Editing Albert Ghiorso (section)

===New elements===
After the war, Seaborg and Ghiorso returned to Berkeley, where they and colleagues used the 60" Crocker cyclotron to produce elements of increasing atomic number by bombarding exotic targets with helium ions. In experiments during 1949–1950, they produced and identified elements 97 ([[berkelium]]) and 98 ([[californium]]). In 1953, in a collaboration with Argonne Lab, Ghiorso and collaborators sought and found elements 99 ([[einsteinium]]) and 100 ([[fermium]]), identified by their characteristic radiation in dust collected by airplanes from the first thermonuclear explosion (the [[Ivy Mike|Mike test]]). In 1955, the group used the cyclotron to produce 17 atoms of element 101 ([[mendelevium]]), the first new element to be discovered atom-by-atom. The recoil technique invented by Ghiorso was crucial to obtaining an identifiable signal from individual atoms of the new element.
[[File:96904536.thumb3.jpeg|thumb|Ghiorso updates a periodic table in 1961 with the newly discovered element [[lawrencium]] while co-discoverers Robert Latimer, [[Torbjørn Sikkeland|Torbjorn Sikkeland]] and Almon Larsh look on.]]
In the mid-1950s it became clear that to extend the periodic chart any further, a new accelerator would be needed, and the Berkeley Heavy Ion Linear Accelerator (HILAC) was built, with Ghiorso in charge. That machine was used in the discovery of elements 102–106 (102, [[nobelium]]; 103, [[lawrencium]]; 104, [[rutherfordium]]; 105, [[dubnium]] and 106, [[seaborgium]]), each produced and identified on the basis of only a few atoms. The discovery of each successive element was made possible by the development of innovative techniques in robotic target handling, fast chemistry, efficient radiation detectors, and computer data processing. The 1972 upgrade of the HILAC to the superHILAC provided higher intensity ion beams, which was crucial to producing enough new atoms to enable detection of element 106.

With increasing atomic number, the experimental difficulties of producing and identifying a new element increase significantly. In the 1970s and 1980s, resources for new element research at Berkeley were diminishing, but the GSI laboratory at Darmstadt, Germany, under the leadership of Peter Armbruster and with considerable resources, was able to produce and identify elements 107–109 (107, [[bohrium]]; 108, [[hassium]] and 109, [[meitnerium]]). In the early 1990s, the Berkeley and Darmstadt groups made a collaborative attempt to create element 110. Experiments at Berkeley were unsuccessful, but eventually elements 110–112 (110, [[darmstadtium]]; 111, [[roentgenium]] and 112, [[copernicium]]) were identified at the Darmstadt laboratory. Subsequent work at the JINR laboratory at Dubna, led by Yuri Oganessian and a Russian-American team of scientists, was successful in identifying elements 113–118 (113, [[nihonium]]; 114, [[flerovium]]; 115, [[moscovium]]; 116, [[livermorium]]; 117, [[tennessine]] and 118, [[oganesson]]), thereby completing the [[Period 7 element]]s of the periodic table of the elements.