BEBC getting ready to operate

First tracks were taken in the 3.7 m Big European Bubble Chamber (BEBC) in March. A hydrogen leak that interrupted the tests was repaired quickly and operation continued up to 2.6 T. No troublesome effects appeared due to eddy currents in the metal piston that is temporarily replacing the plastic piston. BEBC has now been "warmed up" to receive the last touches before the physics programme is launched in about two months [with protons from the PS].

• Compiled from text on p109.


Gargamelle getting ready to operate again

The heavy-liquid bubble chamber Gargamelle is being prepared for operation again. Its first task will be to supply photographs of neutrino interactions in freon. Scheduled for December 1972, this had to be postponed because vibrations during expansion of the chamber led to fractures in some of the pipework of the pressure system.

The expansion system was completely dismantled during the annual PS shutdown (January and February). The trolley which carries the recompression tanks as well as the expansion tank and storage tanks were all rebuilt. The girders were reinforced and the whole structure was strengthened with struts. The trolley no longer stands on wheels but on supports set in the floor and has arms resting on the edge of the pit to prevent the assembly from moving during operation.

• Compiled from text on p112.


RCBC operating

At Stanford, the 15 inch Rapid Cycling Bubble Chamber (RCBC) is being used for physics for the first time. The experiment, carried out by a Purdue, Indiana, SLAC, Vanderbilt collaboration, began in March. It is a search for "exotic" mesons with double charge. The quark model maintains that mesons are built up of quark and antiquark pairs. Thus, since a quark is supposed to carry a charge of 1/3 or 2/3, no doubly charged mesons can be built up.

Observation of such mesons will obviously be extremely rare. So the rapid cycling chamber is used in a hybrid system with spark chambers, to select only likely events.

A beam of about 10 positive pions per pulse is fired into the chamber. If exotic mesons exist, they could appear as π+ + p → n + X++. The emerging neutron is converted into charged particles that fire an optical spark chamber.

It is expected that the hybrid system will be triggered once every 200 pulses. The collaboration is hoping to collect 100,000 pictures. Operation without the possibility to trigger the chamber would require collecting and analysing 20 million pictures.

• Compiled from texts on pp114–115.


Compiler’s Note

In the 30 years following their invention in the1950s, more than 100 bubble chambers were built and 100 million stereo photographs were taken.

Scientifically, among many seminal results was the discovery of the Omega-minus in the 80 inch hydrogen chamber at BNL, and the neutral weak current in Gargamelle at CERN.

Sociologically, effects were twofold. As chambers increased in size, they were housed as facilities in central laboratories and the community of users formed international collaborations. In addition, bubble-chamber photographs offered an intuitive view of subnuclear interactions that aided the public understanding of particle physics.

Technically, mainframe computing capacity at host labs grew to meet the needs of bubble-chamber physics, while smaller, dedicated, online computers became an integral part of film-scanning machines.