1795 decree revising the metric system as replacing the gravet introduced in 1793, its definition remained that of the weight of a cubic centimetre of water. French gramme was taken from the Late Latin term gramma.
This word—ultimately from Greek γράμμα, "letter"—had adopted a specialised meaning in Late Antiquity of "one twenty-fourth part of an ounce", corresponding to about 1.14 modern grams. This use of the term is found in the carmen de ponderibus et mensuris composed around 400 AD. There is evidence that the Greek γράμμα was used in the same sense at around the same time, in the 4th century, survived in this sense into Medieval Greek, while the Latin term did not remain current in Medieval Latin and was recovered in Renaissance scholarship; the gram was the fundamental unit of mass in the 19th-century centimetre–gram–second system of units. The CGS system co-existed with the MKS system of units, first proposed in 1901, during much of the 20th century, but the gram has been displaced by the kilogram as the fundamental unit for mass when the MKS system was chosen for the SI base units in 1960; the gram is today the most used unit of measurement for non-liquid ingredients in cooking and grocery shopping worldwide.
Most standards and legal requirements for nutrition labels on food products require relative contents to be stated per 100 g of the product, such that the resulting figure can be read as a percentage by weight. 1 gram = 15.4323583529 grains 1 grain = 0.06479891 grams 1 avoirdupois ounce = 28.349523125 grams 1 troy ounce = 31.1034768 grams 100 grams = 3.527396195 ounces 1 gram = 5 carats 1 gram = 8.98755179×1013 joules 1 undecimogramme = 1 "eleventh-gram" = 10−11 grams in the historic quadrant–eleventh-gram–second system a.k.a. hebdometre–undecimogramme–second system 500 grams = 1 Jin in the Chinese units of measurement. 1 gram is equal to 1 small paper clip or pen cap. The Japanese 1 yen coin has a mass of one gram, lighter than the British penny, the United States cent, the Euro cent, the 5 cent Australian coins. Conversion of units Duella Gold gram Orders of magnitude Gram at Encyclopædia Britannica
Dollar is the name of more than 20 currencies, including those of Australia, Hong Kong, Liberia, New Zealand, Singapore and the United States. The U. S. dollar is the official currency of the Caribbean Netherlands, East Timor, Ecuador, El Salvador, the Federated States of Micronesia, the Marshall Islands and Zimbabwe. One dollar is divided into 100 cents. On 15 January 1520, the Kingdom of Bohemia began minting coins from silver mined locally in Joachimsthal and marked on reverse with the Bohemian lion; the coins were called joachimsthaler, which became shortened in common usage to taler. The German name "Joachimsthal" means "Joachim's valley" or "Joachim's dale"; this name found its way into other languages: Czech and Slovenian tolar, Hungarian tallér, Danish and Norwegian daler, Swedish daler, Icelandic dalur, Dutch daalder or daler, Ethiopian ታላሪ, Italian tallero, Greek τάλληρον, τάλιρο, tàlleron, tàliro, Polish talar, Persian dare, as well as – via Dutch – into English as dollar. A Dutch coin depicting a lion was called the leeuwendaler or leeuwendaalder, literally'lion daler'.
The Dutch Republic produced these coins to accommodate its booming international trade. The leeuwendaler circulated throughout the Middle East and was imitated in several German and Italian cities; this coin was popular in the Dutch East Indies and in the Dutch New Netherland Colony. It was in circulation throughout the Thirteen Colonies during the 17th and early 18th centuries and was popularly known as "lion dollar"; the currencies of Romania and Bulgaria are, to this day,'lion'. The modern American-English pronunciation of dollar is still remarkably close to the 17th century Dutch pronunciation of daler; some well-worn examples circulating in the Colonies were known as "dog dollars". Spanish pesos – having the same weight and shape – came to be known as Spanish dollars. By the mid-18th century, the lion dollar had been replaced by Spanish dollar, the famous "pieces of eight", which were distributed in the Spanish colonies in the New World and in the Philippines; the sign is first attested in business correspondence in the 1770s as a scribal abbreviation "ps", referring to the Spanish American peso, that is, the "Spanish dollar" as it was known in British North America.
These late 18th- and early 19th-century manuscripts show that the s came to be written over the p developing a close equivalent to the "$" mark, this new symbol was retained to refer to the American dollar as well, once this currency was adopted in 1785 by the United States. By the time of the American Revolution, Spanish dollars gained significance because they backed paper money authorized by the individual colonies and the Continental Congress. Common in the Thirteen Colonies, Spanish dollars were legal tender in one colony, Virginia. On April 2, 1792, U. S. Secretary of the Treasury Alexander Hamilton reported to Congress the precise amount of silver found in Spanish dollar coins in common use in the states; as a result, the United States dollar was defined as a unit of pure silver weighing 371 4/16th grains, or 416 grains of standard silver. It was specified that the "money of account" of the United States should be expressed in those same "dollars" or parts thereof. Additionally, all lesser-denomination coins were defined as percentages of the dollar coin, such that a half-dollar was to contain half as much silver as a dollar, quarter-dollars would contain one-fourth as much, so on.
In an act passed in January 1837, the dollar's alloy was set at 15%. Subsequent coins would contain the same amount of pure silver as but were reduced in overall weight. On February 21, 1853, the quantity of silver in the lesser coins was reduced, with the effect that their denominations no longer represented their silver content relative to dollar coins. Various acts have subsequently been passed affecting the amount and type of metal in U. S. coins, so that today there is no legal definition of the term "dollar" to be found in U. S. statute. The closest thing to a definition is found in United States Code Title 31, Section 5116, paragraph b, subsection 2: "The Secretary shall sell silver under conditions the Secretary considers appropriate for at least $1.292929292 a fine troy ounce." However, the dollar's constitutional meaning has remained unchanged through the years. Silver was removed from U. S. coinage by 1965 and the dollar became a free-floating fiat currency without a commodity backing defined in terms of real gold or silver.
The US Mint continues to make silver $1-denomination coins, but these are not intended for general circulation. The quantity of silver chosen in 1792 to correspond to one dollar, namely, 371.25 grains of pure silver, is close to the geometric mean of one troy pound and one pennyweight. In what follows, "dollar" will be used as a unit of mass. A troy pound being 5760 grains and a pennyweight being 240 times smaller, or 24 grains, the geometric mean is, to the nearest hundredth, 371.81 grains. This means that the ratio of a pound to a dollar equals the ratio of a dollar to a pennyweight; these ratios are very close to the ratio of a gram to a grain: 15.43. In the United States, the ratio of the value of gold to the value of silver in the period from 1792 to 1873 averaged to about 15.5, being 15 from 1792 to 1834 and around 16 from 1834 to 1873. This is nearly the value of the gold to silver ratio determined by Isaac Newton in 17
The euro is the official currency of 19 of the 28 member states of the European Union. This group of states is known as the eurozone or euro area, counts about 343 million citizens as of 2019; the euro is the second largest and second most traded currency in the foreign exchange market after the United States dollar. The euro is subdivided into 100 cents; the currency is used by the institutions of the European Union, by four European microstates that are not EU members, as well as unilaterally by Montenegro and Kosovo. Outside Europe, a number of special territories of EU members use the euro as their currency. Additionally, 240 million people worldwide as of 2018 use currencies pegged to the euro; the euro is the second largest reserve currency as well as the second most traded currency in the world after the United States dollar. As of August 2018, with more than €1.2 trillion in circulation, the euro has one of the highest combined values of banknotes and coins in circulation in the world, having surpassed the U.
S. dollar. The name euro was adopted on 16 December 1995 in Madrid; the euro was introduced to world financial markets as an accounting currency on 1 January 1999, replacing the former European Currency Unit at a ratio of 1:1. Physical euro coins and banknotes entered into circulation on 1 January 2002, making it the day-to-day operating currency of its original members, by March 2002 it had replaced the former currencies. While the euro dropped subsequently to US$0.83 within two years, it has traded above the U. S. dollar since the end of 2002, peaking at US$1.60 on 18 July 2008. In late 2009, the euro became immersed in the European sovereign-debt crisis, which led to the creation of the European Financial Stability Facility as well as other reforms aimed at stabilising and strengthening the currency; the euro is managed and administered by the Frankfurt-based European Central Bank and the Eurosystem. As an independent central bank, the ECB has sole authority to set monetary policy; the Eurosystem participates in the printing and distribution of notes and coins in all member states, the operation of the eurozone payment systems.
The 1992 Maastricht Treaty obliges most EU member states to adopt the euro upon meeting certain monetary and budgetary convergence criteria, although not all states have done so. The United Kingdom and Denmark negotiated exemptions, while Sweden turned down the euro in a 2003 referendum, has circumvented the obligation to adopt the euro by not meeting the monetary and budgetary requirements. All nations that have joined the EU since 1993 have pledged to adopt the euro in due course. Since 1 January 2002, the national central banks and the ECB have issued euro banknotes on a joint basis. Euro banknotes do not show. Eurosystem NCBs are required to accept euro banknotes put into circulation by other Eurosystem members and these banknotes are not repatriated; the ECB issues 8% of the total value of banknotes issued by the Eurosystem. In practice, the ECB's banknotes are put into circulation by the NCBs, thereby incurring matching liabilities vis-à-vis the ECB; these liabilities carry interest at the main refinancing rate of the ECB.
The other 92% of euro banknotes are issued by the NCBs in proportion to their respective shares of the ECB capital key, calculated using national share of European Union population and national share of EU GDP weighted. The euro is divided into 100 cents. In Community legislative acts the plural forms of euro and cent are spelled without the s, notwithstanding normal English usage. Otherwise, normal English plurals are sometimes used, with many local variations such as centime in France. All circulating coins have a common side showing the denomination or value, a map in the background. Due to the linguistic plurality in the European Union, the Latin alphabet version of euro is used and Arabic numerals. For the denominations except the 1-, 2- and 5-cent coins, the map only showed the 15 member states which were members when the euro was introduced. Beginning in 2007 or 2008 the old map is being replaced by a map of Europe showing countries outside the Union like Norway, Belarus, Russia or Turkey.
The 1-, 2- and 5-cent coins, keep their old design, showing a geographical map of Europe with the 15 member states of 2002 raised somewhat above the rest of the map. All common sides were designed by Luc Luycx; the coins have a national side showing an image chosen by the country that issued the coin. Euro coins from any member state may be used in any nation that has adopted the euro; the coins are issued in denominations of €2, €1, 50c, 20c, 10c, 5c, 2c, 1c. To avoid the use of the two smallest coins, some cash transactions are rounded to the nearest five cents in the Netherlands and Ireland and in Finland; this practice is discouraged by the Commission, as is the practice of certain shops of refusing to accept high-value euro notes. Commemorative coins with €2 face value have been issued with changes to the design of the national side of the coin; these include both issued coins, such as the €2 commemorative coin for the fiftieth anniversary of the signing of the Treaty of Rome, nationally i