An international team of scientists from Russia and the United States, including two Department of Energy national laboratories and two universities, has discovered the newest superheavy element（超重元素） , element 117. The team included scientists from the Joint¹ Institute of Nuclear Research (Dubna, Russia), the Research Institute for Advanced Reactors³ (Dimitrovgrad), Lawrence Livermore National Laboratory, Oak Ridge⁴ National Laboratory, Vanderbilt University, and the University of Nevada, Las Vegas.

Academician（院士，学会会员） Yuri Oganessian, scientific leader of the Flerov Laboratory of Nuclear Reactions at JINR and spokesperson for the collaboration⁵ said, "The discovery of element 117 is the culmination⁶（顶点，高潮） of a decade-long journey to expand the periodic table（周期表） and write the next chapter in heavy element research."

The team established the existence of element 117 from decay patterns observed following the bombardment（炮击，轰炸） of a radioactive berkelium（锫） target with calcium⁷（钙） ions at the JINR U400 cyclotron（回旋加速器） in Dubna. The experiment depended on the availability of special detection facilities and dedicated⁸ accelerator time at Dubna, unique isotope⁹（同位素） production and separation facilities at Oak Ridge, and distinctive¹⁰ nuclear data analysis capabilities¹¹ at Livermore.

"This is a significant breakthrough for science," LLNL director George Miller¹² said. "The discovery of a new element provides new insight into the makeup¹³ of the universe and is a testimony¹⁴ to the strength of science and technology at the partner institutions."

"This collaboration and the discovery of element 117 demonstrates the fundamental importance of scientists from different nations and institutions working together to address complex scientific challenges," ORNL Director Thom Mason said.

The two-year experimental campaign began at the High Flux¹⁵ Isotope Reactor² in Oak Ridge with a 250-day irradiation（照射，发光） in the world's most intense neutron¹⁶（中子） flux（流量，流出） to produce 22 mg of berkelium. This was followed by 90 days of processing at Oak Ridge to separate and purify the berkelium, target preparation at Dimitrovgrad, 150 days of bombardment at one of the world's most powerful heavy ion accelerators at Dubna, data analysis at Livermore and Dubna, and assessment¹⁷ and review of the results by the team. The entire process was driven by the 320-day half-life of the berkelium target material.

The experiment produced six atoms of element 117. For each atom, the team observed the alpha decay from element 117 to 115 to 113 and so on until the nucleus¹⁸ fissioned（分裂，分体） , splitting into two lighter¹⁹ elements. In total, 11 new "neutron-rich" isotopes²⁰ were produced, bringing researchers closer to the presumed "island of stability" of superheavy elements.

The island of stability is a term in nuclear physics that refers to the possible existence of a region beyond the current periodic table where new superheavy elements with special numbers of neutrons²¹ and protons would exhibit increased stability. Such an island would extend the periodic table to even heavier elements and support longer isotopic²² lifetimes to enable chemistry experiments.

Element 117 was the only missing element in row seven of the periodic table. On course to the island of stability, researchers initially²³ skipped element 117 due to the difficulty in obtaining the berkelium target material. The observed decay patterns in the new isotopes from this experiment, as close as researchers have ever approached the island of stability, continue a general trend of increasing stability for superheavy elements with increasing numbers of neutrons in the nucleus. This provides strong evidence for the existence of the island of stability.