TY - JOUR
T1 - The modern era of light kaonic atom experiments
AU - Curceanu, Catalina
AU - Guaraldo, Carlo
AU - Iliescu, Mihail
AU - Cargnelli, Michael
AU - Hayano, Ryugo
AU - Marton, Johann
AU - Zmeskal, Johann
AU - Ishiwatari, Tomoichi
AU - Iwasaki, Masa
AU - Okada, Shinji
AU - Sirghi, Diana Laura
AU - Tatsuno, Hideyuki
PY - 2019/6
Y1 - 2019/6
N2 - This review covers the modern era of experimental kaonic atom studies, encompassing 20 years of activity, defined by breakthroughs in technological developments which allowed performing a series of long-awaited precision measurements. Kaonic atoms are atomic systems where an electron is replaced by a negatively charged kaon, containing the strange quark, which interacts in the lowest orbits with the nucleus also by the strong interaction. As a result, their study offers the unique opportunity to perform experiments equivalent to scattering at vanishing relative energy. This allows one to study the strong interaction between the antikaon and the nucleon or the nucleus "at threshold," namely, at zero relative energy, without the need of ad hoc extrapolation to zero energy, as in scattering experiments. The fast progress achieved in performing precision light kaonic atom experiments, which also solved long-pending inconsistencies with theoretical calculations generated by old measurements, relies on the development of novel cryogenic targets, x-ray detectors, and the availability of pure and intense charged kaon beams, which propelled an unprecedented progress in the field. Future experiments, based on new undergoing technological developments, will further boost the kaonic atom studies, thus fostering a deeper understanding of the low-energy strong interaction extended to the second family of quarks.
AB - This review covers the modern era of experimental kaonic atom studies, encompassing 20 years of activity, defined by breakthroughs in technological developments which allowed performing a series of long-awaited precision measurements. Kaonic atoms are atomic systems where an electron is replaced by a negatively charged kaon, containing the strange quark, which interacts in the lowest orbits with the nucleus also by the strong interaction. As a result, their study offers the unique opportunity to perform experiments equivalent to scattering at vanishing relative energy. This allows one to study the strong interaction between the antikaon and the nucleon or the nucleus "at threshold," namely, at zero relative energy, without the need of ad hoc extrapolation to zero energy, as in scattering experiments. The fast progress achieved in performing precision light kaonic atom experiments, which also solved long-pending inconsistencies with theoretical calculations generated by old measurements, relies on the development of novel cryogenic targets, x-ray detectors, and the availability of pure and intense charged kaon beams, which propelled an unprecedented progress in the field. Future experiments, based on new undergoing technological developments, will further boost the kaonic atom studies, thus fostering a deeper understanding of the low-energy strong interaction extended to the second family of quarks.
U2 - 10.1103/RevModPhys.91.025006
DO - 10.1103/RevModPhys.91.025006
M3 - Article
AN - SCOPUS:85070671126
SN - 0034-6861
VL - 91
JO - Reviews of Modern Physics
JF - Reviews of Modern Physics
IS - 2
M1 - 025006
ER -