@prefix dbo: .
@prefix dbr: .
dbr:Interstellar_medium dbo:wikiPageWikiLink dbr:Energy_level .
dbo:wikiPageWikiLink dbr:Energy_level .
dbr:Francium dbo:wikiPageWikiLink dbr:Energy_level .
dbr:Excited_state dbo:wikiPageWikiLink dbr:Energy_level .
dbo:wikiPageWikiLink dbr:Energy_level .
dbr:Internal_energy dbo:wikiPageWikiLink dbr:Energy_level .
dbr:Electron_configuration dbo:wikiPageWikiLink dbr:Energy_level .
dbr:Atomic_electron_transition dbo:wikiPageWikiLink dbr:Energy_level .
dbr:Electromagnetic_cavity dbo:wikiPageWikiLink dbr:Energy_level .
dbr:Megamaser dbo:wikiPageWikiLink dbr:Energy_level .
dbr:Valley_of_stability dbo:wikiPageWikiLink dbr:Energy_level .
dbo:wikiPageWikiLink dbr:Energy_level .
dbr:Timeline_of_quantum_mechanics dbo:wikiPageWikiLink dbr:Energy_level .
dbr:Transparency_and_translucency dbo:wikiPageWikiLink dbr:Energy_level .
dbr:Atomic_orbital dbo:wikiPageWikiLink dbr:Energy_level .
dbr:Atomic_clock dbo:wikiPageWikiLink dbr:Energy_level .
@prefix foaf: .
@prefix wikipedia-en: .
wikipedia-en:Energy_level foaf:primaryTopic dbr:Energy_level .
dbr:Planetary_nebula dbo:wikiPageWikiLink dbr:Energy_level .
dbr:Outline_of_electronics dbo:wikiPageWikiLink dbr:Energy_level .
dbr:Vacuum_level dbo:wikiPageWikiLink dbr:Energy_level .
dbo:wikiPageWikiLink dbr:Energy_level .
dbr:Molecular_orbital_diagram dbo:wikiPageWikiLink dbr:Energy_level .
dbr:Non-bonding_orbital dbo:wikiPageWikiLink dbr:Energy_level .
dbr:Rotational_spectroscopy dbo:wikiPageWikiLink dbr:Energy_level .
dbr:Electron_excitation dbo:wikiPageWikiLink dbr:Energy_level .
dbr:Energy_operator dbo:wikiPageWikiLink dbr:Energy_level .
dbo:wikiPageWikiLink dbr:Energy_level .
dbo:wikiPageWikiLink dbr:Energy_level .
dbr:Electronic_state dbo:wikiPageWikiLink dbr:Energy_level ;
dbo:wikiPageRedirects dbr:Energy_level .
dbr:Degenerate_energy_levels dbo:wikiPageWikiLink dbr:Energy_level .
dbr:Anode_ray dbo:wikiPageWikiLink dbr:Energy_level .
dbo:wikiPageWikiLink dbr:Energy_level .
dbr:Hydrogen_anion dbo:wikiPageWikiLink dbr:Energy_level .
dbr:Hydrogen_spectral_series dbo:wikiPageWikiLink dbr:Energy_level .
dbo:wikiPageWikiLink dbr:Energy_level .
dbr:Characteristic_X-ray dbo:wikiPageWikiLink dbr:Energy_level .
dbr:Deep-level_transient_spectroscopy dbo:wikiPageWikiLink dbr:Energy_level .
dbr:Deuterium_arc_lamp dbo:wikiPageWikiLink dbr:Energy_level .
dbr:Dunham_expansion dbo:wikiPageWikiLink dbr:Energy_level .
dbo:wikiPageWikiLink dbr:Energy_level .
dbr:Rydberg_atom dbo:wikiPageWikiLink dbr:Energy_level .
dbr:ONIOM dbo:wikiPageWikiLink dbr:Energy_level .
dbr:Nuclear_acoustic_resonance dbo:wikiPageWikiLink dbr:Energy_level .
dbr:Nuclear_magnetic_moment dbo:wikiPageWikiLink dbr:Energy_level .
dbr:Thermally_stimulated_current_spectroscopy dbo:wikiPageWikiLink dbr:Energy_level .
dbr:Quantum_level dbo:wikiPageWikiLink dbr:Energy_level .
dbr:Chemiosmosis dbo:wikiPageWikiLink dbr:Energy_level .
dbr:X-ray_filter dbo:wikiPageWikiLink dbr:Energy_level .
dbr:Rabi_frequency dbo:wikiPageWikiLink dbr:Energy_level .
dbr:Elbe_Sluice dbo:wikiPageWikiLink dbr:Energy_level .
dbr:Energy_level_splitting dbo:wikiPageWikiLink dbr:Energy_level .
dbr:Future_of_an_expanding_universe dbo:wikiPageWikiLink dbr:Energy_level .
dbr:Crystallographic_defects_in_diamond dbo:wikiPageWikiLink dbr:Energy_level .
dbr:Oscillator_strength dbo:wikiPageWikiLink dbr:Energy_level .
dbr:Chip-scale_atomic_clock dbo:wikiPageWikiLink dbr:Energy_level .
dbo:wikiPageWikiLink dbr:Energy_level .
dbr:Polythiophene dbo:wikiPageWikiLink dbr:Energy_level .
dbr:Vibronic_spectroscopy dbo:wikiPageWikiLink dbr:Energy_level .
dbr:Adiabatic_theorem dbo:wikiPageWikiLink dbr:Energy_level .
dbr:Heavy_Rydberg_system dbo:wikiPageWikiLink dbr:Energy_level .
dbr:Rendering_equation dbo:wikiPageWikiLink dbr:Energy_level .
dbr:Cyclopropenylidene dbo:wikiPageWikiLink dbr:Energy_level .
dbo:wikiPageWikiLink dbr:Energy_level .
dbr:Balmer_jump dbo:wikiPageWikiLink dbr:Energy_level .
dbr:Pandya_theorem dbo:wikiPageWikiLink dbr:Energy_level .
dbr:Diffuse_interstellar_bands dbo:wikiPageWikiLink dbr:Energy_level .
dbr:Glycerol_and_potassium_permanganate dbo:wikiPageWikiLink dbr:Energy_level .
dbo:wikiPageWikiLink dbr:Energy_level .
dbr:History_of_watches dbo:wikiPageWikiLink dbr:Energy_level .
dbr:Energy_Level dbo:wikiPageWikiLink dbr:Energy_level ;
dbo:wikiPageRedirects dbr:Energy_level .
dbr:Power_level dbo:wikiPageWikiLink dbr:Energy_level .
dbr:Quantum_dot_cellular_automaton dbo:wikiPageWikiLink dbr:Energy_level .
dbr:Quantum_jump dbo:wikiPageWikiLink dbr:Energy_level .
dbr:Vibrational_energy_relaxation dbo:wikiPageWikiLink dbr:Energy_level .
dbr:Intersubband_polariton dbo:wikiPageWikiLink dbr:Energy_level .
dbr:Hydrophobic_collapse dbo:wikiPageWikiLink dbr:Energy_level .
dbr:Spectral_line_ratios dbo:wikiPageWikiLink dbr:Energy_level .
dbr:Chiral_anomaly dbo:wikiPageWikiLink dbr:Energy_level .
dbr:Laurdan dbo:wikiPageWikiLink dbr:Energy_level .
dbr:Biophoton dbo:wikiPageWikiLink dbr:Energy_level .
dbo:wikiPageWikiLink dbr:Energy_level .
dbr:Tight_binding dbo:wikiPageWikiLink dbr:Energy_level .
dbr:X-ray_optics dbo:wikiPageWikiLink dbr:Energy_level .
dbr:Planck_relation dbo:wikiPageWikiLink dbr:Energy_level .
dbr:Positronium dbo:wikiPageWikiLink dbr:Energy_level .
dbr:Fermi_point dbo:wikiPageWikiLink dbr:Energy_level .
dbr:Fine_electronic_structure dbo:wikiPageWikiLink dbr:Energy_level .
dbr:Grotrian_diagram dbo:wikiPageWikiLink dbr:Energy_level .
dbo:wikiPageWikiLink dbr:Energy_level .
dbr:Energy_State dbo:wikiPageWikiLink dbr:Energy_level ;
dbo:wikiPageRedirects dbr:Energy_level .
dbo:wikiPageWikiLink dbr:Energy_level ;
dbo:wikiPageRedirects dbr:Energy_level .
dbr:Energy_state dbo:wikiPageWikiLink dbr:Energy_level ;
dbo:wikiPageRedirects dbr:Energy_level .
dbr:Nanocluster dbo:wikiPageWikiLink dbr:Energy_level .
dbo:wikiPageWikiLink dbr:Energy_level .
dbr:Surface_acoustic_wave dbo:wikiPageWikiLink dbr:Energy_level .
dbo:wikiPageWikiLink dbr:Energy_level .
dbr:Molecular_electronic_transition dbo:wikiPageWikiLink dbr:Energy_level .
dbr:Molecular_entity dbo:wikiPageWikiLink dbr:Energy_level .
dbr:Thiolate-protected_gold_cluster dbo:wikiPageWikiLink dbr:Energy_level .
dbr:The_Quality_of_Life_Assessment_of_Growth_Hormone_Deficiency_in_Adults_Measure dbo:wikiPageWikiLink dbr:Energy_level .
dbo:wikiPageWikiLink dbr:Energy_level .
dbr:Non-degenerate_two-photon_absorption dbo:wikiPageWikiLink dbr:Energy_level .
dbr:Period_4_element dbo:wikiPageWikiLink dbr:Energy_level .
dbr:Quantum_dot_display dbo:wikiPageWikiLink dbr:Energy_level .
dbr:P680 dbo:wikiPageWikiLink dbr:Energy_level .
dbr:P700 dbo:wikiPageWikiLink dbr:Energy_level .
dbr:Two-dimensional_electron_gas dbo:wikiPageWikiLink dbr:Energy_level .
dbr:Spin_qubit_quantum_computer dbo:wikiPageWikiLink dbr:Energy_level .
dbr:Quantized_electronic_structure dbo:wikiPageWikiLink dbr:Energy_level ;
dbo:wikiPageRedirects dbr:Energy_level .
dbr:Quantized_energy_levels_of_atoms dbo:wikiPageWikiLink dbr:Energy_level ;
dbo:wikiPageRedirects dbr:Energy_level .
dbr:Quantum_Energy dbo:wikiPageWikiLink dbr:Energy_level ;
dbo:wikiPageRedirects dbr:Energy_level .
dbr:Quantum_energy_level dbo:wikiPageWikiLink dbr:Energy_level ;
dbo:wikiPageRedirects dbr:Energy_level .
dbr:Quantum_levels dbo:wikiPageWikiLink dbr:Energy_level ;
dbo:wikiPageRedirects dbr:Energy_level .
dbr:Atomic_energy_level dbo:wikiPageWikiLink dbr:Energy_level ;
dbo:wikiPageRedirects dbr:Energy_level .
dbr:Molecular_energy_state dbo:wikiPageWikiLink dbr:Energy_level ;
dbo:wikiPageRedirects dbr:Energy_level .
dbr:Magnetic_susceptibility dbo:wikiPageWikiLink dbr:Energy_level .
dbo:wikiPageWikiLink dbr:Energy_level .
dbr:Atom dbo:wikiPageWikiLink dbr:Energy_level .
dbr:Hydrogen dbo:wikiPageWikiLink dbr:Energy_level .
dbr:Nanoparticle dbo:wikiPageWikiLink dbr:Energy_level .
dbr:Energy dbo:wikiPageWikiLink dbr:Energy_level .
dbr:Alkali_metal dbo:wikiPageWikiLink dbr:Energy_level .
dbr:Cathode_ray dbo:wikiPageWikiLink dbr:Energy_level .
dbr:Umesh_Waghmare dbo:wikiPageWikiLink dbr:Energy_level .
dbr:Shallow_donor dbo:wikiPageWikiLink dbr:Energy_level .
dbr:Selective_adsorption dbo:wikiPageWikiLink dbr:Energy_level .
dbr:Superconducting_quantum_computing dbo:wikiPageWikiLink dbr:Energy_level .
dbr:Gas dbo:wikiPageWikiLink dbr:Energy_level .
dbr:Neutron dbo:wikiPageWikiLink dbr:Energy_level .
dbr:Zero-point_energy dbo:wikiPageWikiLink dbr:Energy_level .
dbr:Proton dbo:wikiPageWikiLink dbr:Energy_level .
dbr:Type_II_supernova dbo:wikiPageWikiLink dbr:Energy_level .
dbr:Dual-energy_X-ray_absorptiometry dbo:wikiPageWikiLink dbr:Energy_level .
dbr:Clock dbo:wikiPageWikiLink dbr:Energy_level .
dbr:Diffraction dbo:wikiPageWikiLink dbr:Energy_level .
dbr:X-ray_crystallography dbo:wikiPageWikiLink dbr:Energy_level .
dbr:Molecular_orbital_theory dbo:wikiPageWikiLink dbr:Energy_level .
dbr:H_II_region dbo:wikiPageWikiLink dbr:Energy_level .
@prefix rdf: .
@prefix owl: .
dbr:Energy_level rdf:type owl:Thing .
@prefix yago: .
dbr:Energy_level rdf:type yago:Property104916342 ,
yago:Abstraction100002137 ,
yago:ChemicalProperty105009758 ,
yago:WikicatChemicalProperties ,
yago:Attribute100024264 .
@prefix rdfs: .
dbr:Energy_level rdfs:label "\u0645\u0633\u062A\u0648\u0649 \u0637\u0627\u0642\u0629"@ar ,
"Nivel energ\u00E9tico"@es ,
"N\u00EDvel de energia"@pt ,
"Tingkat energi"@in ,
"Poziom energetyczny"@pl ,
"Nivell d'energia"@ca ,
"Energinivelo"@eo ,
"Energieniveau"@de ,
"\uC5D0\uB108\uC9C0 \uC900\uC704"@ko ,
"Niveau d'\u00E9nergie"@fr ,
"\u042D\u043D\u0435\u0440\u0433\u0435\u0442\u0438\u0447\u0435\u0441\u043A\u0438\u0439 \u0443\u0440\u043E\u0432\u0435\u043D\u044C"@ru ,
"Leibh\u00E9al fuinnimh"@ga ,
"Energieniveau"@nl ,
"Energy level"@en ,
"\u30A8\u30CD\u30EB\u30AE\u30FC\u6E96\u4F4D"@ja ,
"\u0415\u043D\u0435\u0440\u0433\u0435\u0442\u0438\u0447\u043D\u0438\u0439 \u0440\u0456\u0432\u0435\u043D\u044C"@uk ,
"\u80FD\u7EA7"@zh ,
"Livello energetico"@it ,
"Energiniv\u00E5"@sv ;
rdfs:comment "Dalam fisika, tingkat energi (energy level atau energy state) adalah besar energi tertentu yang dapat dimiliki sebuah atom, inti atom, atau partikel subatom yang terikat pada ruang tertentu. Menurut mekanika kuantum, partikel atau sistem tersebut tidak dapat memiliki energi dengan besar sembarang, tetapi hanya bisa memiliki salah satu dari beberapa \"tingkat\" dengan energi berbeda. Tingkat terendah disebut keadaan dasar atau tingkat dasar (ground state) dan tingkat-tingkat diatasnya disebut tingkat eksitasi atau keadaan terekistasi."@in ,
"Poziom energetyczny \u2013 energia stanu dost\u0119pnego dla cz\u0105stki. Poziom mo\u017Ce by\u0107 zdegenerowany, je\u015Bli dana warto\u015B\u0107 energii cechuje wi\u0119cej ni\u017C jeden stan kwantowy."@pl ,
"Ein Energieniveau ist die diskrete Energie, die als Energieeigenzustand zu einem quantenmechanischen Zustand eines Systems (etwa eines Atoms oder eines Atomkerns) geh\u00F6rt. Energieniveaus sind Eigenwerte des Hamilton-Operators, sie sind deshalb zeitunabh\u00E4ngig. Das System kann sich dauerhaft nur in einem dieser Zust\u00E4nde, aber nicht bei anderen, dazwischen liegenden Werten der Energie \u201Eaufhalten\u201C. Das tiefste Energieniveau wird als Grundzustand bezeichnet (bzw. im Falle von Entartung als \"Grundzust\u00E4nde\"), alle anderen Niveaus hei\u00DFen angeregte Zust\u00E4nde."@de ,
"Energinivelo estas kiu apartenas al kvantuma stato de sistemo (precipe de atomo) je certa energio (energistato). Energiniveloj estas permesitaj de la , ili do estas temposendependaj. Energi-preno kaj -dono en la sistemo povas okazi nur per alia energinivelo. Tio ekzemple povas okazi per a\u016D radiado de fotono kun la adekvata energio. Tio rezultigas diskretajn spektrajn liniojn en la radiada spektro. Aldoni\u011Das tamen ankora\u016D fajnstruktura kaj korektoj kaj la ."@eo ,
"\uC5D0\uB108\uC9C0 \uC900\uC704(Energy \u6E96\u4F4D)\uB294 \uC6D0\uC790\uC640 \uBD84\uC790\uAC00 \uAC16\uB294 \uC5D0\uB108\uC9C0\uC758 \uAC12\uC774\uB2E4. \uBCF4\uC5B4\uC758 \uC6D0\uC790 \uBAA8\uD615\uC5D0\uC11C \uC804\uC790\uAC00 \uC5D0\uB108\uC9C0\uB97C \uBC1B\uC544 \uC704\uCE58\uB97C \uBC14\uAFB8\uBA74, \uC774 \uC704\uCE58\uB4E4\uC774 \uC5D0\uB108\uC9C0 \uC900\uC704\uC774\uB2E4. \uACE0\uC804 \uBB3C\uB9AC\uD559\uC5D0 \uBAA8\uC21C\uB418\uB294 \uC774 \uAC1C\uB150\uC744 \uB3C4\uC785\uD568\uC73C\uB85C\uC368 \uBCF4\uC5B4\uB294 \uC218\uC18C \uC6D0\uC790\uC758 \uC120 \uC2A4\uD399\uD2B8\uB7FC\uC744 \uC124\uBA85\uD560 \uC218 \uC788\uC5C8\uB2E4."@ko ,
"Un nivell d'energia o nivell energ\u00E8tic \u00E9s una quantitat estable d'energia, que un sistema f\u00EDsic pot tenir; el terme s'utilitza m\u00E9s comunament fent refer\u00E8ncia a la configuraci\u00F3 electr\u00F2nica d'electrons, en \u00E0toms o mol\u00E8cules. Segons la teoria qu\u00E0ntica, nom\u00E9s certs nivells d'energia s\u00F3n possibles; com m\u00E9s alt \u00E9s el nivell energ\u00E8tic on l'electr\u00F3 est\u00E0 situat, m\u00E9s gran \u00E9s la seva energia potencial. El conjunt de tots els nivells energ\u00E8tics d'un sistema s'anomena espectre energ\u00E8tic Les energies espec\u00EDfiques d'aquests components depenen de l'estat energ\u00E8tic on estigui l'electr\u00F3 i de la subst\u00E0ncia."@ca ,
"\u80FD\u7EA7\uFF08\u82F1\u8A9E\uFF1Aenergy level\uFF09\u53C8\u79F0\u80FD\u9636\uFF0C\u662F\u63CF\u8FF0\u5FAE\u89C2\u7C92\u5B50\u4F53\u7CFB\uFF08\u539F\u5B50\u3001\u7535\u5B50\u3001\u5206\u5B50\u7B49\uFF09\u53EF\u80FD\u5B58\u5728\u7684\u76F8\u5BF9\u7A33\u5B9A\u72B6\u6001\u4E0B\uFF0C\u6240\u5BF9\u5E94\u4E00\u7CFB\u5217\u4E0D\u8FDE\u7EED\u7684\u3001\u5206\u7ACB\u7684\u4E14\u786E\u5B9A\u7684\u201C\u5185\u5728\u201D\u80FD\u91CF\u503C\u6216\u72B6\u6001\u3002 \u80FD\u7EA7\u7406\u8BBA\u5219\u662F\u4E00\u79CD\u89E3\u91CA\u539F\u5B50\u6838\u5916\u7535\u5B50\u8FD0\u52A8\u8F68\u9053\u7684\u7406\u8BBA\u3002\u5B83\u8BA4\u4E3A\u7535\u5B50\u53EA\u80FD\u5728\u7279\u5B9A\u7684\u3001\u5206\u7ACB\u7684\u8F68\u9053\u4E0A\u8FD0\u52A8\uFF0C\u5404\u4E2A\u8F68\u9053\u4E0A\u7684\u7535\u5B50\u5177\u6709\u5206\u7ACB\u7684\u80FD\u91CF\uFF0C\u8FD9\u4E9B\u80FD\u91CF\u503C\u5373\u4E3A\u80FD\u7EA7\u3002\u7531\u4E8E\u8DDD\u539F\u5B50\u6838\u8D8A\u8FDC\u7684\u7535\u5B50\u8D8A\u4E0D\u53D7\u675F\u7F1A\uFF0C\u56E0\u6B64\u5176\u80FD\u7EA7\u8D8A\u9AD8\uFF0C\u8BE5\u7535\u5B50\u5177\u6709\u8D8A\u591A\u7684\u7535\u5B50\u80FD\u91CF\u3002 \u7535\u5B50\u53EF\u4EE5\u5728\u4E0D\u540C\u7684\u8F68\u9053\u95F4\u53D1\u751F\u8DC3\u8FC1\uFF0C\u7535\u5B50\u5438\u6536\u80FD\u91CF\u53EF\u4EE5\u4ECE\u4F4E\u80FD\u7EA7\u8DC3\u8FC1\u5230\u9AD8\u80FD\u7EA7\u6216\u8005\u4ECE\u9AD8\u80FD\u7EA7\u8DC3\u8FC1\u5230\u4F4E\u80FD\u7EA7\u4ECE\u800C\u8F90\u5C04\u51FA\u5149\u5B50\u3002\u6C22\u539F\u5B50\u7684\u80FD\u7EA7\u53EF\u4EE5\u7531\u5B83\u7684\u5149\u8C31\u663E\u793A\u51FA\u6765\u3002"@zh ,
"\u30A8\u30CD\u30EB\u30AE\u30FC\u6E96\u4F4D\uFF08\u30A8\u30CD\u30EB\u30AE\u30FC\u3058\u3085\u3093\u3044\u3001\u82F1: energy level\uFF09\u3068\u306F\u3001\u7CFB\u306E\u30A8\u30CD\u30EB\u30AE\u30FC\u306E\u6E2C\u5B9A\u5024\u3068\u3057\u3066\u3042\u308A\u5F97\u308B\u5024\u3001\u3064\u307E\u308A\u305D\u306E\u7CFB\u306E\u30CF\u30DF\u30EB\u30C8\u30CB\u30A2\u30F3\u306E\u56FA\u6709\u5024\u3092\u4E26\u3079\u305F\u3082\u306E\u3067\u3042\u308B\u3002 \u305D\u308C\u305E\u308C\u306E\u30A8\u30CD\u30EB\u30AE\u30FC\u6E96\u4F4D\u306F\u3001\u91CF\u5B50\u6570\u3084\u9805\u8A18\u53F7\u306A\u3069\u3067\u533A\u5225\u3055\u308C\u308B"@ja ,
"A quantum mechanical system or particle that is bound\u2014that is, confined spatially\u2014can only take on certain discrete values of energy, called energy levels. This contrasts with classical particles, which can have any amount of energy. The term is commonly used for the energy levels of the electrons in atoms, ions, or molecules, which are bound by the electric field of the nucleus, but can also refer to energy levels of nuclei or vibrational or rotational energy levels in molecules. The energy spectrum of a system with such discrete energy levels is said to be quantized."@en ,
"In meccanica quantistica, i livelli energetici di un sistema sono i determinati valori discreti dell'energia che sono accessibili al sistema. Questo \u00E8 in contrasto con la meccanica classica, dove l'energia pu\u00F2 assumere ogni valore. Sin dalle origini della chimica come scienza era stato osservato che l'assorbimento della luce da parte dei gas non varia in maniera morbida con la lunghezza d'onda ma \u00E8 caratterizzato dalla presenza di un gran numero di picchi estremamente sottili e disposti in maniera complicata. ."@it ,
"\u0633\u0648\u064A\u0629 \u0623\u0648 \u0645\u0633\u062A\u0648\u0649 \u0627\u0644\u0637\u0627\u0642\u0629 \u0641\u064A \u0627\u0644\u0641\u064A\u0632\u064A\u0627\u0621 \u0627\u0644\u0630\u0631\u064A\u0629 \u0648\u0627\u0644\u0641\u064A\u0632\u064A\u0627\u0621 \u0627\u0644\u062C\u0632\u064A\u0626\u064A\u0629 \u0648\u0643\u064A\u0645\u064A\u0627\u0621 \u0627\u0644\u0643\u0645\u060C \u0647\u064A \u0645\u062F\u0627\u0631\u0627\u062A \u0648\u0647\u0645\u064A\u0629 \u0644\u062D\u0627\u0644\u0629 \u062A\u0631\u0627\u0628\u0637 \u0628\u064A\u0646 \u062C\u064A\u0633\u0645\u064A\u0646 \u0641\u064A \u0645\u064A\u0643\u0627\u0646\u064A\u0643\u0627 \u0627\u0644\u0643\u0645 \u0645\u062B\u0644 \u062D\u0627\u0644\u0629 \u0627\u0644\u0625\u0644\u0643\u062A\u0631\u0648\u0646 \u0627\u0644\u0645\u0631\u062A\u0628\u0637 \u0628\u0627\u0644\u0630\u0631\u0629 \u0648\u064A\u062F\u0648\u0631 \u062D\u0648\u0644 \u0627\u0644\u0646\u0648\u0627\u0629. \u0648\u064A\u062A\u0645 \u0627\u0633\u062A\u062E\u062F\u0627\u0645 \u0627\u0644\u0645\u0635\u0637\u0644\u062D \u063A\u0644\u0627\u0641 \u0627\u0644\u0637\u0627\u0642\u0629 \u0643\u0645\u0631\u062C\u0639 \u0644\u0644\u062A\u0648\u0632\u064A\u0639 \u0627\u0644\u0625\u0644\u0643\u062A\u0631\u0648\u0646\u064A \u0641\u064A \u0627\u0644\u0630\u0631\u0629 \u0623\u0648 \u0627\u0644\u062C\u0632\u064A\u0621. \u0648\u0637\u0628\u0642\u0627 \u0644\u0646\u0638\u0631\u064A\u0629 \u0627\u0644\u0643\u0645 \u0641\u0625\u0646 \u0627\u0644\u0625\u0644\u0643\u062A\u0631\u0648\u0646 \u064A\u0648\u062C\u062F \u0641\u0642\u0637 \u0641\u064A \u062D\u0627\u0644\u0627\u062A \u0643\u0645\u0648\u0645\u064A\u0629 \u00AB\u0645\u062F\u0627\u0631\u0627\u062A\u00BB \u0645\u0639\u064A\u0646\u0629 \u0623\u0648 \u0623\u063A\u0644\u0641\u0629 \u0630\u0627\u062A \u0637\u0627\u0642\u0629 \u0645\u0639\u064A\u0646\u0629. \u0647\u0630\u0627 \u064A\u0639\u0646\u0649 \u0623\u0646 \u0637\u0627\u0642\u0629 \u0627\u0644\u0625\u0644\u0643\u062A\u0631\u0648\u0646 \u0641\u064A \u0627\u0644\u0630\u0631\u0629 \u0623\u0648 \u0641\u064A \u0627\u0644\u062C\u0632\u064A\u0621 \u062A\u0643\u0648\u0646 \u0641\u064A \u0634\u0643\u0644 \u0643\u0645\u0627\u062A (\u0627\u0642\u0631\u0623 \u0627\u0644\u0637\u064A\u0641 \u0648\u0647\u0632\u0627\u0632 \u062A\u0648\u0627\u0641\u0642\u064A \u0644\u0645\u0632\u064A\u062F \u0645\u0646 \u0627\u0644\u062A\u0641\u0627\u0635\u064A\u0644). \u0648\u0637\u0628\u0642\u0627 \u0644\u062A\u0639\u0631\u064A\u0641\u0627\u062A \u0637\u0627\u0642\u0629 \u0627\u0644\u0648\u0636\u0639 \u0627\u0644\u062A\u0642\u0644\u064A\u062F\u064A\u0629\u060C \u0641\u0625\u0646 \u0637\u0627\u0642\u0629 \u0627\u0644\u0648\u0636\u0639 \u062A\u0633\u0627\u0648\u0649 \u0635\u0641\u0631 \u0639\u0646\u062F \u0627\u0644\u0644\u0627 \u0646\u0647\u0627\u064A\u0629\u060C \u0645\u0645\u0627 \u064A\u0624\u062F\u0649 \u0644\u0648\u062C\u0648\u062F \u0637\u0627\u0642\u0629 \u0648\u0636\u0639 \u0633\u0627\u0644\u0628\u0629 \u0644\u062D\u0627\u0644\u0629 \u062A\u0631\u0627\u0628\u0637 \u0627\u0644\u0625\u0644\u0643\u062A\u0631\u0648\u0646 \u0641\u064A \u0627\u0644\u0630\u0631\u0629."@ar ,
"Em mec\u00E2nica qu\u00E2ntica, n\u00EDvel de energia ou n\u00EDvel energ\u00E9tico \u00E9 um estado qu\u00E2ntico (de um el\u00E9tron, \u00E1tomo ou mol\u00E9cula, por exemplo) cuja energia est\u00E1 bem definida ao longo do tempo. Desse modo, os n\u00EDveis energ\u00E9ticos s\u00E3o as fun\u00E7\u00F5es pr\u00F3prias do operador hamiltoniano, e suas energias respectivas s\u00E3o seus valores. Se a energia potencial \u00E9 considerada zero a uma dist\u00E2ncia infinita do n\u00FAcleo do \u00E1tomo ou da mol\u00E9cula, conven\u00E7\u00E3o usual, ent\u00E3o os respectivos estados eletr\u00F4nicos possuem energia potencial negativa."@pt ,
"N\u00ED f\u00E9idir le c\u00F3ras meicni\u00FAil candamach n\u00F3 c\u00E1ithn\u00EDn at\u00E1 - is \u00E9 sin, at\u00E1 s\u00E1innithe go sp\u00E1s\u00FAil - ach luachanna scoite fuinnimh \u00E1irithe, ar a dtugtar leibh\u00E9il fhuinnimh, a ghlacadh. T\u00E1 s\u00E9 seo i gcodarsnacht le c\u00E1ithn\u00EDn\u00ED clasaiceacha, ar f\u00E9idir leo m\u00E9id ar bith fuinnimh a bheith acu. \u00DAs\u00E1idtear an t\u00E9arma go coitianta le haghaidh leibh\u00E9il fuinnimh na leictreon in adaimh, iain, n\u00F3 m\u00F3il\u00EDn\u00ED, at\u00E1 nasctha ag r\u00E9imse leictreach an n\u00FAicl\u00E9as, ach is f\u00E9idir leo tagairt a dh\u00E9anamh freisin do na leibh\u00E9il fhuinnimh sa n\u00FAicl\u00E9as n\u00F3 do na leibh\u00E9il rothlacha n\u00F3 creath\u00FAla fuinnimh i m\u00F3il\u00EDn\u00ED. Deirtear go mb\u00EDonn an speictream fuinnimh i gc\u00F3rais a bhfuil na leibh\u00E9il fhuinnimh scoite sin aige a chainn\u00EDocht\u00FA. Deirtear go nd\u00E9antar speictream fuinnimh c\u00F3rais a bhfuil na leibh\u00E9il fhuinnimh scoite sin aige"@ga ,
"Een energieniveau is de discrete energie die als een energetische eigentoestand bij een kwantummechanische toestand van een systeem (bijvoorbeeld een atoom of een atoomkern) hoort.Energieniveaus zijn toegestane eigenwaarden van de Hamiltonoperator en zijn daarom tijdsonafhankelijk. Het systeem kan zich continu slechts in \u00E9\u00E9n toestand bevinden, maar kan niet een van de daartussenin liggende energiewaarden hebben. Een aan zichzelf overgelaten systeem tracht er altijd zijn laagste energieniveau, zijn grondtoestand, te bereiken. Alle andere niveaus worden aangeslagen toestanden genoemd."@nl ,
"En mec\u00E1nica cu\u00E1ntica, un nivel energ\u00E9tico es un estado (o conjunto de estados) cuya energ\u00EDa es uno de los valores posibles del operador hamiltoniano, y por lo tanto su valor de energ\u00EDa es un valor propio de dicho operador. Matem\u00E1ticamente los estados de un cierto nivel energ\u00E9tico son funciones propias del mismo hamiltoniano."@es ,
"\u0415\u043D\u0435\u0440\u0433\u0435\u0442\u0438\u0447\u043D\u0438\u0439 \u0440\u0456\u0432\u0435\u043D\u044C \u2014 \u0434\u043E\u0437\u0432\u043E\u043B\u0435\u043D\u0435 \u0437\u043D\u0430\u0447\u0435\u043D\u043D\u044F \u0435\u043D\u0435\u0440\u0433\u0456\u0457 \u0432 \u043A\u0432\u0430\u043D\u0442\u043E\u0432\u0456\u0439 \u043C\u0435\u0445\u0430\u043D\u0456\u0446\u0456. \u0421\u0443\u043A\u0443\u043F\u043D\u0456\u0441\u0442\u044C \u0435\u043D\u0435\u0440\u0433\u0435\u0442\u0438\u0447\u043D\u0438\u0445 \u0440\u0456\u0432\u043D\u0456\u0432 \u043D\u0430\u0437\u0438\u0432\u0430\u044E\u0442\u044C \u0435\u043D\u0435\u0440\u0433\u0435\u0442\u0438\u0447\u043D\u0438\u043C \u0441\u043F\u0435\u043A\u0442\u0440\u043E\u043C. \u041C\u0430\u0442\u0435\u043C\u0430\u0442\u0438\u0447\u043D\u043E \u0435\u043D\u0435\u0440\u0433\u0435\u0442\u0438\u0447\u043D\u0438\u0439 \u0440\u0456\u0432\u0435\u043D\u044C \u0454 \u0432\u043B\u0430\u0441\u043D\u0438\u043C \u0437\u043D\u0430\u0447\u0435\u043D\u043D\u044F\u043C \u043E\u043F\u0435\u0440\u0430\u0442\u043E\u0440\u0430 \u0435\u043D\u0435\u0440\u0433\u0456\u0457 \u2014 \u0433\u0430\u043C\u0456\u043B\u044C\u0442\u043E\u043D\u0456\u0430\u043D\u0430. \u041A\u043E\u0436\u0435\u043D \u0435\u043D\u0435\u0440\u0433\u0435\u0442\u0438\u0447\u043D\u0438\u0439 \u0440\u0456\u0432\u0435\u043D\u044C \u0432\u0456\u0434\u043F\u043E\u0432\u0456\u0434\u0430\u0454 \u043E\u0434\u043D\u043E\u043C\u0443 \u0430\u0431\u043E \u043A\u0456\u043B\u044C\u043A\u043E\u043C \u0441\u0442\u0430\u0446\u0456\u043E\u043D\u0430\u0440\u043D\u0438\u043C \u0441\u0442\u0430\u043D\u0430\u043C \u043A\u0432\u0430\u043D\u0442\u043E\u0432\u043E\u0457 \u0441\u0438\u0441\u0442\u0435\u043C\u0438. \u0423 \u0432\u0438\u043F\u0430\u0434\u043A\u0443, \u043A\u043E\u043B\u0438 \u0442\u0430\u043A\u0438\u0445 \u0441\u0442\u0430\u043D\u0456\u0432 \u043A\u0456\u043B\u044C\u043A\u0430, \u0435\u043D\u0435\u0440\u0433\u0435\u0442\u0438\u0447\u043D\u0438\u0439 \u0440\u0456\u0432\u0435\u043D\u044C \u043D\u0430\u0437\u0438\u0432\u0430\u044E\u0442\u044C \u0432\u0438\u0440\u043E\u0434\u0436\u0435\u043D\u0438\u043C (\u0434\u0443\u0431\u043B\u0435\u0442\u043D\u0438\u043C, \u0442\u0440\u0438\u043F\u043B\u0435\u0442\u043D\u0438\u043C \u0442\u043E\u0449\u043E, \u0432 \u0437\u0430\u043B\u0435\u0436\u043D\u043E\u0441\u0442\u0456 \u0432\u0456\u0434 \u0442\u043E\u0433\u043E, \u0441\u043A\u0456\u043B\u044C\u043A\u0438 \u0441\u0442\u0430\u043D\u0456\u0432 \u043C\u0430\u044E\u0442\u044C \u043E\u0434\u043D\u0430\u043A\u043E\u0432\u0443 \u0435\u043D\u0435\u0440\u0433\u0456\u044E)."@uk ,
"\u042D\u043D\u0435\u0440\u0433\u0435\u0442\u0438\u0447\u0435\u0441\u043A\u0438\u0439 \u0443\u0440\u043E\u0432\u0435\u043D\u044C \u2014 \u0441\u043E\u0431\u0441\u0442\u0432\u0435\u043D\u043D\u044B\u0435 \u0437\u043D\u0430\u0447\u0435\u043D\u0438\u044F \u044D\u043D\u0435\u0440\u0433\u0438\u0438 \u043A\u0432\u0430\u043D\u0442\u043E\u0432\u044B\u0445 \u0441\u0438\u0441\u0442\u0435\u043C, \u0442\u043E \u0435\u0441\u0442\u044C \u0441\u0438\u0441\u0442\u0435\u043C, \u0441\u043E\u0441\u0442\u043E\u044F\u0449\u0438\u0445 \u0438\u0437 \u043C\u0438\u043A\u0440\u043E\u0447\u0430\u0441\u0442\u0438\u0446 (\u044D\u043B\u0435\u043A\u0442\u0440\u043E\u043D\u043E\u0432, \u043F\u0440\u043E\u0442\u043E\u043D\u043E\u0432 \u0438 \u0434\u0440\u0443\u0433\u0438\u0445 \u044D\u043B\u0435\u043C\u0435\u043D\u0442\u0430\u0440\u043D\u044B\u0445 \u0447\u0430\u0441\u0442\u0438\u0446) \u0438 \u043F\u043E\u0434\u0447\u0438\u043D\u044F\u044E\u0449\u0438\u0445\u0441\u044F \u0437\u0430\u043A\u043E\u043D\u0430\u043C \u043A\u0432\u0430\u043D\u0442\u043E\u0432\u043E\u0439 \u043C\u0435\u0445\u0430\u043D\u0438\u043A\u0438. \u041A\u0430\u0436\u0434\u044B\u0439 \u0443\u0440\u043E\u0432\u0435\u043D\u044C \u0445\u0430\u0440\u0430\u043A\u0442\u0435\u0440\u0438\u0437\u0443\u0435\u0442\u0441\u044F \u043E\u043F\u0440\u0435\u0434\u0435\u043B\u0451\u043D\u043D\u044B\u043C \u0441\u043E\u0441\u0442\u043E\u044F\u043D\u0438\u0435\u043C \u0441\u0438\u0441\u0442\u0435\u043C\u044B, \u0438\u043B\u0438 \u043F\u043E\u0434\u043C\u043D\u043E\u0436\u0435\u0441\u0442\u0432\u043E\u043C \u0442\u0430\u043A\u043E\u0432\u044B\u0445 \u0432 \u0441\u043B\u0443\u0447\u0430\u0435 \u0432\u044B\u0440\u043E\u0436\u0434\u0435\u043D\u0438\u044F. \u041F\u043E\u043D\u044F\u0442\u0438\u0435 \u043F\u0440\u0438\u043C\u0435\u043D\u0438\u043C\u043E \u043A \u0430\u0442\u043E\u043C\u0430\u043C (\u044D\u043B\u0435\u043A\u0442\u0440\u043E\u043D\u043D\u044B\u0435 \u0443\u0440\u043E\u0432\u043D\u0438), \u043C\u043E\u043B\u0435\u043A\u0443\u043B\u0430\u043C (\u0440\u0430\u0437\u043B\u0438\u0447\u043D\u044B\u0435 \u0443\u0440\u043E\u0432\u043D\u0438, \u0441\u043E\u043E\u0442\u0432\u0435\u0442\u0441\u0442\u0432\u0443\u044E\u0449\u0438\u0435 \u043A\u043E\u043B\u0435\u0431\u0430\u043D\u0438\u044F\u043C \u0438 \u0432\u0440\u0430\u0449\u0435\u043D\u0438\u044F\u043C \u2014 \u043A\u043E\u043B\u0435\u0431\u0430\u0442\u0435\u043B\u044C\u043D\u044B\u0435 \u0438 \u0432\u0440\u0430\u0449\u0430\u0442\u0435\u043B\u044C\u043D\u044B\u0435 \u0443\u0440\u043E\u0432\u043D\u0438), \u0430\u0442\u043E\u043C\u043D\u044B\u043C \u044F\u0434\u0440\u0430\u043C (\u0432\u043D\u0443\u0442\u0440\u0438\u044F\u0434\u0435\u0440\u043D\u044B\u0435 \u044D\u043D\u0435\u0440\u0433\u0435\u0442\u0438\u0447\u0435\u0441\u043A\u0438\u0435 \u0443\u0440\u043E\u0432\u043D\u0438) \u0438 \u0442. \u0434."@ru ,
"Energiniv\u00E5 eller kvantniv\u00E5 \u00E4r i kvantfysik de energitillst\u00E5nd som ett fysiskt system kan ha. Termen anv\u00E4nds vanligtvis i samband med elektronkonfigurationen i atomer, molekyler eller k\u00E4rnor, eftersom skillnaden i energiniv\u00E5er f\u00F6r ett makroskopiskt objekt \u00E4r f\u00F6rsumbar. Denna artikel om kvantfysik eller subatom\u00E4r fysik saknar v\u00E4sentlig information. Du kan hj\u00E4lpa till genom att l\u00E4gga till den."@sv ,
"Un niveau d'\u00E9nergie est une quantit\u00E9 utilis\u00E9e pour d\u00E9crire les syst\u00E8mes en m\u00E9canique quantique et par extension dans la physique en g\u00E9n\u00E9ral, sachant que, s'il y a bien quantification de l'\u00E9nergie, \u00E0 un niveau d'\u00E9nergie donn\u00E9 correspond un \u00AB \u00E9tat du syst\u00E8me \u00BB donn\u00E9 ; \u00E0 moins que le niveau d'\u00E9nergie soit dit \u00AB d\u00E9g\u00E9n\u00E9r\u00E9 \u00BB. La notion de niveau d'\u00E9nergie a \u00E9t\u00E9 propos\u00E9e en 1913 par le physicien danois Niels Bohr."@fr ;
foaf:depiction ,
,
,
.
@prefix dcterms: .
@prefix dbc: .
dbr:Energy_level dcterms:subject dbc:Quantum_chemistry ,
dbc:Computational_chemistry ,
dbc:Molecular_physics ,
dbc:Spectroscopy ,
dbc:Theoretical_chemistry ,
dbc:Chemical_properties ,
dbc:Atomic_physics ;
dbo:abstract "\u0633\u0648\u064A\u0629 \u0623\u0648 \u0645\u0633\u062A\u0648\u0649 \u0627\u0644\u0637\u0627\u0642\u0629 \u0641\u064A \u0627\u0644\u0641\u064A\u0632\u064A\u0627\u0621 \u0627\u0644\u0630\u0631\u064A\u0629 \u0648\u0627\u0644\u0641\u064A\u0632\u064A\u0627\u0621 \u0627\u0644\u062C\u0632\u064A\u0626\u064A\u0629 \u0648\u0643\u064A\u0645\u064A\u0627\u0621 \u0627\u0644\u0643\u0645\u060C \u0647\u064A \u0645\u062F\u0627\u0631\u0627\u062A \u0648\u0647\u0645\u064A\u0629 \u0644\u062D\u0627\u0644\u0629 \u062A\u0631\u0627\u0628\u0637 \u0628\u064A\u0646 \u062C\u064A\u0633\u0645\u064A\u0646 \u0641\u064A \u0645\u064A\u0643\u0627\u0646\u064A\u0643\u0627 \u0627\u0644\u0643\u0645 \u0645\u062B\u0644 \u062D\u0627\u0644\u0629 \u0627\u0644\u0625\u0644\u0643\u062A\u0631\u0648\u0646 \u0627\u0644\u0645\u0631\u062A\u0628\u0637 \u0628\u0627\u0644\u0630\u0631\u0629 \u0648\u064A\u062F\u0648\u0631 \u062D\u0648\u0644 \u0627\u0644\u0646\u0648\u0627\u0629. \u0648\u064A\u062A\u0645 \u0627\u0633\u062A\u062E\u062F\u0627\u0645 \u0627\u0644\u0645\u0635\u0637\u0644\u062D \u063A\u0644\u0627\u0641 \u0627\u0644\u0637\u0627\u0642\u0629 \u0643\u0645\u0631\u062C\u0639 \u0644\u0644\u062A\u0648\u0632\u064A\u0639 \u0627\u0644\u0625\u0644\u0643\u062A\u0631\u0648\u0646\u064A \u0641\u064A \u0627\u0644\u0630\u0631\u0629 \u0623\u0648 \u0627\u0644\u062C\u0632\u064A\u0621. \u0648\u0637\u0628\u0642\u0627 \u0644\u0646\u0638\u0631\u064A\u0629 \u0627\u0644\u0643\u0645 \u0641\u0625\u0646 \u0627\u0644\u0625\u0644\u0643\u062A\u0631\u0648\u0646 \u064A\u0648\u062C\u062F \u0641\u0642\u0637 \u0641\u064A \u062D\u0627\u0644\u0627\u062A \u0643\u0645\u0648\u0645\u064A\u0629 \u00AB\u0645\u062F\u0627\u0631\u0627\u062A\u00BB \u0645\u0639\u064A\u0646\u0629 \u0623\u0648 \u0623\u063A\u0644\u0641\u0629 \u0630\u0627\u062A \u0637\u0627\u0642\u0629 \u0645\u0639\u064A\u0646\u0629. \u0647\u0630\u0627 \u064A\u0639\u0646\u0649 \u0623\u0646 \u0637\u0627\u0642\u0629 \u0627\u0644\u0625\u0644\u0643\u062A\u0631\u0648\u0646 \u0641\u064A \u0627\u0644\u0630\u0631\u0629 \u0623\u0648 \u0641\u064A \u0627\u0644\u062C\u0632\u064A\u0621 \u062A\u0643\u0648\u0646 \u0641\u064A \u0634\u0643\u0644 \u0643\u0645\u0627\u062A (\u0627\u0642\u0631\u0623 \u0627\u0644\u0637\u064A\u0641 \u0648\u0647\u0632\u0627\u0632 \u062A\u0648\u0627\u0641\u0642\u064A \u0644\u0645\u0632\u064A\u062F \u0645\u0646 \u0627\u0644\u062A\u0641\u0627\u0635\u064A\u0644). \u0648\u0637\u0628\u0642\u0627 \u0644\u062A\u0639\u0631\u064A\u0641\u0627\u062A \u0637\u0627\u0642\u0629 \u0627\u0644\u0648\u0636\u0639 \u0627\u0644\u062A\u0642\u0644\u064A\u062F\u064A\u0629\u060C \u0641\u0625\u0646 \u0637\u0627\u0642\u0629 \u0627\u0644\u0648\u0636\u0639 \u062A\u0633\u0627\u0648\u0649 \u0635\u0641\u0631 \u0639\u0646\u062F \u0627\u0644\u0644\u0627 \u0646\u0647\u0627\u064A\u0629\u060C \u0645\u0645\u0627 \u064A\u0624\u062F\u0649 \u0644\u0648\u062C\u0648\u062F \u0637\u0627\u0642\u0629 \u0648\u0636\u0639 \u0633\u0627\u0644\u0628\u0629 \u0644\u062D\u0627\u0644\u0629 \u062A\u0631\u0627\u0628\u0637 \u0627\u0644\u0625\u0644\u0643\u062A\u0631\u0648\u0646 \u0641\u064A \u0627\u0644\u0630\u0631\u0629. \u0648\u062A\u0628\u0644\u063A \u0637\u0627\u0642\u0629 \u0627\u0644\u0627\u0631\u062A\u0628\u0627\u0637 \u0644\u0644\u0625\u0644\u0643\u062A\u0631\u0648\u0646 \u0641\u064A \u0630\u0631\u0629 \u0627\u0644\u0647\u064A\u062F\u0631\u0648\u062C\u064A\u0646 13.6 \u0625\u0644\u0643\u062A\u0631\u0648\u0646 \u0641\u0648\u0644\u062A."@ar ,
"Energiniv\u00E5 eller kvantniv\u00E5 \u00E4r i kvantfysik de energitillst\u00E5nd som ett fysiskt system kan ha. Termen anv\u00E4nds vanligtvis i samband med elektronkonfigurationen i atomer, molekyler eller k\u00E4rnor, eftersom skillnaden i energiniv\u00E5er f\u00F6r ett makroskopiskt objekt \u00E4r f\u00F6rsumbar. Denna artikel om kvantfysik eller subatom\u00E4r fysik saknar v\u00E4sentlig information. Du kan hj\u00E4lpa till genom att l\u00E4gga till den."@sv ,
"N\u00ED f\u00E9idir le c\u00F3ras meicni\u00FAil candamach n\u00F3 c\u00E1ithn\u00EDn at\u00E1 - is \u00E9 sin, at\u00E1 s\u00E1innithe go sp\u00E1s\u00FAil - ach luachanna scoite fuinnimh \u00E1irithe, ar a dtugtar leibh\u00E9il fhuinnimh, a ghlacadh. T\u00E1 s\u00E9 seo i gcodarsnacht le c\u00E1ithn\u00EDn\u00ED clasaiceacha, ar f\u00E9idir leo m\u00E9id ar bith fuinnimh a bheith acu. \u00DAs\u00E1idtear an t\u00E9arma go coitianta le haghaidh leibh\u00E9il fuinnimh na leictreon in adaimh, iain, n\u00F3 m\u00F3il\u00EDn\u00ED, at\u00E1 nasctha ag r\u00E9imse leictreach an n\u00FAicl\u00E9as, ach is f\u00E9idir leo tagairt a dh\u00E9anamh freisin do na leibh\u00E9il fhuinnimh sa n\u00FAicl\u00E9as n\u00F3 do na leibh\u00E9il rothlacha n\u00F3 creath\u00FAla fuinnimh i m\u00F3il\u00EDn\u00ED. Deirtear go mb\u00EDonn an speictream fuinnimh i gc\u00F3rais a bhfuil na leibh\u00E9il fhuinnimh scoite sin aige a chainn\u00EDocht\u00FA. Deirtear go nd\u00E9antar speictream fuinnimh c\u00F3rais a bhfuil na leibh\u00E9il fhuinnimh scoite sin aige Sa cheimic agus san fhisic adamhach, f\u00E9adtar smaoineamh ar leictreonsceall, n\u00F3 pr\u00EDomhleibh\u00E9al fuinnimh, mar fhithis leictreon amh\u00E1in n\u00F3 n\u00EDos m\u00F3 timpeall n\u00FAicl\u00E9as an adaimh. De r\u00E9ir theoiric Bhohr, bh\u00ED fithis\u00ED \u00E1irithe thart ar an n\u00FAicl\u00E9as, agus fad a bh\u00ED an leictreon in aon fhithis d\u00EDobh sin, n\u00EDor astaigh s\u00E9 fuinneamh ar bith. Tugtar an \"sceall 1\" ar an sceall is gaire don n\u00FAicl\u00E9as (ar a dtugtar \"sceall K \" freisin), agus tar \u00E9is sin, tugtar an \"sceall 2\" (n\u00F3 an \"sceall L\" ), ansin an \"sceall 3\" (n\u00F3 \"sceall M\") , agus mar sin de, n\u00EDos faide agus n\u00EDos faide \u00F3n n\u00FAicl\u00E9as. Comhfhreagra\u00EDonn na scealla leis na (n = 1, 2, 3, 4 ...), n\u00F3 t\u00E1 siad lip\u00E9adaithe in ord aib\u00EDtre le litreacha a \u00FAs\u00E1idtear sa (K, L, M, N\u2026). N\u00ED f\u00E9idir ach l\u00EDon seasta leictreon a bheith i ngach sceall: Is f\u00E9idir leis an gc\u00E9ad sceall suas le dh\u00E1 leictreon a shealbh\u00FA, is f\u00E9idir leis an dara sceall suas le hocht (2 + 6) leictreon a shealbh\u00FA, is f\u00E9idir leis an tr\u00ED\u00FA sceall suas le 18 (2 + 6 + 10) a choinne\u00E1il agus mar sin de. Is \u00ED an fhoirmle ghinear\u00E1lta gur f\u00E9idir leis an nao\u00FA sceall suas le 2(n2) leictreon a choinne\u00E1il. \u00D3s rud \u00E9 go n-aomtar leictreoin go dt\u00ED an n\u00FAicl\u00E9as, is gn\u00E1ch nach n-\u00E1it\u00EDonn leictreoin adaimh scealla seachtracha m\u00E1 t\u00E1 na scealla istigh l\u00EDonta go hioml\u00E1n cheana f\u00E9in ag leictreoin eile. Mar sin f\u00E9in, n\u00ED riachtanas docht \u00E9 seo: d\u2019fh\u00E9adfadh go mbeadh dh\u00E1 n\u00F3 fi\u00FA tr\u00ED sceall seachtrach neamhioml\u00E1n ag adamh. (F\u00E9ach riail Madelung le haghaidh tuilleadh sonra\u00ED.) Le haghaidh m\u00EDni\u00FA ar an bhf\u00E1th go bhfuil leictreoin sna scealla seo f\u00E9ach cumra\u00EDocht na leictreon. M\u00E1 t\u00E1 an fuinneamh poit\u00E9insi\u00FAil socraithe go nialas ag fad \u00E9igr\u00EDochta \u00F3n n\u00FAicl\u00E9as adamhach n\u00F3 \u00F3n m\u00F3il\u00EDn, an gn\u00E1thchoinbhinsi\u00FAn, ansin t\u00E1 fuinneamh f\u00E9ideartha di\u00FAltach ag staid nasctha leictreon. M\u00E1 t\u00E1 adamh, ian, n\u00F3 m\u00F3il\u00EDn ag an leibh\u00E9al fuinnimh is \u00EDsle is f\u00E9idir, deirtear go bhfuil s\u00E9 f\u00E9in agus a leictreoin sa . M\u00E1 t\u00E1 s\u00E9 ar leibh\u00E9al fuinnimh n\u00EDos airde, deirtear go bhfuil s\u00E9 flosctha, n\u00F3 go bhfuil aon leictreon a bhfuil fuinneamh n\u00EDos airde acu n\u00E1 an bhunstaid flosctha. M\u00E1 t\u00E1 n\u00EDos m\u00F3 n\u00E1 staid mheicni\u00FAil chandamach amh\u00E1in ag an bhfuinneamh c\u00E9anna, t\u00E1 na leibh\u00E9il fhuinnimh \u201Cd\u00EDchine\u00E1lach\u201D. Tugtar orthu ansin."@ga ,
"Poziom energetyczny \u2013 energia stanu dost\u0119pnego dla cz\u0105stki. Poziom mo\u017Ce by\u0107 zdegenerowany, je\u015Bli dana warto\u015B\u0107 energii cechuje wi\u0119cej ni\u017C jeden stan kwantowy."@pl ,
"Ein Energieniveau ist die diskrete Energie, die als Energieeigenzustand zu einem quantenmechanischen Zustand eines Systems (etwa eines Atoms oder eines Atomkerns) geh\u00F6rt. Energieniveaus sind Eigenwerte des Hamilton-Operators, sie sind deshalb zeitunabh\u00E4ngig. Das System kann sich dauerhaft nur in einem dieser Zust\u00E4nde, aber nicht bei anderen, dazwischen liegenden Werten der Energie \u201Eaufhalten\u201C. Das tiefste Energieniveau wird als Grundzustand bezeichnet (bzw. im Falle von Entartung als \"Grundzust\u00E4nde\"), alle anderen Niveaus hei\u00DFen angeregte Zust\u00E4nde. Anschaulich kann man sich vorstellen, dass Anordnung und Bewegungsweise der Elektronen in der Atomh\u00FClle \u2013 oder der Nukleonen im Kern \u2013 jeweils nur in ganz bestimmter Form stabil sind. Jeder dieser Zust\u00E4nde hat einen anderen, bestimmten Energieinhalt. Allerdings gibt es oberhalb einer bestimmten Grenzenergie auch ein Energie-Kontinuum, einen Bereich beliebiger m\u00F6glicher Energiewerte. In einem konservativen Feld, etwa im Coulombfeld in der Atomh\u00FClle, entspricht diese Grenze gerade der Bindungsenergie des am leichtesten abtrennbaren Teilchens (siehe z. B. Ionisation). Das Kontinuum m\u00F6glicher Energien ergibt sich daraus, dass dieses abgetrennte Teilchen mit einer beliebigen kinetischen Energie davonfliegen kann. In anderen Feldern, etwa f\u00FCr die Nukleonen des Atomkerns, f\u00E4llt die Kontinuumsgrenze nicht mit der Bindungsenergie eines Teilchens zusammen. In beiden F\u00E4llen kann es auch im Kontinuum Energieniveaus geben, die sich etwa als Resonanzen in Wirkungsquerschnitten bemerkbar machen. In Atomen tritt dies auf, wenn ein Zustand mit einem asymptotisch freien Teilchen entartet \u2013 also energiegleich ist mit einem Zustand ohne asymptotisch freies Teilchen."@de ,
"En mec\u00E1nica cu\u00E1ntica, un nivel energ\u00E9tico es un estado (o conjunto de estados) cuya energ\u00EDa es uno de los valores posibles del operador hamiltoniano, y por lo tanto su valor de energ\u00EDa es un valor propio de dicho operador. Matem\u00E1ticamente los estados de un cierto nivel energ\u00E9tico son funciones propias del mismo hamiltoniano."@es ,
"\u0415\u043D\u0435\u0440\u0433\u0435\u0442\u0438\u0447\u043D\u0438\u0439 \u0440\u0456\u0432\u0435\u043D\u044C \u2014 \u0434\u043E\u0437\u0432\u043E\u043B\u0435\u043D\u0435 \u0437\u043D\u0430\u0447\u0435\u043D\u043D\u044F \u0435\u043D\u0435\u0440\u0433\u0456\u0457 \u0432 \u043A\u0432\u0430\u043D\u0442\u043E\u0432\u0456\u0439 \u043C\u0435\u0445\u0430\u043D\u0456\u0446\u0456. \u0421\u0443\u043A\u0443\u043F\u043D\u0456\u0441\u0442\u044C \u0435\u043D\u0435\u0440\u0433\u0435\u0442\u0438\u0447\u043D\u0438\u0445 \u0440\u0456\u0432\u043D\u0456\u0432 \u043D\u0430\u0437\u0438\u0432\u0430\u044E\u0442\u044C \u0435\u043D\u0435\u0440\u0433\u0435\u0442\u0438\u0447\u043D\u0438\u043C \u0441\u043F\u0435\u043A\u0442\u0440\u043E\u043C. \u041C\u0430\u0442\u0435\u043C\u0430\u0442\u0438\u0447\u043D\u043E \u0435\u043D\u0435\u0440\u0433\u0435\u0442\u0438\u0447\u043D\u0438\u0439 \u0440\u0456\u0432\u0435\u043D\u044C \u0454 \u0432\u043B\u0430\u0441\u043D\u0438\u043C \u0437\u043D\u0430\u0447\u0435\u043D\u043D\u044F\u043C \u043E\u043F\u0435\u0440\u0430\u0442\u043E\u0440\u0430 \u0435\u043D\u0435\u0440\u0433\u0456\u0457 \u2014 \u0433\u0430\u043C\u0456\u043B\u044C\u0442\u043E\u043D\u0456\u0430\u043D\u0430. \u041A\u043E\u0436\u0435\u043D \u0435\u043D\u0435\u0440\u0433\u0435\u0442\u0438\u0447\u043D\u0438\u0439 \u0440\u0456\u0432\u0435\u043D\u044C \u0432\u0456\u0434\u043F\u043E\u0432\u0456\u0434\u0430\u0454 \u043E\u0434\u043D\u043E\u043C\u0443 \u0430\u0431\u043E \u043A\u0456\u043B\u044C\u043A\u043E\u043C \u0441\u0442\u0430\u0446\u0456\u043E\u043D\u0430\u0440\u043D\u0438\u043C \u0441\u0442\u0430\u043D\u0430\u043C \u043A\u0432\u0430\u043D\u0442\u043E\u0432\u043E\u0457 \u0441\u0438\u0441\u0442\u0435\u043C\u0438. \u0423 \u0432\u0438\u043F\u0430\u0434\u043A\u0443, \u043A\u043E\u043B\u0438 \u0442\u0430\u043A\u0438\u0445 \u0441\u0442\u0430\u043D\u0456\u0432 \u043A\u0456\u043B\u044C\u043A\u0430, 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\u0449\u043E \u043F\u0435\u0440\u0435\u0432\u0438\u0449\u0443\u0454 \u0435\u043D\u0435\u0440\u0433\u0456\u044E \u043E\u0441\u043D\u043E\u0432\u043D\u043E\u0433\u043E \u0441\u0442\u0430\u043D\u0443 \u043A\u0432\u0430\u043D\u0442\u043E\u0432\u043E\u0457 \u0441\u0438\u0441\u0442\u0435\u043C\u0438, \u043E\u043F\u0438\u0441\u0443\u044E\u0442\u044C \u044F\u043A \u0437\u0431\u0443\u0434\u0436\u0435\u043D\u0456 \u0441\u0442\u0430\u043D\u0438."@uk ,
"In meccanica quantistica, i livelli energetici di un sistema sono i determinati valori discreti dell'energia che sono accessibili al sistema. Questo \u00E8 in contrasto con la meccanica classica, dove l'energia pu\u00F2 assumere ogni valore. Sin dalle origini della chimica come scienza era stato osservato che l'assorbimento della luce da parte dei gas non varia in maniera morbida con la lunghezza d'onda ma \u00E8 caratterizzato dalla presenza di un gran numero di picchi estremamente sottili e disposti in maniera complicata. Una prima trattazione fenomenologica del problema venne fatta nel 1885 da Johann Jakob Balmer che not\u00F2 come la disposizione di un gruppo di righe di assorbimento dell'atomo di idrogeno venisse ben descritta dalla formula: . Questa formula venne successivamente generalizzata da Johannes Rydberg e Walther Ritz in modo da poter descrivere la posizione di tutte le righe di assorbimento ma questa rimaneva una descrizione fenomenologica, per quanto accurata, senza un vero fondamento scientifico. Il tentativo di spiegare la natura dei picchi di assorbimento fu alla base del modello atomico di Bohr: gi\u00E0 Rutherford aveva proposto l'idea che l'atomo fosse composto da un piccolo nucleo carico positivamente attorno al quale ruotavano in orbite circolari gli elettroni. Tuttavia un sistema del genere non \u00E8 stabile perch\u00E9 un elettrone accelerato emette radiazione e quindi perde energia. Per risolvere il problema Bohr, seguendo le idee proposte da Planck e Einstein, ipotizz\u00F2 che gli elettroni potessero trovarsi solo su determinati livelli energetici e potessero muoversi dall'uno all'altro solo per passi discreti. Questo semplice (ma rivoluzionario) modello permette di descrivere molto bene le righe di assorbimento di molti gas e fu una delle basi per lo sviluppo della meccanica quantistica."@it ,
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"Een energieniveau is de discrete energie die als een energetische eigentoestand bij een kwantummechanische toestand van een systeem (bijvoorbeeld een atoom of een atoomkern) hoort.Energieniveaus zijn toegestane eigenwaarden van de Hamiltonoperator en zijn daarom tijdsonafhankelijk. Het systeem kan zich continu slechts in \u00E9\u00E9n toestand bevinden, maar kan niet een van de daartussenin liggende energiewaarden hebben. Een aan zichzelf overgelaten systeem tracht er altijd zijn laagste energieniveau, zijn grondtoestand, te bereiken. Alle andere niveaus worden aangeslagen toestanden genoemd. Om het aanschouwelijk te maken, kan men zich voorstellen dat de rangschikking en de bewegingen van de elektronen in de elektronenschil \u2013 of de nucleonen in de atoomkern \u2013 alleen bij bepaalde gevallen stabiel zijn. Elk van deze toestanden heeft een andere, vaste, energie-inhoud. Boven een bepaalde grensenergie is er echter ook een continu\u00FCm, een gebied waar willekeurige energiewaarden mogelijk zijn. Bij een atoom komt deze grensenergie overeen met de bindingsenergie van het betreffende elektron; het niet langer gebonden elektron (bijvoorbeeld bij ionisatie) kan daardoor een willekeurige kinetische energie hebben. In de atoomkern is de situatie gecompliceerder; hier bestaan er ook discrete energieniveaus boven de bindingsenergie van het nucleon. Deze niveaus leiden bijvoorbeeld tot resonanties in de werkzame doorsnede van kernreacties."@nl ,
"\u80FD\u7EA7\uFF08\u82F1\u8A9E\uFF1Aenergy level\uFF09\u53C8\u79F0\u80FD\u9636\uFF0C\u662F\u63CF\u8FF0\u5FAE\u89C2\u7C92\u5B50\u4F53\u7CFB\uFF08\u539F\u5B50\u3001\u7535\u5B50\u3001\u5206\u5B50\u7B49\uFF09\u53EF\u80FD\u5B58\u5728\u7684\u76F8\u5BF9\u7A33\u5B9A\u72B6\u6001\u4E0B\uFF0C\u6240\u5BF9\u5E94\u4E00\u7CFB\u5217\u4E0D\u8FDE\u7EED\u7684\u3001\u5206\u7ACB\u7684\u4E14\u786E\u5B9A\u7684\u201C\u5185\u5728\u201D\u80FD\u91CF\u503C\u6216\u72B6\u6001\u3002 \u80FD\u7EA7\u7406\u8BBA\u5219\u662F\u4E00\u79CD\u89E3\u91CA\u539F\u5B50\u6838\u5916\u7535\u5B50\u8FD0\u52A8\u8F68\u9053\u7684\u7406\u8BBA\u3002\u5B83\u8BA4\u4E3A\u7535\u5B50\u53EA\u80FD\u5728\u7279\u5B9A\u7684\u3001\u5206\u7ACB\u7684\u8F68\u9053\u4E0A\u8FD0\u52A8\uFF0C\u5404\u4E2A\u8F68\u9053\u4E0A\u7684\u7535\u5B50\u5177\u6709\u5206\u7ACB\u7684\u80FD\u91CF\uFF0C\u8FD9\u4E9B\u80FD\u91CF\u503C\u5373\u4E3A\u80FD\u7EA7\u3002\u7531\u4E8E\u8DDD\u539F\u5B50\u6838\u8D8A\u8FDC\u7684\u7535\u5B50\u8D8A\u4E0D\u53D7\u675F\u7F1A\uFF0C\u56E0\u6B64\u5176\u80FD\u7EA7\u8D8A\u9AD8\uFF0C\u8BE5\u7535\u5B50\u5177\u6709\u8D8A\u591A\u7684\u7535\u5B50\u80FD\u91CF\u3002 \u7535\u5B50\u53EF\u4EE5\u5728\u4E0D\u540C\u7684\u8F68\u9053\u95F4\u53D1\u751F\u8DC3\u8FC1\uFF0C\u7535\u5B50\u5438\u6536\u80FD\u91CF\u53EF\u4EE5\u4ECE\u4F4E\u80FD\u7EA7\u8DC3\u8FC1\u5230\u9AD8\u80FD\u7EA7\u6216\u8005\u4ECE\u9AD8\u80FD\u7EA7\u8DC3\u8FC1\u5230\u4F4E\u80FD\u7EA7\u4ECE\u800C\u8F90\u5C04\u51FA\u5149\u5B50\u3002\u6C22\u539F\u5B50\u7684\u80FD\u7EA7\u53EF\u4EE5\u7531\u5B83\u7684\u5149\u8C31\u663E\u793A\u51FA\u6765\u3002"@zh ,
"A quantum mechanical system or particle that is bound\u2014that is, confined spatially\u2014can only take on certain discrete values of energy, called energy levels. This contrasts with classical particles, which can have any amount of energy. The term is commonly used for the energy levels of the electrons in atoms, ions, or molecules, which are bound by the electric field of the nucleus, but can also refer to energy levels of nuclei or vibrational or rotational energy levels in molecules. The energy spectrum of a system with such discrete energy levels is said to be quantized. In chemistry and atomic physics, an electron shell, or principal energy level, may be thought of as the orbit of one or more electrons around an atom's nucleus. The closest shell to the nucleus is called the \"1 shell\" (also called \"K shell\"), followed by the \"2 shell\" (or \"L shell\"), then the \"3 shell\" (or \"M shell\"), and so on farther and farther from the nucleus. The shells correspond with the principal quantum numbers (n = 1, 2, 3, 4 ...) or are labeled alphabetically with letters used in the X-ray notation (K, L, M, N...). Each shell can contain only a fixed number of electrons: The first shell can hold up to two electrons, the second shell can hold up to eight (2 + 6) electrons, the third shell can hold up to 18 (2 + 6 + 10) and so on. The general formula is that the nth shell can in principle hold up to 2n2 electrons. Since electrons are electrically attracted to the nucleus, an atom's electrons will generally occupy outer shells only if the more inner shells have already been completely filled by other electrons. However, this is not a strict requirement: atoms may have two or even three incomplete outer shells. (See Madelung rule for more details.) For an explanation of why electrons exist in these shells see electron configuration. If the potential energy is set to zero at infinite distance from the atomic nucleus or molecule, the usual convention, then bound electron states have negative potential energy. If an atom, ion, or molecule is at the lowest possible energy level, it and its electrons are said to be in the ground state. If it is at a higher energy level, it is said to be excited, or any electrons that have higher energy than the ground state are excited. An energy level is regarded as degenerate if there is more than one measurable quantum mechanical state associated with it."@en ,
"Em mec\u00E2nica qu\u00E2ntica, n\u00EDvel de energia ou n\u00EDvel energ\u00E9tico \u00E9 um estado qu\u00E2ntico (de um el\u00E9tron, \u00E1tomo ou mol\u00E9cula, por exemplo) cuja energia est\u00E1 bem definida ao longo do tempo. Desse modo, os n\u00EDveis energ\u00E9ticos s\u00E3o as fun\u00E7\u00F5es pr\u00F3prias do operador hamiltoniano, e suas energias respectivas s\u00E3o seus valores. As diferentes espectroscopias estudam as transi\u00E7\u00F5es entre os diferentes n\u00EDveis de energia. A espectroscopia infravermelha, por exemplo, estuda transi\u00E7\u00F5es entre os n\u00EDveis energ\u00E9ticos da vibra\u00E7\u00E3o molecular, a espectroscopia ultravioleta e vis\u00EDvel estuda as transi\u00E7\u00F5es eletr\u00F4nicas e a espectroscopia M\u00F6ssbauer se ocupa das transi\u00E7\u00F5es nucleares. Na qu\u00EDmica e na f\u00EDsica at\u00F4mica, uma camada eletr\u00F4nica, ou um n\u00EDvel de energia principal, pode ser pensado como uma \u00F3rbita de el\u00E9trons girando ao redor do n\u00FAcleo do \u00E1tomo. A camada mais pr\u00F3xima do n\u00FAcleo \u00E9 chamada de \"camada 1\" (tamb\u00E9m chamada de \"camada K\"), seguida da\" camada 2\" (ou \"camada L\"), depois a \"camada 3\" (ou \"camada M\"), e assim por diante, conforme se afasta do n\u00FAcleo. As camadas correspondem aos n\u00FAmeros qu\u00E2nticos principais (n = 1,2,3,4...) ou s\u00E3o nomeadas na ordem alfab\u00E9tica com letras usadas na rota\u00E7\u00E3o de raio-x (K, L, M,...). Se a energia potencial \u00E9 considerada zero a uma dist\u00E2ncia infinita do n\u00FAcleo do \u00E1tomo ou da mol\u00E9cula, conven\u00E7\u00E3o usual, ent\u00E3o os respectivos estados eletr\u00F4nicos possuem energia potencial negativa. Se um \u00E1tomo, \u00EDon ou mol\u00E9cula est\u00E1 no menor estado poss\u00EDvel de energia, ele e seus el\u00E9trons s\u00E3o ditos no estado fundamental. Se ele est\u00E1 em um n\u00EDvel mais alto de energia, \u00E9 dito excitado, ou quaisquer el\u00E9trons que possuem energia maior do que o estado fundamental est\u00E3o excitados. Se mais de um estado mec\u00E2nico qu\u00E2ntico est\u00E1 com a mesma energia, os n\u00EDveis de energia est\u00E3o \"degenerados\". Eles s\u00E3o ent\u00E3o chamados de n\u00EDveis de energia degenerados."@pt ,
"\u30A8\u30CD\u30EB\u30AE\u30FC\u6E96\u4F4D\uFF08\u30A8\u30CD\u30EB\u30AE\u30FC\u3058\u3085\u3093\u3044\u3001\u82F1: energy level\uFF09\u3068\u306F\u3001\u7CFB\u306E\u30A8\u30CD\u30EB\u30AE\u30FC\u306E\u6E2C\u5B9A\u5024\u3068\u3057\u3066\u3042\u308A\u5F97\u308B\u5024\u3001\u3064\u307E\u308A\u305D\u306E\u7CFB\u306E\u30CF\u30DF\u30EB\u30C8\u30CB\u30A2\u30F3\u306E\u56FA\u6709\u5024\u3092\u4E26\u3079\u305F\u3082\u306E\u3067\u3042\u308B\u3002 \u305D\u308C\u305E\u308C\u306E\u30A8\u30CD\u30EB\u30AE\u30FC\u6E96\u4F4D\u306F\u3001\u91CF\u5B50\u6570\u3084\u9805\u8A18\u53F7\u306A\u3069\u3067\u533A\u5225\u3055\u308C\u308B"@ja ,
"Energinivelo estas kiu apartenas al kvantuma stato de sistemo (precipe de atomo) je certa energio (energistato). Energiniveloj estas permesitaj de la , ili do estas temposendependaj. Energi-preno kaj -dono en la sistemo povas okazi nur per alia energinivelo. Tio ekzemple povas okazi per a\u016D radiado de fotono kun la adekvata energio. Tio rezultigas diskretajn spektrajn liniojn en la radiada spektro. La energinivelojn de la atomoj oni priskribas per la \u0109efa kvantuma nombro n. La energio de la stato kun la kvantuma nombro n en la atomo kun la atoma nombro Z estas alproksimi\u011De :kun la Rydberg-energio Ry = 13,6 eV; sed tio nur validas por oksidosimilaj sistemoj. Aldoni\u011Das tamen ankora\u016D fajnstruktura kaj korektoj kaj la ."@eo ,
"Dalam fisika, tingkat energi (energy level atau energy state) adalah besar energi tertentu yang dapat dimiliki sebuah atom, inti atom, atau partikel subatom yang terikat pada ruang tertentu. Menurut mekanika kuantum, partikel atau sistem tersebut tidak dapat memiliki energi dengan besar sembarang, tetapi hanya bisa memiliki salah satu dari beberapa \"tingkat\" dengan energi berbeda. Tingkat terendah disebut keadaan dasar atau tingkat dasar (ground state) dan tingkat-tingkat diatasnya disebut tingkat eksitasi atau keadaan terekistasi."@in ,
"Un nivell d'energia o nivell energ\u00E8tic \u00E9s una quantitat estable d'energia, que un sistema f\u00EDsic pot tenir; el terme s'utilitza m\u00E9s comunament fent refer\u00E8ncia a la configuraci\u00F3 electr\u00F2nica d'electrons, en \u00E0toms o mol\u00E8cules. Segons la teoria qu\u00E0ntica, nom\u00E9s certs nivells d'energia s\u00F3n possibles; com m\u00E9s alt \u00E9s el nivell energ\u00E8tic on l'electr\u00F3 est\u00E0 situat, m\u00E9s gran \u00E9s la seva energia potencial. Hem de pensar amb els nivells energ\u00E8tics com a graons d'una escala, separats per dist\u00E0ncies desiguals. Una pilota (a la realitat seria un electr\u00F3), situada al gra\u00F3 m\u00E9s baix tindr\u00E0 una energia potencial petita, per tant ser\u00E0 un estat poc energ\u00E8tic. La pilota no \u00E9s estable entremig de dos graons, no hi han estats intermedis, ha d'estar for\u00E7osament situada en un gra\u00F3. Podem fer pujar la pilota un o m\u00E9s graons, subministrant-l'hi energia, i quan fem baixar la pilota un o m\u00E9s graons, allibera energia. El conjunt de tots els nivells energ\u00E8tics d'un sistema s'anomena espectre energ\u00E8tic Un estat energ\u00E8tic o estat energ\u00E8tic molecular \u00E9s la suma dels components electr\u00F2nic, vibrational, i rotacional, de manera que: Les energies espec\u00EDfiques d'aquests components depenen de l'estat energ\u00E8tic on estigui l'electr\u00F3 i de la subst\u00E0ncia."@ca ,
"Un niveau d'\u00E9nergie est une quantit\u00E9 utilis\u00E9e pour d\u00E9crire les syst\u00E8mes en m\u00E9canique quantique et par extension dans la physique en g\u00E9n\u00E9ral, sachant que, s'il y a bien quantification de l'\u00E9nergie, \u00E0 un niveau d'\u00E9nergie donn\u00E9 correspond un \u00AB \u00E9tat du syst\u00E8me \u00BB donn\u00E9 ; \u00E0 moins que le niveau d'\u00E9nergie soit dit \u00AB d\u00E9g\u00E9n\u00E9r\u00E9 \u00BB. La notion de niveau d'\u00E9nergie a \u00E9t\u00E9 propos\u00E9e en 1913 par le physicien danois Niels Bohr. Ainsi, les \u00E9tats que peut prendre un atome sont souvent d\u00E9crits en premi\u00E8re approximation par les diff\u00E9rents niveaux d'\u00E9nergie de ses couches \u00E9lectroniques, ce qui permet notamment de pr\u00E9dire son spectre d'\u00E9mission ou d'absorption des photons. La th\u00E9orie de la m\u00E9canique quantique moderne donnant une explication de ces niveaux d'\u00E9nergie en termes d'\u00E9quation de Schr\u00F6dinger a \u00E9t\u00E9 avanc\u00E9e par Erwin Schr\u00F6dinger et Werner Heisenberg en 1926."@fr ,
"\uC5D0\uB108\uC9C0 \uC900\uC704(Energy \u6E96\u4F4D)\uB294 \uC6D0\uC790\uC640 \uBD84\uC790\uAC00 \uAC16\uB294 \uC5D0\uB108\uC9C0\uC758 \uAC12\uC774\uB2E4. \uBCF4\uC5B4\uC758 \uC6D0\uC790 \uBAA8\uD615\uC5D0\uC11C \uC804\uC790\uAC00 \uC5D0\uB108\uC9C0\uB97C \uBC1B\uC544 \uC704\uCE58\uB97C \uBC14\uAFB8\uBA74, \uC774 \uC704\uCE58\uB4E4\uC774 \uC5D0\uB108\uC9C0 \uC900\uC704\uC774\uB2E4. \uACE0\uC804 \uBB3C\uB9AC\uD559\uC5D0 \uBAA8\uC21C\uB418\uB294 \uC774 \uAC1C\uB150\uC744 \uB3C4\uC785\uD568\uC73C\uB85C\uC368 \uBCF4\uC5B4\uB294 \uC218\uC18C \uC6D0\uC790\uC758 \uC120 \uC2A4\uD399\uD2B8\uB7FC\uC744 \uC124\uBA85\uD560 \uC218 \uC788\uC5C8\uB2E4."@ko ;
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