About: Energy

In physics, energy is an indirectly observed quantity. It is often understood as the ability a physical system has to do work on other physical systems. Since work is defined as a force acting through a distance (a length of space), energy is always equivalent to the ability to exert pulls or pushes against the basic forces of nature, along a path of a certain length. The total energy contained in an object is identified with its mass, and energy (like mass), cannot be created or destroyed.

Property	Value
dbpedia-owl:abstract	Die Energie ist eine physikalische Größe, die in allen Teilgebieten der Physik sowie in der Technik, der Chemie, der Biologie und der Wirtschaft eine zentrale Rolle spielt. Ihre SI-Einheit ist das Joule. In der theoretischen Physik wird Energie als diejenige Größe definiert, die aufgrund der Zeitinvarianz der Naturgesetze erhalten bleibt. Viele einführende Texte definieren Energie in anschaulicherer, allerdings nicht allgemeingültiger Form als Fähigkeit, mechanische Arbeit zu verrichten, Wärme abzugeben oder Licht auszusenden. In der technischen Thermodynamik wird die maximale Arbeit, die sie verrichten kann, als Exergie bezeichnet. Energie ist nötig, um einen Körper zu beschleunigen oder um ihn entgegen einer Kraft zu bewegen, um eine Substanz zu erwärmen, um ein Gas zusammenzudrücken, um elektrischen Strom fließen zu lassen oder um elektromagnetische Wellen abzustrahlen. Pflanzen, Tiere und Menschen benötigen Energie, um leben zu können. Energie benötigt man auch für den Betrieb von Computersystemen, für Telekommunikation und für jegliche wirtschaftliche Produktion. Energie kann in verschiedenen Energieformen vorkommen. Hierzu gehören beispielsweise potentielle Energie, kinetische Energie, chemische Energie oder thermische Energie. Energie lässt sich in verschiedene Energieformen umwandeln. Dabei kann die Gesamtenergie innerhalb eines abgeschlossenen Systems aufgrund der Energieerhaltung weder vermehrt noch vermindert werden. Weiterhin setzt der zweite Hauptsatz der Thermodynamik der Umwandelbarkeit prinzipielle Grenzen, insbesondere ist thermische Energie nur eingeschränkt in andere Energieformen umwandelbar und zwischen Systemen übertragbar. Nach der Einsteinschen Relativitätstheorie muss auch einer ruhenden Masse m eine Energie vom Betrag zugeordnet werden. Gemäß den hamiltonschen Bewegungsgleichungen und der Schrödinger-Gleichung bestimmt Energie die zeitliche Entwicklung physikalischer Systeme. In physics, energy is an indirectly observed quantity. It is often understood as the ability a physical system has to do work on other physical systems. Since work is defined as a force acting through a distance (a length of space), energy is always equivalent to the ability to exert pulls or pushes against the basic forces of nature, along a path of a certain length. The total energy contained in an object is identified with its mass, and energy (like mass), cannot be created or destroyed. When matter (ordinary material particles) is changed into energy (such as energy of motion, or into radiation), the mass of the system does not change through the transformation process. However, there may be mechanistic limits as to how much of the matter in an object may be changed into other types of energy and thus into work, on other systems. Energy, like mass, is a scalar physical quantity. In the International System of Units (SI), energy is measured in joules, but in many fields other units, such as kilowatt-hours and kilocalories, are customary. All of these units translate to units of work, which is always defined in terms of forces and the distances that the forces act through. A system can transfer energy to another system by simply transferring matter to it (since matter is equivalent to energy, in accordance with its mass). However, when energy is transferred by means other than matter-transfer, the transfer produces changes in the second system, as a result of work done on it. This work manifests itself as the effect of force(s) applied through distances within the target system. For example, a system can emit energy to another by transferring (radiating) electromagnetic energy, but this creates forces upon the particles that absorb the radiation. Similarly, a system may transfer energy to another by physically impacting it, but that case the energy of motion in an object, called kinetic energy, results in forces acting over distances (new energy) to appear in another object that is struck. Transfer of thermal energy by heat occurs by both of these mechanisms: heat can be transferred by electromagnetic radiation, or by physical contact in which direct particle-particle impacts transfer kinetic energy. Energy may be stored in systems without being present as matter, or as kinetic or electromagnetic energy. Stored energy is created whenever a particle has been moved through a field it interacts with (requiring a force to do so), but the energy to accomplish this is stored as a new position of the particles in the field—a configuration that must be "held" or fixed by a different type of force (otherwise, the new configuration would resolve itself by the field pushing or pulling the particle back toward its previous position). This type of energy "stored" by force-fields and particles that have been forced into a new physical configuration in the field by doing work on them by another system, is referred to as potential energy. A simple example of potential energy is the work needed to lift an object in a gravity field, up to a support. Each of the basic forces of nature is associated with a different type of potential energy, and all types of potential energy (like all other types of energy) appears as system mass, whenever present. For example, a compressed spring will be slightly more massive than before it was compressed. Likewise, whenever energy is transferred between systems by any mechanism, an associated mass is transferred with it. Any form of energy may be transformed into another form. For example, all types of potential energy are converted into kinetic energy when the objects are given freedom to move to different position (as for example, when an object falls off a support). When energy is in a form other than thermal energy, it may be transformed with good or even perfect efficiency, to any other type of energy, including electricity or production of new particles of matter. With thermal energy, however, there are often limits to the efficiency of the conversion to other forms of energy, as described by the second law of thermodynamics. In all such energy transformation processes, the total energy remains the same, and a transfer of energy from one system to another, results in a loss to compensate for any gain. This principle, the conservation of energy, was first postulated in the early 19th century, and applies to any isolated system. According to Noether's theorem, the conservation of energy is a consequence of the fact that the laws of physics do not change over time. Although the total energy of a system does not change with time, its value may depend on the frame of reference. For example, a seated passenger in a moving airplane has zero kinetic energy relative to the airplane, but non-zero kinetic energy (and higher total energy) relative to the Earth. El término energía tiene diversas acepciones y definiciones, relacionadas con la idea de una capacidad para obrar, transformar o poner en movimiento. En física, «energía» se define como la capacidad para realizar un trabajo. En tecnología y economía, «energía» se refiere a un recurso natural (incluyendo a su tecnología asociada) para extraerla, transformarla, y luego darle un uso industrial o económico. Energia on kaikilla fysiikan aloilla keskeisessä asemassa esiintyvä suure, jota koskee yleinen säilymislaki. Energia määritellään usein voiman, kappaleen tai systeemin kyvyksi tehdä työtä. Työ taas voi esimerkiksi kiihdyttää jotakin kappaletta. Fysiikan, erityisesti termodynamiikan kehitys on kuitenkin johtanut energian käsitteen laajenemiseen, eikä tämä määritelmä mutkattomasti sovellu kaikkiin energian muotoihin. SI-järjestelmässä energian ja myös työn yksikkö on joule. Sähköenergian yksikkönä käytetään usein kilowattituntia (1 kWh = 3,6 MJ = 3 600 000 J). Myös muita energian yksiköitä käytetään yleisesti. Energialla voi olla erilaisia ilmenemismuotoja: liike-energia, potentiaalienergia, lämpöenergia, sähkömagneettinen energia jne. Energian eri muodot voivat muuttua toisikseen. Kaikissa fysiikan tuntemissa ilmiöissä eri energianmuotojen summa kuitenkin pysyy vakiona, toisin sanoen energiaa ei synny eikä häviä. Tämän ilmaisee energian säilymislaki, joka tunnetaan myös energiaperiaatteena. Kaikki energian muodot eivät kuitenkaan ole käytettävissä mekaanisen työn suorittamiseen. Esimerkiksi lämpöenergia voi tehdä työtä vain, jos se on epätasaisesti jakautunut. Exergia on se osuus energiasta, joka voi tehdä työtä, anergia on se osa, jota ei voi täten hyödyntää, esimerkiksi lämpöenergia ympäristön lämpötilassa. Systeemin (esim. kappaleen) kokonaisenergia on jossa T on liike-energia, V potentiaalienergia ja U systeemin sisäinen energia. Kokonaisenergia E voidaan jakaa monella tavalla näihin komponentteihin, joten eri havaitsijat voivat mitata samalle kappaleelle esim. erilaisen liike-energian. Ajattele vaikka liikkuvassa autossa olevaa kappaletta. Auton sisällä ja ulkopuolella olevat havaitsijat mittaavat kappaleelle erilaiset nopeudet ja siis myös erilaisen liike-energian. Nyt kuitenkin V tai U ovat myös erilaisia, niin että kokonaisenergia E aina on sama. Suhteellisuusteorian mukaan myös aine sisältää energiaa. Energia voi vapautua aineesta esimerkiksi ydinreaktiossa. Energian hyödyntämisen tehokkuutta mitataan hyötysuhteella. In fisica l'energia è definita come la capacità di un corpo o di un sistema di compiere lavoro e la misura di questo lavoro è a sua volta la misura dell'energia. Dal punto di vista strettamente termodinamico l'energia è definita come tutto ciò che può essere trasformato in calore a bassa temperatura. Il concetto di energia nasce, nella meccanica classica, dall'osservazione sperimentale che la capacità di un sistema fisico di sviluppare una forza decade quando il sistema stesso stabilisce un'interazione con uno o più sistemi mediante la stessa forza. In questo senso l'energia può essere definita come una grandezza fisica posseduta dal sistema che può venire "consumata" per generare una forza. Dal momento che l'energia posseduta da un sistema può essere utilizzata dal sistema stesso per produrre più tipi di forze, si definisce una seconda grandezza, il lavoro appunto, che definisce il consumo di energia in relazione al processo fisico mediante il quale la forza è stata generata. エネルギー（独 Energie）は、物理学を中心に、自然科学全般で取り扱われる物理量であり、ある系が潜在的に持っている、外部に対して行うことができる仕事量のことである。エネルギーという語はドイツ語のEnergieが日本語に持ち込まれたもので、その語源となったギリシア語のἐνέργεια energeiaは「仕事」を意味する単語ἔργον ergonに前置詞enをつけたἐνεργός energosに由来する。 Energie is een natuurkundige grootheid. De SI-eenheid van energie is joule. Energie wordt vaak aangeduid als de mogelijkheid om arbeid te verrichten. Energi (fra gresk ενέργεια, styrke) er evnen til å utføre arbeid, hvor arbeid er definert som kraft anvendt gjennom en strekning. Standard vitenskapelig måleenhet for energi er joule (J). Energi kan også måles i kalorier (cal) eller kilokalorier (kcal). I sammenheng med elektrisitet brukes målenheten kilowatt-timer. Energi kan ikke bli borte eller oppstå, men bare gå over i en annen energiform.. Se: termodynamikk. Uttrykkene energi og kraft har ulik betydning i forskjellige fagfelter. I fysikken fokuseres det på å beskrive denne egenskapen kvantitativt ved en definisjon som gjør det mulig å betrakte energi både som en totaltilstand og som utført arbeid av ulike typer. Energiloven: Energi kan verken skapes eller forsvinne, kun overføres fra én energiform til en annen. Energi er en fundamental størrelse for ethvert fysisk system. Det er altså uttrykk for et potensial til å utføre mekanisk arbeid eller til å avgi varme. Tidligere ble energi beskrevet i forhold til enkle observerte effekter. For det er alltid slik at når et objekt har forandret seg, er energi blitt utvekslet med omgivelsene. Da man forstod at det som skaper endringene kan lagres i objekter, ble begrepet energi lansert som potensialet for endring samt størrelsen av endringen. Slike effekter (både potensielle og realiserte) har mange former. Eksempler: Kinetisk energi for et tog i fart Termisk energi i en varmtvannstank Kjemisk energi i mat Elektrokjemisk energi i batterier Potensiell (Stillingsenergi) i et lodd som henger over bakken Det å si at energi er endringen eller potensialet for endring, klarer ikke å beskrive alle forekomster av energi i vår fysiske verden. Energi kan både brukes til å frembringe en observerbar endring, eller til å forhindre en observerbar endring. I siste tilfelle er det klart vanskeligere å observere energioverføringen som har funnet sted. Et tikilogramslodd som er festet på en statuearm ser ikke ut til å kreve noe energi mens det henger der, men hvis du selv står og holder loddet er det tydelig at energi kreves. Du føler loddets tyngde om du beveger loddet opp og ned eller holder det i ro. Loddet får potensiell energi når du løfter det opp i jordens tyngdefelt. Når du slipper loddet går potensiell energi over til kinetisk energi (bevegelsesenergi) etterhvert som det får fart i fallet ned mot bakken. En liten andel av den potensielle energien overføres til luftens molekyler (luftmotstand) slik at disse får større gjennomsnittshastighet som igjen representerer (termisk) energiinnhold som (i teorien) kan måles som en temperaturøkning). I det loddet treffer bakken går den kinetiske energien over til termisk energi i bakken. Energia gr. ενεργεια (energeia) – skalarna wielkość fizyczna charakteryzująca stan układu fizycznego jako jego zdolność do wykonania pracy. Energia występuje w różnych postaciach np: energia kinetyczna, energia sprężystości, energia cieplna, energia jądrowa. Z punktu widzenia termodynamiki niektóre formy energii są funkcjami stanu i potencjałami termodynamicznymi. Energia i jej zmiany opisują stan i wzajemne oddziaływania obiektów fizycznych, przemiany fizyczne i chemiczne oraz wszelkiego rodzaju procesy występujące w przyrodzie. Energia jest wielkością addytywną. Energię we wzorach fizycznych zapisuje się najczęściej za pomocą symbolu E. Em ciência, definir energia não é algo trivial, e alguns autores chegam a argumentar que "a ciência não é capaz de definir energia, ao menos como um conceito independente". Contudo, mesmo para estes autores, "embora não se saiba o que é energia, se sabe o que ela não é", em clara alusão aos demais significados da palavra difundidos em senso comum, não obstante bem distintos daqueles encontrados no meio científico . Este artigo foca a acepção científica da palavra energia. Em ciência energia refere-se a uma das duas grandezas físicas necessárias à correta descrição do inter-relacionamento - sempre mútuo - entre dois entes ou sistemas físicos. A segunda grandeza é o momento. Os entes ou sistemas em interação trocam energia e momento, mas o fazem de forma que ambas as grandezas sempre obedeçam à respectiva lei de conservação. É bem difundido - não só em senso comum - que energia associa-se geralmente à capacidade de produzir um trabalho ou realizar uma ação . Em verdade a etimologia da palavra tem origem no idioma grego, onde εργος (ergos) significa "trabalho". Embora não completamente abrangente no que tange à definição de energia, esta associação não se mostra por completo fora do domínio científico, e, em princípio, qualquer ente que esteja a trabalhar - por exemplo, a mover outro objeto, a deformá-lo ou a fazê-lo ser percorrido por uma corrente eléctrica - está a "gastar" parte de sua energia, transferindo-a ao sistema sobre o qual realiza o trabalho. O conceito de energia é um dos conceitos essenciais da Física. Nascido no século XIX, desempenha papel crucial não só nesta cadeira bem como em todas as outras disciplinas que juntas integram a ciência moderna. É notoriamente relevante na química e biologia, e mesmo em economia e outras áreas de cunho social a energia destaca-se como pedra fundamental: o comércio de energia move bilhões anualmente. Pela sua importância há na Física uma subárea dedicada quase que exclusivamente ao estudo da energia: a termodinâmica. Em termodinâmica o trabalho é uma entre as duas possíveis formas de transferência de energia entre sistemas físicos; a outra forma dá-se através do calor. Predefinição:Física geral För metafysiska fenomen, se Andlig energi. Energi är en fysikalisk storhet. Energi är något som medför förändring, rörelse eller någon form av uträttat arbete. Energi kan vara lagrad (potentiell energi eller lägesenergi) eller något som överförs. Ibland avses med energi helt enkelt utfört arbete. SI-grundenheten för energi är joule (J), men även enheterna kalori (cal), voltamperesekund (V · A · s), wattimme (W · h) och elektronvolt (eV) används, mest beroende på att energi historiskt har tolkats som olika kvantiteter i olika fysikaliska sammanhang fram till 1900-talet. I SI (internationella måttenhetssystemet) används definitionen av energi och effekt tillsamman med grundenheten strömstyrka för att definiera övriga elektriska enheter. Genom detta får man ett enhetligt system av enheter där det klart framgår att elektrisk energi och till exempel mekanisk energi inte skiljer sig åt till sin natur. Den totala energin i ett slutet system bevaras alltid och kan bara överföras från en energiform till en annan och aldrig skapas eller förintas. Detta faktum – energins oförstörbarhet – kallas energiprincipen. Эне́ргия — скалярная физическая величина, являющаяся единой мерой различных форм движения материи и мерой перехода движения материи из одних форм в другие. Введение понятия энергии удобно тем, что в случае, если физическая система является замкнутой, то её энергия сохраняется во времени. Это утверждение носит название закона сохранения энергии. 能量，乃物理学中描写一个系统或一个过程的一个量，就是使物体动或变的力所做的功。一个系统的能量可以被定义为从一个被定义的零能量的状态转换为该系统现状的功的总和。一个系统到底有多少能量，在物理中并不是一个确定的值，它随着对这个系统的描写而变换。举一个例，我们观察一个1kg质量固体之能量：倘研究经典力学而只考慮动能的话，其能量，就是我们要将它从静止狀態加速到它现有速度所加的功的总和。倘研究热学而只对它的内能感兴趣的话，那么它的能量就是我们要将它从绝对零度加热到它现有温度所加的功的总和。倘研究物理化学而只对它所含有的化学能感兴趣的话，那么它的能量就是我们在合成这个個体时对它的原料加入的功的总和。倘研究原子物理学而只对它所含的原子能感兴趣的话，那么它的能量就是我们从原子能为零的状态对它做功、使它达到现在状态的功的总和。当然我们也可以用反过来的方法，来定义这物体所含的能量，两例：该固体的内能，是将它冷却到绝对零度所释放出来的功的总和。该固体的原子能，是将它所含的所有的原子能全部释放出来的功的总和。可见，能量是一个非常常用和非常基础的物理概念，但同时也是一个非常抽象和非常难定义的物理概念。事实上，物理学家一直到19世纪中才真正理解能量这个概念。在此之前能量常常被与力、动量等概念相混。有一段时间里，物理学家使用过一个称为“活力”的、与能量非常相似的概念，其意思是一种使物体活泼起来（动起来、热起来）的力。英语中的能量一词energy是两个希腊词的组合：εν是“在……之中”的意思，εργοs是“功、劳动”的意思。加在一起 en-ergi 就是“加进去的功”的意思。在物理学中，能量是最基础的一个概念之一，从开门的经典力学到宇宙学、相对论和量子力学，能量总是一个中心的概念。一般在常用语中，或在科普读物中，「能量」是指一个系统能够释放出来的、或者可以从中获得的、可以相当于做一定量的功。比如说1千克汽油含12千瓦小时能量的话，那么是指假如将1千克的汽油中的化学能全部施放出来時，可以做12kWh的功。能量在物理中的符号一般是E，其国际单位是焦耳J。除焦耳外常用的还有千瓦小时kWh和卡cal：除此之外在物理中，尤其在原子物理和粒子物理中还常使用电子伏： Fichier:Lightning over Oradea Romania 2. jpg La foudre illustre généralement l'énergie à l'état naturel. Paradoxalement elle en contient assez peu. Sa violence vient surtout de la rapidité et de l'extrême localisation du phénomène. L'énergie est la capacité d'un système à modifier un état, à produire un travail entraînant un mouvement, de la lumière ou de la chaleur. C'est une grandeur physique qui caractérise l'état d'un système et qui est d'une manière globale conservée au cours des conversions. Dans le Système international d'unités (SI), l'énergie s'exprime en joules. Dans l'industrie, on utilise la tonne d'équivalent pétrole. Dans la vie courante, on utilise le kilowatt-heure ou la calorie, et en physique des particules on utilise plutôt l'électron-volt, la conversion entre ces unités dont les ordres de grandeur diffèrent se résumant à une simple constante de proportionnalité. Le terme énergie recouvre plusieurs réalités qui se recoupent partiellement : l'énergie au sens de la science physique, l'énergie humaine, phénomène physiologique et psychologique, l'énergie utilisée par les sociétés humaines
dbpedia-owl:thumbnail	http://upload.wikimedia.org/wikipedia/commons/thumb/2/23/Lightning_over_Oradea_Romania_zoom.jpg/200px-Lightning_over_Oradea_Romania_zoom.jpg
dbpedia-owl:wikiPageExternalLink	http://www.lightandmatter.com/html_books/2cl/ch01/ch01.html#Section1.2
dcterms:subject	category:Fundamental_physics_concepts category:Energy category:State_functions category:Greek_loanwords category:Introductory_physics category:Physical_quantities
rdfs:comment	El término energía tiene diversas acepciones y definiciones, relacionadas con la idea de una capacidad para obrar, transformar o poner en movimiento. En física, «energía» se define como la capacidad para realizar un trabajo. En tecnología y economía, «energía» se refiere a un recurso natural (incluyendo a su tecnología asociada) para extraerla, transformarla, y luego darle un uso industrial o económico. エネルギー（独 Energie）は、物理学を中心に、自然科学全般で取り扱われる物理量であり、ある系が潜在的に持っている、外部に対して行うことができる仕事量のことである。エネルギーという語はドイツ語のEnergieが日本語に持ち込まれたもので、その語源となったギリシア語のἐνέργεια energeiaは「仕事」を意味する単語ἔργον ergonに前置詞enをつけたἐνεργός energosに由来する。 Energie is een natuurkundige grootheid. De SI-eenheid van energie is joule. Energie wordt vaak aangeduid als de mogelijkheid om arbeid te verrichten. Эне́ргия — скалярная физическая величина, являющаяся единой мерой различных форм движения материи и мерой перехода движения материи из одних форм в другие. Введение понятия энергии удобно тем, что в случае, если физическая система является замкнутой, то её энергия сохраняется во времени. Это утверждение носит название закона сохранения энергии. 能量，乃物理学中描写一个系统或一个过程的一个量，就是使物体动或变的力所做的功。一个系统的能量可以被定义为从一个被定义的零能量的状态转换为该系统现状的功的总和。一个系统到底有多少能量，在物理中并不是一个确定的值，它随着对这个系统的描写而变换。举一个例，我们观察一个1kg质量固体之能量：倘研究经典力学而只考慮动能的话，其能量，就是我们要将它从静止狀態加速到它现有速度所加的功的总和。倘研究热学而只对它的内能感兴趣的话，那么它的能量就是我们要将它从绝对零度加热到它现有温度所加的功的总和。倘研究物理化学而只对它所含有的化学能感兴趣的话，那么它的能量就是我们在合成这个個体时对它的原料加入的功的总和。倘研究原子物理学而只对它所含的原子能感兴趣的话，那么它的能量就是我们从原子能为零的状态对它做功、使它达到现在状态的功的总和。当然我们也可以用反过来的方法，来定义这物体所含的能量，两例：该固体的内能，是将它冷却到绝对零度所释放出来的功的总和。该固体的原子能，是将它所含的所有的原子能全部释放出来的功的总和。可见，能量是一个非常常用和非常基础的物理概念，但同时也是一个非常抽象和非常难定义的物理概念。事实上，物理学家一直到19世纪中才真正理解能量这个概念。在此之前能量常常被与力、动量等概念相混。有一段时间里，物理学家使用过一个称为“活力”的、与能量非常相似的概念，其意思是一种使物体活泼起来（动起来、热起来）的力。英语中的能量一词energy是两个希腊词的组合：εν是“在……之中”的意思，εργοs是“功、劳动”的意思。加在一起 en-ergi 就是“加进去的功”的意思。在物理学中，能量是最基础的一个概念之一，从开门的经典力学到宇宙学、相对论和量子力学，能量总是一个中心的概念。一般在常用语中，或在科普读物中，「能量」是指一个系统能够释放出来的、或者可以从中获得的、可以相当于做一定量的功。比如说1千克汽油含12千瓦小时能量的话，那么是指假如将1千克的汽油中的化学能全部施放出来時，可以做12kWh的功。能量在物理中的符号一般是E，其国际单位是焦耳J。除焦耳外常用的还有千瓦小时kWh和卡cal：除此之外在物理中，尤其在原子物理和粒子物理中还常使用电子伏： Die Energie ist eine physikalische Größe, die in allen Teilgebieten der Physik sowie in der Technik, der Chemie, der Biologie und der Wirtschaft eine zentrale Rolle spielt. Ihre SI-Einheit ist das Joule. In der theoretischen Physik wird Energie als diejenige Größe definiert, die aufgrund der Zeitinvarianz der Naturgesetze erhalten bleibt. In physics, energy is an indirectly observed quantity. It is often understood as the ability a physical system has to do work on other physical systems. Since work is defined as a force acting through a distance (a length of space), energy is always equivalent to the ability to exert pulls or pushes against the basic forces of nature, along a path of a certain length. The total energy contained in an object is identified with its mass, and energy (like mass), cannot be created or destroyed. Energia on kaikilla fysiikan aloilla keskeisessä asemassa esiintyvä suure, jota koskee yleinen säilymislaki. Energia määritellään usein voiman, kappaleen tai systeemin kyvyksi tehdä työtä. Työ taas voi esimerkiksi kiihdyttää jotakin kappaletta. Fysiikan, erityisesti termodynamiikan kehitys on kuitenkin johtanut energian käsitteen laajenemiseen, eikä tämä määritelmä mutkattomasti sovellu kaikkiin energian muotoihin. SI-järjestelmässä energian ja myös työn yksikkö on joule. In fisica l'energia è definita come la capacità di un corpo o di un sistema di compiere lavoro e la misura di questo lavoro è a sua volta la misura dell'energia. Dal punto di vista strettamente termodinamico l'energia è definita come tutto ciò che può essere trasformato in calore a bassa temperatura. Energia gr. ενεργεια (energeia) – skalarna wielkość fizyczna charakteryzująca stan układu fizycznego jako jego zdolność do wykonania pracy. Energia występuje w różnych postaciach np: energia kinetyczna, energia sprężystości, energia cieplna, energia jądrowa. Z punktu widzenia termodynamiki niektóre formy energii są funkcjami stanu i potencjałami termodynamicznymi. Energi (fra gresk ενέργεια, styrke) er evnen til å utføre arbeid, hvor arbeid er definert som kraft anvendt gjennom en strekning. Standard vitenskapelig måleenhet for energi er joule (J). Energi kan også måles i kalorier (cal) eller kilokalorier (kcal). I sammenheng med elektrisitet brukes målenheten kilowatt-timer. Energi kan ikke bli borte eller oppstå, men bare gå over i en annen energiform.. Se: termodynamikk. Uttrykkene energi og kraft har ulik betydning i forskjellige fagfelter. Em ciência, definir energia não é algo trivial, e alguns autores chegam a argumentar que "a ciência não é capaz de definir energia, ao menos como um conceito independente". Contudo, mesmo para estes autores, "embora não se saiba o que é energia, se sabe o que ela não é", em clara alusão aos demais significados da palavra difundidos em senso comum, não obstante bem distintos daqueles encontrados no meio científico . Este artigo foca a acepção científica da palavra energia. För metafysiska fenomen, se Andlig energi. Energi är en fysikalisk storhet. Energi är något som medför förändring, rörelse eller någon form av uträttat arbete. Energi kan vara lagrad (potentiell energi eller lägesenergi) eller något som överförs. Ibland avses med energi helt enkelt utfört arbete. Fichier:Lightning over Oradea Romania 2. jpg La foudre illustre généralement l'énergie à l'état naturel. Paradoxalement elle en contient assez peu. Sa violence vient surtout de la rapidité et de l'extrême localisation du phénomène. L'énergie est la capacité d'un système à modifier un état, à produire un travail entraînant un mouvement, de la lumière ou de la chaleur.
rdfs:label	Energy Energie Energia Energía Énergie Energia エネルギー Energie Energia (fizyka) Energi Energia Энергия Energi 能量
owl:sameAs	fbase:Energy
foaf:depiction	http://upload.wikimedia.org/wikipedia/commons/2/23/Lightning_over_Oradea_Romania_zoom.jpg
foaf:page	http://en.wikipedia.org/wiki/Energy
is dbpedia-owl:field of	dbpedia:Barry_Brook_(scientist) dbpedia:John_Abraham_(professor) dbpedia:Vaclav_Smil
is dbpedia-owl:genre of	dbpedia:LibRESys
is dbpedia-owl:industry of	dbpedia:Finmeccanica dbpedia:Sonat dbpedia:TECO_Energy dbpedia:Hardy_Oil_and_Gas dbpedia:Hunting_plc dbpedia:Oil_Refineries_Ltd dbpedia:Areva dbpedia:DONG_Energy dbpedia:VEBA dbpedia:Yuganskneftegaz dbpedia:The_Energy_Group dbpedia:Terasen_Gas dbpedia:Seismic_Micro-Technology dbpedia:Resun dbpedia:Oscar_Downstream dbpedia:Love's_Travel_Stops_ dbpedia:Alpiq dbpedia:Ranhill_Berhad dbpedia:Eidsiva_Energi dbpedia:Gasum dbpedia:EQT dbpedia:Mitsubishi_Corporation dbpedia:AeroVironment dbpedia:Eastern_Electricity dbpedia:Cameco dbpedia:Tokyo_Electric_Power_Company dbpedia:Atwood_Oceanics dbpedia:World_Energy_Council dbpedia:Dynegy dbpedia:Platts dbpedia:Gushan_Environmental_Energy dbpedia:Noble_Group dbpedia:International_Power dbpedia:Naftal dbpedia:Canadian_Oil_Sands dbpedia:Shenergy_Company dbpedia:AES_Corporation dbpedia:Central_Electricity_Generating_Board dbpedia:CPS_Energy dbpedia:IDT_Corporation dbpedia:Sociedad_Comercial_del_Plata dbpedia:Nova_Scotia_Power dbpedia:AGL_Energy dbpedia:Salamander_Energy dbpedia:Sime_Darby dbpedia:Maple_Energy dbpedia:National_Power_Corporation dbpedia:Neste_Oil dbpedia:National_Power dbpedia:Comgás dbpedia:Integrated_Utility_Services_UK dbpedia:Dynamotive_Energy_Systems dbpedia:Al_Ghurair dbpedia:Petrohawk dbpedia:Electrabel dbpedia:Pricelock dbpedia:Crystatech dbpedia:CE_Electric_UK dbpedia:Eesti_Energia dbpedia:SK_Group dbpedia:Vale_(mining_company) dbpedia:Anonima_Petroli_Italiana dbpedia:MFA_Oil dbpedia:STX_Corporation dbpedia:Edison_(company) dbpedia:Integrys_Energy_Group dbpedia:Oklahoma_Gas_&_Electric dbpedia:Hathor_Exploration dbpedia:Paz_Oil_Company dbpedia:Direct_Energy dbpedia:Solar_Millennium dbpedia:Melrose_Resources dbpedia:Sabah_Electricity dbpedia:Transnational_Corporation_of_Nigeria dbpedia:American_Light_and_Traction dbpedia:AREVA_Resources_Canada dbpedia:Chr._Salvesen_ dbpedia:Muthoot dbpedia:Shenergy_Group dbpedia:Paladin_Energy dbpedia:Scotia_Gas_Networks dbpedia:Nord_Stream_AG dbpedia:Hidroelectrica dbpedia:Wales_&_West_Utilities dbpedia:Raízen dbpedia:Sertco dbpedia:J-W_Energy_Company dbpedia:Walter_Energy dbpedia:Unión_Fenosa dbpedia:Imperial_Energy_Corporation dbpedia:Heritage_Oil dbpedia:Avista dbpedia:Laborelec dbpedia:Trondhjems_Elektricitetsværk_og_Sporvei dbpedia:Tsinghua_Tongfang_Company dbpedia:Energylinx dbpedia:On-Ramp_Wireless dbpedia:Dana_Petroleum dbpedia:Tokyo_Gas dbpedia:Enron_scandal dbpedia:Challenger_LTD dbpedia:Venture_Production dbpedia:Recycled_Energy_Development dbpedia:Stone_Bond_Technologies dbpedia:Walchandnagar_Industries dbpedia:Atlas_America dbpedia:PCC_Group dbpedia:GE_Energy dbpedia:The_Shaksy_Group dbpedia:Natur-Energi dbpedia:China_Clean_Energy dbpedia:Eaga dbpedia:Energinet.dk dbpedia:Elektroprivreda_Bosne_i_Hercegovine dbpedia:Kedco dbpedia:Global_Clean_Energy_Holdings dbpedia:MXenergy dbpedia:Expro_International_Group dbpedia:MSPL_Limited dbpedia:Israel_Corporation dbpedia:Nalcor_Energy dbpedia:Maritime_Electric dbpedia:Elering
is dbpedia-owl:nonFictionSubject of	dbpedia:Gusher_of_Lies dbpedia:Power_Hungry dbpedia:Pipe_Dreams:_Greed,_Ego,_and_the_Death_of_Enron
is dbpedia-owl:product of	dbpedia:Koch_Industries dbpedia:Arta_Industrial_Group dbpedia:Roper_Industries dbpedia:Alpiq dbpedia:CCS_Midstream_Services dbpedia:Mahindra_Group dbpedia:Sherritt_International dbpedia:Vattenfall dbpedia:AGL_Energy dbpedia:Osaka_Gas dbpedia:Industrial_Promotion_Services dbpedia:Enerflex dbpedia:Catlin_Group dbpedia:Industrial_Development_and_Renovation_Organization_of_Iran dbpedia:Transnational_Corporation_of_Nigeria dbpedia:Inversiones_Argos dbpedia:Welspun_Group dbpedia:Tinfos dbpedia:Cofra_Group dbpedia:China_Merchants_Energy_Shipping dbpedia:American_Clean_Skies_Foundation dbpedia:Votorantim_Group dbpedia:Singapore_Mercantile_Exchange dbpedia:Manila_Commodity_Exchange
is dbpedia-owl:service of	dbpedia:Garrigues_(law_firm) dbpedia:Watson,_Farley_&_Williams dbpedia:Bracewell_&_Giuliani dbpedia:Mouchel dbpedia:GAI_Consultants,_Inc.
is dbpedia-owl:type of	dbpedia:Puget_Sound_Energy
is dbpedia-owl:wikiPageDisambiguates of	dbpedia:NRG dbpedia:Energetic_(disambiguation) dbpedia:Energy_(disambiguation)
is dbpedia-owl:wikiPageRedirects of	dbpedia:Effort dbpedia:Energetic dbpedia:Energies dbpedia:Energy_(natural_science) dbpedia:Total_energy dbpedia:Energy_(biology) dbpedia:Energy(Biology) dbpedia:Energy_(cosmology) dbpedia:Energy_form dbpedia:Energy_(physics) dbpedia:Energy_(chemistry) dbpedia:Energy_(earth_science) dbpedia:Energy(Chemistry) dbpedia:Energy(Earth_Sciences) dbpedia:Energy_(Earth_science) dbpedia:Energy_forms dbpedia:Physical_energy dbpedia:Molar_energy dbpedia:Energy_(physical) dbpedia:Energetically dbpedia:Energizations dbpedia:Energisations dbpedia:Reenergizes dbpedia:Reenergized dbpedia:Reenergizer dbpedia:Reenergizational dbpedia:Reenergises dbpedia:Reenergised dbpedia:Reenergiser dbpedia:Reenergisational dbpedia:Re-energize dbpedia:Re-energizing dbpedia:Re-energizers dbpedia:Re-energise dbpedia:Re-energising dbpedia:Re-energisers dbpedia:Energizes dbpedia:Energized_(physics) dbpedia:Energizing dbpedia:Energises dbpedia:Energising dbpedia:Energizers dbpedia:Energisers dbpedia:Reenergize dbpedia:Reenergizations dbpedia:Reenergise dbpedia:Reenergisations dbpedia:Re-energization dbpedia:Re-energisation dbpedia:Energization dbpedia:Energisation dbpedia:Reenergizing dbpedia:Reenergizers dbpedia:Reenergising dbpedia:Reenergisers dbpedia:Re-energizes dbpedia:Re-energized dbpedia:Re-energizer dbpedia:Re-energizational dbpedia:Re-energises dbpedia:Re-energised dbpedia:Re-energiser dbpedia:Re-energisational dbpedia:Energy_physics dbpedia:Energize dbpedia:Energise dbpedia:Energizer_(physics) dbpedia:Energizational dbpedia:Energisational dbpedia:Reenergization dbpedia:Reenergisation dbpedia:Re-energizations dbpedia:Re-energisations
is dbpprop:aux of	dbpedia:List_of_The_Magic_School_Bus_episodes
is dbpprop:data of	dbpedia:SmartPlanet
is dbpprop:field of	dbpedia:Barry_Brook_(scientist) dbpedia:Vaclav_Smil
is dbpprop:focus of	dbpedia:Energy_Cities
is dbpprop:genre of	dbpedia:LibRESys
is dbpprop:industry of	dbpedia:Finmeccanica dbpedia:Sonat dbpedia:TECO_Energy dbpedia:Hardy_Oil_and_Gas dbpedia:Hunting_plc dbpedia:Oil_Refineries_Ltd dbpedia:Areva dbpedia:DONG_Energy dbpedia:VEBA dbpedia:Yuganskneftegaz dbpedia:The_Energy_Group dbpedia:Terasen_Gas dbpedia:Seismic_Micro-Technology dbpedia:Resun dbpedia:Oscar_Downstream dbpedia:Love's_Travel_Stops_ dbpedia:Alpiq dbpedia:Ranhill_Berhad dbpedia:Eidsiva_Energi dbpedia:Gasum dbpedia:EQT dbpedia:Mitsubishi_Corporation dbpedia:AeroVironment dbpedia:Eastern_Electricity dbpedia:Cameco dbpedia:Tokyo_Electric_Power_Company dbpedia:Atwood_Oceanics dbpedia:World_Energy_Council dbpedia:Platts dbpedia:Gushan_Environmental_Energy dbpedia:Noble_Group dbpedia:International_Power dbpedia:Naftal dbpedia:Canadian_Oil_Sands dbpedia:Shenergy_Company dbpedia:AES_Corporation dbpedia:Central_Electricity_Generating_Board dbpedia:CPS_Energy dbpedia:IDT_Corporation dbpedia:Sociedad_Comercial_del_Plata dbpedia:Nova_Scotia_Power dbpedia:AGL_Energy dbpedia:Salamander_Energy dbpedia:Maple_Energy dbpedia:National_Power_Corporation dbpedia:Neste_Oil dbpedia:National_Power dbpedia:Comgás dbpedia:Integrated_Utility_Services_UK dbpedia:Dynamotive_Energy_Systems dbpedia:Al_Ghurair dbpedia:Electrabel dbpedia:Pricelock dbpedia:Crystatech dbpedia:CE_Electric_UK dbpedia:Eesti_Energia dbpedia:Vale_(mining_company) dbpedia:Anonima_Petroli_Italiana dbpedia:MFA_Oil dbpedia:STX_Corporation dbpedia:Edison_(company) dbpedia:Integrys_Energy_Group dbpedia:Oklahoma_Gas_&_Electric dbpedia:Paz_Oil_Company dbpedia:Direct_Energy dbpedia:Solar_Millennium dbpedia:Melrose_Resources dbpedia:Sabah_Electricity dbpedia:Transnational_Corporation_of_Nigeria dbpedia:American_Light_and_Traction dbpedia:AREVA_Resources_Canada dbpedia:Chr._Salvesen_ dbpedia:Shenergy_Group dbpedia:Paladin_Energy dbpedia:Scotia_Gas_Networks dbpedia:Nord_Stream_AG dbpedia:Hidroelectrica dbpedia:Wales_&_West_Utilities dbpedia:Raízen dbpedia:Sertco dbpedia:J-W_Energy_Company dbpedia:Walter_Energy dbpedia:Unión_Fenosa dbpedia:Imperial_Energy_Corporation dbpedia:Heritage_Oil dbpedia:Avista dbpedia:Laborelec dbpedia:Tsinghua_Tongfang_Company dbpedia:On-Ramp_Wireless dbpedia:Dana_Petroleum dbpedia:Tokyo_Gas dbpedia:Challenger_LTD dbpedia:Venture_Production dbpedia:Recycled_Energy_Development dbpedia:Walchandnagar_Industries dbpedia:Atlas_America dbpedia:PCC_Group dbpedia:GE_Energy dbpedia:The_Shaksy_Group dbpedia:Natur-Energi dbpedia:Eaga dbpedia:Energinet.dk dbpedia:Elektroprivreda_Bosne_i_Hercegovine dbpedia:Global_Clean_Energy_Holdings dbpedia:MXenergy dbpedia:Expro_International_Group dbpedia:MSPL_Limited dbpedia:Nalcor_Energy dbpedia:Maritime_Electric dbpedia:Elering
is dbpprop:products of	dbpedia:Koch_Industries dbpedia:Arta_Industrial_Group dbpedia:Alpiq dbpedia:Mahindra_Group dbpedia:AGL_Energy dbpedia:Osaka_Gas dbpedia:Industrial_Promotion_Services dbpedia:Industrial_Development_and_Renovation_Organization_of_Iran dbpedia:Inversiones_Argos dbpedia:Welspun_Group dbpedia:Cofra_Group dbpedia:China_Merchants_Energy_Shipping dbpedia:Votorantim_Group
is dbpprop:quantity of	dbpedia:Joule
is dbpprop:sectors of	dbpedia:Economy_of_Spain
is dbpprop:services of	dbpedia:GAI_Consultants,_Inc.
is dbpprop:subject of	dbpedia:Gusher_of_Lies dbpedia:Power_Hungry dbpedia:Pipe_Dreams:_Greed,_Ego,_and_the_Death_of_Enron
is dbpprop:title of	dbpedia:Simon_D'Ujanga
is dbpprop:type of	dbpedia:Puget_Sound_Energy
is owl:sameAs of	http://www4.wiwiss.fu-berlin.de/flickrwrappr/photos/Energy
is foaf:primaryTopic of	http://en.wikipedia.org/wiki/Energy