Bạn đang xem: nguyên tử lượng là gì
This article needs vĩ đại be updated. The reason given is: it needs vĩ đại reflect the 2019 redefinition of the SI base units, which came into effect on trăng tròn May 2019. Please help update this article vĩ đại reflect recent events or newly available information. (January 2020)
The atomic mass (ma or m) is the mass of an atom. Although the SI unit of mass is the kilogram (symbol: kg), atomic mass is often expressed in the non-SI unit dalton (symbol: Da) – equivalently, unified atomic mass unit (u). 1 Da is defined as 1⁄12 of the mass of a không tính tiền carbon-12 atom at rest in its ground state. The protons and neutrons of the nucleus tài khoản for nearly all of the total mass of atoms, with the electrons and nuclear binding energy making minor contributions. Thus, the numeric value of the atomic mass when expressed in daltons has nearly the same value as the mass number. Conversion between mass in kilograms and mass in daltons can be done using the atomic mass constant .
The formula used for conversion is:
where is the molar mass constant, is the Avogadro constant, and is the experimentally determined molar mass of carbon-12.
The relative isotopic mass (see section below) can be obtained by dividing the atomic mass ma of an isotope by the atomic mass constant mu yielding a dimensionless value. Thus, the atomic mass of a carbon-12 atom is 12 Da by definition, but the relative isotopic mass of a carbon-12 atom is simply 12. The sum of relative isotopic masses of all atoms in a molecule is the relative molecular mass.
The atomic mass of an isotope and the relative isotopic mass refers vĩ đại a certain specific isotope of an element. Because substances are usually not isotopically pure, it is convenient vĩ đại use the elemental atomic mass which is the average (mean) atomic mass of an element, weighted by the abundance of the isotopes. The dimensionless (standard) atomic weight is the weighted mean relative isotopic mass of a (typical naturally occurring) mixture of isotopes.
The atomic mass of atoms, ions, or atomic nuclei is slightly less kêu ca the sum of the masses of their constituent protons, neutrons, and electrons, due vĩ đại binding energy mass loss (per E = mc2).
Relative isotopic mass
Relative isotopic mass (a property of a single atom) is not vĩ đại be confused with the averaged quantity atomic weight (see above), that is an average of values for many atoms in a given sample of a chemical element.
While atomic mass is an absolute mass, relative isotopic mass is a dimensionless number with no units. This loss of units results from the use of a scaling ratio with respect vĩ đại a carbon-12 standard, and the word "relative" in the term "relative isotopic mass" refers vĩ đại this scaling relative vĩ đại carbon-12.
The relative isotopic mass, then, is the mass of a given isotope (specifically, any single nuclide), when this value is scaled by the mass of carbon-12, where the latter has vĩ đại be determined experimentally. Equivalently, the relative isotopic mass of an isotope or nuclide is the mass of the isotope relative vĩ đại 1/12 of the mass of a carbon-12 atom.
For example, the relative isotopic mass of a carbon-12 atom is exactly 12. For comparison, the atomic mass of a carbon-12 atom is exactly 12 daltons. Alternately, the atomic mass of a carbon-12 atom may be expressed in any other mass units: for example, the atomic mass of a carbon-12 atom is 1.99264687992(60)×10−26 kg.
As is the case for the related atomic mass when expressed in daltons, the relative isotopic mass numbers of nuclides other kêu ca carbon-12 are not whole numbers, but are always close vĩ đại whole numbers. This is discussed fully below.
Similar terms for different quantities
The atomic mass or relative isotopic mass are sometimes confused, or incorrectly used, as synonyms of relative atomic mass (also known as atomic weight) or the standard atomic weight (a particular variety of atomic weight, in the sense that it is standardized). However, as noted in the introduction, atomic mass is an absolute mass while all other terms are dimensionless. Relative atomic mass and standard atomic weight represent terms for (abundance-weighted) averages of relative atomic masses in elemental samples, not for single nuclides. As such, relative atomic mass and standard atomic weight often differ numerically from the relative isotopic mass.
The atomic mass (relative isotopic mass) is defined as the mass of a single atom, which can only be one isotope (nuclide) at a time, and is not an abundance-weighted average, as in the case of relative atomic mass/atomic weight. The atomic mass or relative isotopic mass of each isotope and nuclide of a chemical element is, therefore, a number that can in principle be measured vĩ đại high precision, since every specimen of such a nuclide is expected vĩ đại be exactly identical vĩ đại every other specimen, as all atoms of a given type in the same energy state, and every specimen of a particular nuclide, are expected vĩ đại be exactly identical in mass vĩ đại every other specimen of that nuclide. For example, every atom of oxygen-16 is expected vĩ đại have exactly the same atomic mass (relative isotopic mass) as every other atom of oxygen-16.
In the case of many elements that have one naturally occurring isotope (mononuclidic elements) or one dominant isotope, the difference between the atomic mass of the most common isotope, and the (standard) relative atomic mass or (standard) atomic weight can be small or even nil, and does not affect most bulk calculations. However, such an error can exist and even be important when considering individual atoms for elements that are not mononuclidic.
For non-mononuclidic elements that have more kêu ca one common isotope, the numerical difference in relative atomic mass (atomic weight) from even the most common relative isotopic mass, can be half a mass unit or more (e.g. see the case of chlorine where atomic weight and standard atomic weight are about 35.45). The atomic mass (relative isotopic mass) of an uncommon isotope can differ from the relative atomic mass, atomic weight, or standard atomic weight, by several mass units.
Relative isotopic masses are always close vĩ đại whole-number values, but never (except in the case of carbon-12) exactly a whole number, for two reasons:
- protons and neutrons have different masses, and different nuclides have different ratios of protons and neutrons.
- atomic masses are reduced, vĩ đại different extents, by their binding energies.
The ratio of atomic mass vĩ đại mass number (number of nucleons) varies from 0.9988381346(51) for 56Fe vĩ đại 1.007825031898(14) for 1H.
Any mass defect due vĩ đại nuclear binding energy is experimentally a small fraction (less kêu ca 1%) of the mass of an equal number of không tính tiền nucleons. When compared vĩ đại the average mass per nucleon in carbon-12, which is moderately strongly-bound compared with other atoms, the mass defect of binding for most atoms is an even smaller fraction of a dalton (unified atomic mass unit, based on carbon-12). Since không tính tiền protons and neutrons differ from each other in mass by a small fraction of a dalton (1.38844933(49)×10−3 Da), rounding the relative isotopic mass, or the atomic mass of any given nuclide given in daltons vĩ đại the nearest whole number, always gives the nucleon count, or mass number. Additionally, the neutron count (neutron number) may then be derived by subtracting the number of protons (atomic number) from the mass number (nucleon count).
The amount that the ratio of atomic masses vĩ đại mass number deviates from 1 is as follows: the deviation starts positive at hydrogen-1, then decreases until it reaches a local minimum at helium-4. Isotopes of lithium, beryllium, and boron are less strongly bound kêu ca helium, as shown by their increasing mass-to-mass number ratios.
At carbon, the ratio of mass (in daltons) vĩ đại mass number is defined as 1, and after carbon it becomes less kêu ca one until a minimum is reached at iron-56 (with only slightly higher values for iron-58 and nickel-62), then increases vĩ đại positive values in the heavy isotopes, with increasing atomic number. This corresponds vĩ đại the fact that nuclear fission in an element heavier kêu ca zirconium produces energy, and fission in any element lighter kêu ca niobium requires energy. On the other hand, nuclear fusion of two atoms of an element lighter kêu ca scandium (except for helium) produces energy, whereas fusion in elements heavier kêu ca calcium requires energy. The fusion of two atoms of 4He yielding beryllium-8 would require energy, and the beryllium would quickly fall apart again. 4He can fuse with tritium (3H) or with 3He; these processes occurred during Big Bang nucleosynthesis. The formation of elements with more kêu ca seven nucleons requires the fusion of three atoms of 4He in the triple alpha process, skipping over lithium, beryllium, and boron vĩ đại produce carbon-12.
Here are some values of the ratio of atomic mass vĩ đại mass number:
|Nuclide||Ratio of atomic mass vĩ đại mass number|
Measurement of atomic masses
Direct comparison and measurement of the masses of atoms is achieved with mass spectrometry.
Relationship between atomic and molecular masses
Similar definitions apply vĩ đại molecules. One can calculate the molecular mass of a compound by adding the atomic masses (not the standard atomic weights) of its constituent atoms. Conversely, the molar mass is usually computed from the standard atomic weights (not the atomic or nuclide masses). Thus, molecular mass and molar mass differ slightly in numerical value and represent different concepts. Molecular mass is the mass of a molecule, which is the sum of its constituent atomic masses. Molar mass is an average of the masses of the constituent molecules in a chemically pure but isotopically heterogeneous ensemble. In both cases, the multiplicity of the atoms (the number of times it occurs) must be taken into tài khoản, usually by multiplication of each unique mass by its multiplicity.
The first scientists vĩ đại determine relative atomic masses were John Dalton and Thomas Thomson between 1803 and 1805 and Jöns Jakob Berzelius between 1808 and 1826. Relative atomic mass (Atomic weight) was originally defined relative vĩ đại that of the lightest element, hydrogen, which was taken as 1.00, and in the 1820s, Prout's hypothesis stated that atomic masses of all elements would prove vĩ đại be exact multiples of that of hydrogen. Berzelius, however, soon proved that this was not even approximately true, and for some elements, such as chlorine, relative atomic mass, at about 35.5, falls almost exactly halfway between two integral multiples of that of hydrogen. Still later, this was shown vĩ đại be largely due vĩ đại a mix of isotopes, and that the atomic masses of pure isotopes, or nuclides, are multiples of the hydrogen mass, vĩ đại within about 1%.
In the 1860s, Stanislao Cannizzaro refined relative atomic masses by applying Avogadro's law (notably at the Karlsruhe Congress of 1860). He formulated a law vĩ đại determine relative atomic masses of elements: the different quantities of the same element contained in different molecules are all whole multiples of the atomic weight and determined relative atomic masses and molecular masses by comparing the vapor mật độ trùng lặp từ khóa of a collection of gases with molecules containing one or more of the chemical element in question.
In the 20th century, until the 1960s, chemists and physicists used two different atomic-mass scales. The chemists used an "atomic mass unit" (amu) scale such that the natural mixture of oxygen isotopes had an atomic mass 16, while the physicists assigned the same number 16 vĩ đại only the atomic mass of the most common oxygen isotope (16O, containing eight protons and eight neutrons). However, because oxygen-17 and oxygen-18 are also present in natural oxygen this led vĩ đại two different tables of atomic mass. The unified scale based on carbon-12, 12C, met the physicists' need vĩ đại base the scale on a pure isotope, while being numerically close vĩ đại the chemists' scale. This was adopted as the 'unified atomic mass unit'. The current International System of Units (SI) primary recommendation for the name of this unit is the dalton and symbol 'Da'. The name 'unified atomic mass unit' and symbol 'u' are recognized names and symbols for the same unit.
The term atomic weight is being phased out slowly and being replaced by relative atomic mass, in most current usage. This shift in nomenclature reaches back vĩ đại the 1960s and has been the source of much debate in the scientific community, which was triggered by the adoption of the unified atomic mass unit and the realization that weight was in some ways an inappropriate term. The argument for keeping the term "atomic weight" was primarily that it was a well understood term vĩ đại those in the field, that the term "atomic mass" was already in use (as it is currently defined) and that the term "relative atomic mass" might be easily confused with relative isotopic mass (the mass of a single atom of a given nuclide, expressed dimensionlessly relative vĩ đại 1/12 of the mass of carbon-12; see section above).
In 1979, as a compromise, the term "relative atomic mass" was introduced as a secondary synonym for atomic weight. Twenty years later the primacy of these synonyms was reversed, and the term "relative atomic mass" is now the preferred term.
However, the term "standard atomic weights" (referring vĩ đại the standardized expectation atomic weights of differing samples) has not been changed, because simple replacement of "atomic weight" with "relative atomic mass" would have resulted in the term "standard relative atomic mass."
- Atomic number
- Dalton (unit)
- Isotope geochemistry
- Molecular mass
- Jean Stas
- ^ IUPAC, Compendium of Chemical Terminology, 2nd ed. (the "Gold Book") (1997). Online corrected version: (2006–) "atomic mass". doi:10.1351/goldbook.A00496
- ^ "DOE Explains...Nuclei". Energy.gov. Retrieved 2023-04-13.
- ^ The International System of Units (SI). v1.06 (9 ed.). Paris: Bureau International des Poids et Mesures. 2019. ISBN 978-92-822-2272-0.
- ^ Peter J. Mohr, Barry N. Taylor (May trăng tròn, 2019). "NIST Standard Reference Database 121. Fundamental Physical Constants. atomic mass constant". The NIST reference on constants, Units and Uncertainty. National Institute of Standards and Technology. Retrieved December 10, 2019.
- ^ "Avogadro constant". The NIST Reference on Constants, Units, and Uncertainty. May 2019. Archived from the original on 2000-10-25. Retrieved 24 June 2021.
- ^ "Molar mass of carbon-12". The NIST Reference on Constants, Units, and Uncertainty. May 2019. Archived from the original on 2000-12-06. Retrieved 24 June 2021.
- ^ "Proton mass in u". The NIST Reference on Constants, Units, and Uncertainty. May 2019. Archived from the original on 2000-12-07. Retrieved 24 June 2021.
- ^ "neutron mass in u". The NIST Reference on Constants, Units, and Uncertainty. May 2019. Archived from the original on 2000-12-07. Retrieved 24 June 2021.
- ^ "Neutron-proton mass difference in u". The NIST Reference on Constants, Units, and Uncertainty. May 2019. Archived from the original on 2012-09-05. Retrieved 24 June 2021.
- ^ Wang, Meng; Huang, W. J.; Kondev, F. G.; Audi, G.; Naimi, S. (March 2021). "The AME 2020 atomic mass evaluation (II). Tables, graphs and references\ast". Chinese Physics C. 45 (3): 030003. doi:10.1088/1674-1137/abddaf. hdl:11858/00-001M-0000-0010-23E8-5. ISSN 1674-1137. S2CID 235282522.
- ^ Williams, Andrew (2007). "Origin of the Formulas of Dihydrogen and Other Simple Molecules". J. Chem. Educ. 84 (11): 1779. Bibcode:2007JChEd..84.1779W. doi:10.1021/ed084p1779.
- ^ Bureau International des Poids et Mesures (2019): The International System of Units (SI), 9th edition, English version, page 134. Available at the BIPM trang web.
- ^ De Bievre, Phường.; Peiser, H. S. (1992). "'Atomic weight': The name, its history, definition, and units" (PDF). Pure Appl. Chem. 64 (10): 1535. doi:10.1351/pac199264101535. S2CID 96317287.
- NIST relative atomic masses of all isotopes and the standard atomic weights of the elements
- AME2003 Atomic Mass Evaluation Archived 2019-01-11 at the Wayback Machine from the National Nuclear Data Center