Research type Accelerator physics Director Pierluigi Campana Nickname LNF Date founded 8 August 1954 | Field of research Particle physics Location Frascati, Rome, Italy Phone +39 06 94031 Field of research Particle physics | |
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Established August 8, 1954 (as National Accelerator Laboratory) Address Via Enrico Fermi, 40, 00044 Frascati RM, Italy Hours Closed now Friday8AM–2:30PMSaturdayClosedSundayClosedMonday8AM–4PMTuesday8AM–4PMWednesday8AM–4PMThursday8AM–4PM Similar Liceo Classico Statale M, Liceo Scientifico Bruno To, Istituto Nazionale di Fisica, ITT Enrico Fermi Profiles | ||
Laboratori nazionali di frascati
The INFN National Laboratory of Frascati (LNF) was founded in 1954 with the objective of furthering particle physics research, and more specifically to host the 1.1 GeV electrosynchrotron, the first accelerator ever built in Italy. The Laboratory later developed the first ever electron-positron collider: from the first prototype AdA, which demonstrated the feasibility, to the ring ADONE and later on to DAΦNE, still operative today (2016). Besides conducting experiments with their own facilities, the LNF researchers are also taking part in extensive collaborations at external laboratories, especially at CERN and in the United States.
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History and Activity
The INFN National Laboratory of Frascati was founded in 1954 to host an electron synchrotron of 1.1 GeV. The synchrotron, built under the lead of Prof. Giorgio Salvini started working, generating gamma-ray bundles (even polarized) and electron beams in the experiments led by INFN researchers in collaboration with a number of Italian Universities.
In 1960, during a memorable seminar, Bruno Touschek proposed the idea of injecting in the same ring beams of electrons and positrons, circulating in opposite directions, to study their collisions. Hence, AdA (Anello di Accumulazione) was built, within a 1.5 m diameter electro-magnet where the radiofrequency field would accelerate the beams up to 250 MeV. AdA was later moved to the Laboratory of Orsay, Paris, which had a more powerful injector; here the first electron-positron collisions were detected.
AdA’s success led to the design of a more powerful machine: ADONE, with 4 experimental zones and energy beams of 1.5 GeV. ADONE started operating in 1969 and was permanently turned off in 1993. ADONE’s experiments revolved around quantum electrodynamics (QED) tests, proton and neutron form factors, muon study and multihadron production. That last one in particular, more abundant than anticipated, represented an important validation of the quark model and the color hypothesis.
In November 1974, within two days after the SLAC and BNL announcement, the LNF second generation experiments observed the J/ψ particle. In order to produce the J/ψ it was necessary to operate ADONE at about 100 MeV above its maximum nominal energy; that was the reason why the J/ψ hadn’t been found before by LNF experiments.
In 2002, in the same hall as ADONE, the latest machine, DAΦNE, entered in function. It had been designed to operate at Φ resonance, with incredibly intense beams, to search the CP violation in K neutral mesons (KLOE experiment). Many of the other DAΦNE experiments concerned the production of ipernuclei (FINUDA) and the study of kaonic atoms (DEAR, SIDDHARTA).
At the same time some of the LNF researchers took part in important foreign experiments: at CERN, in US laboratories (Fermilab, SLAC, Jefferson Lab), in Hamburg and recently even in Beijing and Japan.
At the moment the LNF participation in the experiments ATLAS, CMS, ALICE, and LHCb at the CERN LHC collider is especially relevant. Also important has been the role of the LNF in the experiments at the Laboratories of Gran Sasso: in particular, the recent experiment OPERA, with the neutrino beam produced at CERN.
At LNF, thanks to the presence of high technology support services, the experimental activity also takes on the design and development of detectors meant to be employed both at the local experiments and the external ones. An example for this is the cryogenic antenna Nautilus, devoted to the search for gravitational waves, involved in Einstein’s general relativity theory.
At the LNF a group of theoretical physicists is also operative. These researchers, in addition to leading independent research, offer guidance and expert advice to the experimental groups.
The design, building and work on the various LNF accelerators entailed the birth and development of a large number of physicists, engineers and technicians skilled in the physics of accelerators. This is a very important and unique resource of the LNF. From that skillfulness stemmed important external realizations, such as CNAO (Centro Nazionale di Adroterapia Oncologica) in Pavia, and collaborations on future sector developments, such as CLIC at CERN.
At the Laboratory new lines of research were also developed, in particular the test facility SPARC, which combines an electron beam of high brilliancy with high intensity, ultrafast laser pulses, devoted to research about plasma acceleration and Free Electron Laser (FEL).
An important role in the LNF’s activities is played by the dissemination of science. Seminars, meetings, refresher courses for high school teachers and general public events take place regularly, as well as school visits and stages for students. Furthermore, the "Open Day" and the participation to "European Researchers' Night" are regular appointments.
Personnel
The LNF staff can count on more than 350 people, divided in:
Besides the staff, the LNF also relies on host and associate personnel: students, doctoral candidates, as well as researchers from other Italian and international Institutions, who take part in the LNF activities.
Location and Infrastructures
The National Laboratory of Frascati is located about 20 km away from Rome, near the town of Frascati, in a 20 hectares area with wide green spaces. An auditorium able to host 300 visitors allows the LNF to host conferences of international interest.