The periodic table and the physics that drives it

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Schwerdtfeger , P , Smits , O R & Pyykkö , P 2020 , ' The periodic table and the physics that drives it ' , Nature reviews chemistry , vol. 4 , no. 7 , pp. 359-380 . https://doi.org/10.1038/s41570-020-0195-y

Title: The periodic table and the physics that drives it
Author: Schwerdtfeger, Peter; Smits, Odile R.; Pyykkö, Pekka
Contributor: University of Helsinki, Department of Chemistry
Date: 2020-07
Language: eng
Number of pages: 22
Belongs to series: Nature reviews chemistry
URI: http://hdl.handle.net/10138/323849
Abstract: As the International Year of the Periodic Table came to an end in 2019, the authors reflect on the chemistry and physics that drive the periodic table of the elements. This includes aspects of periodic trends, relativistic electronic-structure theory, nuclear-structure theory and the astrophysical origin of the elements. Mendeleev's introduction of the periodic table of elements is one of the most important milestones in the history of chemistry, as it brought order into the known chemical and physical behaviour of the elements. The periodic table can be seen as parallel to the Standard Model in particle physics, in which the elementary particles known today can be ordered according to their intrinsic properties. The underlying fundamental theory to describe the interactions between particles comes from quantum theory or, more specifically, from quantum field theory and its inherent symmetries. In the periodic table, the elements are placed into a certain period and group based on electronic configurations that originate from the Pauli and Aufbau principles for the electrons surrounding a positively charged nucleus. This order enables us to approximately predict the chemical and physical properties of elements. Apparent anomalies can arise from relativistic effects, partial-screening phenomena (of type lanthanide contraction) and the compact size of the first shell of everyl-value. Further, ambiguities in electron configurations and the breakdown of assigning a dominant configuration, owing to configuration mixing and dense spectra for the heaviest elements in the periodic table. For the short-lived transactinides, the nuclear stability becomes an important factor in chemical studies. Nuclear stability, decay rates, spectra and reaction cross sections are also important for predicting the astrophysical origin of the elements, including the production of the heavy elements beyond iron in supernova explosions or neutron-star mergers. In this Perspective, we critically analyse the periodic table of elements and the current status of theoretical predictions and origins for the heaviest elements, which combine both quantum chemistry and physics.
Subject: GIANT BRANCH STARS
COUPLED-CLUSTER CALCULATIONS
DIRECT MASS MEASUREMENTS
SUPERHEAVY ELEMENTS
ELECTRONIC-STRUCTURE
NEUTRON-CAPTURE
AB-INITIO
S-PROCESS
PROCESS NUCLEOSYNTHESIS
MOLECULAR-PROPERTIES
116 Chemical sciences
114 Physical sciences
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