With the success of the Manhattan Project and the Radiation Laboratory, MIT moved into a new era of "
big science" funded by the US government. MIT's expansion in nuclear physics was spearheaded by
Jerrold R. Zacharias, who went to Los Alamos late in the war, and recruited
Viki Weisskopf and Rossi as MIT professors. Rossi left Los Alamos for Cambridge on 6 February 1946. Within the new
Laboratory for Nuclear Science, headed by Zacharias, Rossi was delegated to create a
cosmic ray research group at MIT. To help, he recruited four young scientists who had been at Los Alamos as PhD candidates:
Herbert S. Bridge, Matthew Sands, Robert Thompson and Robert Williams. Two who had been in the Radiation Laboratory also came to work with him: John Tinlot and Robert Hulsizer. All six were more mature than typical graduate students, for they had several years of wartime research experience. Consequently, they were paid a stipend similar to that of a
postdoctoral researcher, which was funded by the
Office of Naval Research and enabled them to support families during their graduate studies. For this new phase of his activities, Rossi made a fundamental change of approach. In his words:
Elementary Particles With the discovery of the pion in 1947, the search for new
elementary particles became a popular research topic. By operating fast ionisation chambers within a cloud chamber, Herbert showed that the bursts of ionisation they recorded were primarily produced by relatively low-energy cosmic rays, whose nuclear interactions typically involve the ejection of several
heavily ionising nuclear fragments. On the basis of this effect, he and Rossi demonstrated that the behaviour of these interactions is similar to that of penetrating showers. Rossi's group focused on the use of cloud chambers to study their properties and interactions. In 1948, with the aid of a multi-plate cloud chamber in which lead plates alternated with aluminium ones, Gregory, Rossi and Tinlot showed that the source of the electromagnetic component of cosmic ray interactions was predominantly energetic photons, rather than electrons. This result confirmed Oppenheimer's suggestion of 1947 that neutral pions are produced in interactions, along with charged ones, and that this component arises from their rapid decay into photons. To study the new elementary particles, Bridge and Martin Annis operated a large rectangular multiplate cloud chamber at Echo Lake. This investigation provided the basis for a 1951 PhD thesis by Annis, supervised by Rossi. The next year, these authors, with another student of Rossi's, Stanislaw Olbert, showed how to derive information on particle energies from measurements of their
multiple scattering. This added another way to use cloud chambers to measure the properties of elementary particles. In early 1953, with Bridge, Richard Safford and
Charles Peyrou, Rossi published results of a comprehensive cloud chamber study of the elementary particles that became known as
kaons. Peyrou was a visitor from at the
École Polytechnique, where he had obtained an accurate value of the muon mass in 1947, and Safford was Rossi's student.
Bagnères-de-Bigorre conference By 1952, a bewildering "zoo" of elementary particles had been reported, with various masses, decay schemes, nomenclature and reliability of identification. To deal with this situation, Blackett and Leprince-Ringuet organised an
International Cosmic Ray Conference at
Bagnères-de-Bigorre in 1953. According to
James Cronin, "this conference can be placed in importance in the same category as two other famous conferences, the
Solvay congress of 1927 and the
Shelter Island Conference of 1948." Leprince-Ringuet asked Rossi to give a summary of new information presented at the conference and to propose
nomenclature for the new particles. Before the conference, in response to the latter assignment, Rossi circulated a suggestion that particles with mass smaller than that of a neutron be designated by small
Greek letters and those with larger mass be designated by capital Greek letters. In his talk, on 11 July 1953, he reported that conference results, which he had compiled with the aid of Powell and Fretter, were consistent with this scheme, which was commonly used afterwards. A highlight was Leprince-Ringuet's declaration in his closing talk that: "...in the future we must use particle accelerators". With the 3 GeV
Cosmotron already in operation at
Brookhaven National Laboratory, this declaration reflected a consensus among the participants. As a result, Rossi's group began to wind down their cloud chamber experiments. However, in 1954, Bridge, Hans Courant, Herbert DeStaebler, Jr. and Rossi reported on an unusual event in which a stopping singly charged particle decayed into three photons whose energies totalled more than the proton rest energy. This is the signature of an
antiproton annihilation. The next year, a group led by
Owen Chamberlain and Emilio Segrè detected antiprotons, for which they were awarded the Nobel Prize in Physics in 1960.
Extensive air showers By the time of the Bagnères-de-Bigorre conference, Rossi had already turned his attention toward the astrophysical implications of cosmic ray phenomena, particularly extensive air showers. After Rossi's recognition, in Eritrea, that these events exist, they were extensively studied by
Pierre Auger, and by Williams. At this time, the extremely fast response of the newly developed
scintillation counters offered a new way to study the structure of air showers. To do this, Rossi enlisted his student,
George W. Clark, who completed a PhD in 1952, and Piero Bassi, who was a visitor from the University of Padua. Because solid scintillating material was unavailable, they decided to use
terphenyl dissolved in
benzine, which is an efficient
liquid scintillator. With the aid of three counters deployed on the roof of the MIT Physics building during the winter of 1952/53, they found that shower particles arrived within only one or two meters of a disk, which travels at nearly the speed of light in the direction of the shower axis. This result showed that scintillation counters can not only determine the arrival times of shower disks at many detectors spread over a large area, but also estimate the number of particles striking each detector. These capabilities combine the "fast-timing" method of determining shower arrival directions with the density sampling method of determining their size and the location of their axes.
Agassiz experiment With this progress, Rossi's group began a major experiment that could measure both primary energies and arrival directions of extensive air showers. Participating in this effort were: George Clark, William Kraushaar,
John Linsley, James Earl, and Frank Scherb. Kraushaar came to MIT from Cornell in 1949, after earning his PhD under Kenneth Greisen. With the support of Professor
Donald Menzel, who was director of the
Harvard College Observatory, Rossi's group deployed fifteen liquid scintillators, of area , on the wooded grounds of the observatory's
Agassiz station. The signals were brought on cables to a
Quonset hut, where they were displayed on fifteen
oscillographs and recorded photographically. Shortly after the experiment began to record shower data, lightning ignited the flammable liquid of one of the counters. Local firemen quickly extinguished the resulting fire before it spread to nearby trees, which were soaked with rainwater. Because the trees played an essential role in suppressing atmospheric convection that would degrade telescopic observations, Harvard and MIT carried out tense negotiations until an elaborate system of fire protection was installed, and the experiment was allowed to resume. To eliminate the threat of fire, Clark, Frank Scherb and William B. Smith created a "factory" that made nonflammable plastic scintillator disks, whose thickness was and whose diameter was approximately . After a switch to plastic in the late spring of 1956, the experiment ran continuously. Its findings were reported in
Nature and the
Physical Review. The most important results were summarized by Rossi as: As the Agassiz experiment came to an end, the group realised that observations near the equator and in the southern hemisphere were needed to extend their conclusion that air shower arrival directions are nearly isotropic. Consequently, Clark, in collaboration with
Vikram Sarabhai, ran his smaller experiment at
Kodaikanal, India, at a latitude of 10° N, and confirmed the absence of anisotropies. Later, at the suggestion of Ismael Escobar, the Agassiz equipment was moved to
El Alto at 4200 metres on the
Bolivian plateau at 16° S. Here, Clark, Escobar and Juan Hersil found no anisotropies, but they showed that the structure of air showers at their maximum development is different from that at sea level.
Volcano Ranch experiment The maximum energy of a particle recorded by Agassiz experiment, 1019 electron volt, is close to energies beyond which charged particles can not be confined to the
galactic disc by typical interstellar magnetic fields of 10−5
gauss. A detector array of very large dimensions is needed to detect showers of these energies. John Linsley agreed to take on the responsibility for building such an array. He came to MIT in 1954 from the
University of Minnesota, where he completed a PhD under
Edward P. Ney. Soon, he was joined by
Livio Scarsi, whom Rossi had recruited from Occhialini's group at the
University of Milan. Because no large enough tract of open land was available near Boston, the array was constructed on a semi-desert property known as
Volcano Ranch, about west of
Albuquerque, New Mexico, at an altitude of . During 1957 and 1958, Linsley and Scarsi deployed 19 scintillation counters, which used fluorescent plastic disks similar to those of the Agassiz detectors, except that each counter incorporated four disks viewed by four photomultipliers. Initially the area of the array was 2.5*106 m2, which is to be compared with Agassiz's 105 m2, but in 1960, after Scarsi had returned to
Milan, Linsley spread the detectors over an area of 107 m2. Results from the
Volcano Ranch experiment showed that the cosmic-ray intensity decreases smoothly with energy from 1017 - 1018 electron volt. and that primaries in this range arrive isotropically. Of particular significance was the detection of a single particle whose energy of 1020 electron volt is larger than the maximum that could be contained in the galactic disc by galactic magnetic fields. Particles of these energies can only originate in the
galactic halo or from
beyond the galaxy, and their existence is not consistent with the
Greisen-Zatsepin-Kuzmin limit.
Space plasma research On 4 October 1957, the
Soviet Union launched the first
artificial Earth satellite,
Sputnik 1. This event began the
Sputnik crisis, a "wave of near-hysteria" among a surprised American public. In response, the U.S. government increased funding for the
National Science Foundation, and in 1958, created both the
National Aeronautics and Space Administration (NASA) and the
Advanced Research Projects Agency, which was renamed the Defense Advanced Research Projects Agency (DARPA) in 1972. On 4 June 1958, two days after legislation creating NASA was introduced,
Detlev W. Bronk, chairman of the
National Academy of Sciences, met with the heads of these three agencies to create a new advisory body, the Space Science Board, to provide advice for the expansion of space research and to make sure that funding of fundamental science would be properly emphasized. The Board convened for its first meeting on 27 June 1958. Only four members were already engaged in space research: Rossi,
Leo Goldberg,
John Simpson, and
James Van Allen. Rossi formed a subcommittee which included
Thomas Gold,
Philip Morrison and biologist
Salvador Luria, who agreed that investigations of plasma in interplanetary space would be desirable. Consequently, Rossi decided to turn his group's efforts towards its study. With Herbert Bridge, Rossi designed and tested a plasma probe based on the classical
Faraday cup. However, to enhance the instrument's response to positively charged
protons and to suppress its response to
photoelectrons produced by sunlight, four grids were deployed within the cup. A key innovation was a modulating voltage applied to one of the grids, which converted the signal into an
alternating current, proportional to the proton flux and uncontaminated by any contribution of photoelectrons. After intense lobbying of
Homer Newell, NASA's deputy director of space flight programs, Rossi secured a flight opportunity on
Explorer 10, "
Goddard's first home-grown satellite". The unannounced goal was to hit the Moon, but after launch on 25 March 1961, the satellite went into a highly elongated orbit around Earth, whose
apogee, at 70% of the distance to the Moon, was well short of this goal. Nevertheless, during 52 hours of data recorded by the MIT probe before battery power ran out, Rossi's group found a transition between two distinct regions around Earth. Near Earth, there were fairly strong and well-organised magnetic fields, but no indication of interplanetary protons. At 22 Earth radii, the spacecraft entered a region where magnetic fields were weaker and more irregular, and where a substantial flux of protons was observed coming from the general direction of the Sun. On several occasions during the rest of the flight, this flux disappeared and then reappeared again, which indicated that the spacecraft was flying close to the boundary between the two regions and that this boundary was moving irregularly. Eventually, this boundary became known as the
magnetopause. Under Bridge and Rossi, the MIT space plasma group included Frank Scherb, Edwin Lyon, Alan Lazarus, Alberto Bonnetti, Alberto Egidi, John Belcher and
Constance Dilworth, who was Occhialini's wife. Its Faraday cups have collected data on plasma throughout the Solar System: near Earth on
OGO-1, OGO 3 and IMP 8, in
interplanetary space on
WIND, and in the
Heliosphere and
Heliosheath on
Voyager 1 and
Voyager 2.
X-Ray astronomy discusses the X-ray Explorer Satellite's performance with Bruno Rossi during preflight tests at NASA's
Goddard Space Flight Center As a consultant to
American Science and Engineering, Inc., Rossi initiated the rocket experiments that discovered the first extra-solar source of
X-rays,
Scorpius X-1. Rossi was made
institute professor at MIT in 1966.
Retirement Rossi retired from MIT in 1970. From 1974 to 1980, he taught at the University of Palermo. In retirement, he wrote a number of monographs and a 1990 autobiography,
Moments in the Life of a Scientist, which was published by
Cambridge University Press. He died from a
cardiac arrest at his home in Cambridge on 21 November 1993. He was survived by his wife, Nora, daughters Florence and Linda and son Frank. He was cremated, and his ashes are in the graveyard of the church of
San Miniato al Monte, which overlooks Florence and the hill of Arcetri. == Honors and awards ==