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Peter Menzel Photography
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![Proton decay experiment to determine the ultimate stability of matter..Proton decay. A technician [works with] a 20" (50cm) photomultiplier tube used in the search for proton decay. Hundreds of such tubes line a tank containing 9000 tons of water some 1000 meters underground in a zinc mine in Japan. Tokyo University's Kamiokande experiment was designed to look for decaying protons. If a proton decays, the charged particles it generates move through the water faster than light, and so generate blue 'Cerenkov' radiation. It is this that the photomultipliers detect. Computers then decide whether the event was a decay, or a collision with a solar neutrino. Japan. (1985)](https://www.menzelphoto.com/img-get2/I0000uvdBlshQGUM/fill=/fit=180x180/I0000uvdBlshQGUM.jpg)
![Physics: Proton Decay control room. Cleveland, Ohio, Morton Salt Mine proton decay detector located 600 meters underground in the Morton salt mine near Cleveland, Ohio, which consists of a massive tank containing 21 cubic meters of ultra pure water, its walls lined with photomultiplier tubes, which detect faint flashes of Cerenkov light emitted by the passage of charged particles. [1985]](https://www.menzelphoto.com/img-get2/I0000hJiHKLWLWCk/fill=/fit=180x180/I0000hJiHKLWLWCk.jpg)
![Alan Weinstein from the Stanford Linear Collider (SLC) experiment, seen with a computer-simulated collision event between an electron and a positron. The SLC produces Z-zero particles by this collision process, which takes place at energies high enough for the electron and positron to annihilate one another, the Z-zero left decaying rapidly into another electron/positron pair or a quark/anti-quark pair. The Z-zero is one of the mediators of the weak nuclear force, the force behind radioactive decay, and was discovered at CERN in 1983. The first Z-zero seen at SLC was detected on 11 April 1989. MODEL RELEASED [1988] Menlo Park, California.](https://www.menzelphoto.com/img-get2/I0000.oMC.oP73Ow/fill=/fit=180x180/I0000.oMC.oP73Ow.jpg)
![Matthew Jones, wearing 3-D glasses to view computer simulations, from the Stanford Linear Collider (SLC) experiment, seen with a computer-simulated collision event between an electron and a positron. The SLC produces Z-zero particles by this collision process, which takes place at extremely high energies. The Z-zero is one of the mediators of the weak nuclear force, the force behind radioactive decay, and was discovered at CERN in 1983. The scientist is seen wearing special glasses that enable viewing of computer- generated stereoscopic images of the particle tracks following the collision inside the Large Detector. The first Z-zero seen at SLC was detected on 11 April 1989. MODEL RELEASED [1988]](https://www.menzelphoto.com/img-get2/I0000WrG0PRMxBA8/fill=/fit=180x180/I0000WrG0PRMxBA8.jpg)
![Physics: Stanford Linear Accelerator Center (SLAC) Helen Quinn, theoretician. Stanford Linear Collider (SLC) experiment, Menlo Park, California. With a length of 3km, the Stanford Linear Accelerator is the largest of its kind in the world. The accelerator is used to produce streams of electrons and positrons, which collide at a combined energy of 100 GeV (Giga electron Volts). This massive energy is sufficient to produce Z-zero particles in the collision. The Z-zero is one of the mediators of the weak nuclear force, the force behind radioactive decay, and was first discovered at CERN, Geneva, in 1983. The first Z-zero at SLC was produced on 11 April 1989. MODEL RELEASED [1986].](https://www.menzelphoto.com/img-get2/I0000cWHDUEHIQBo/fill=/fit=180x180/I0000cWHDUEHIQBo.jpg)
![Physics: Stanford Linear Accelerator Center (SLAC), Menlo Park, California. Control Room [1988]. Instrumentation displays inside the control room of the Stanford Linear Collider (SLC) experiment, Menlo Park, California. With a length of 3km, the Stanford Linear Accelerator is the largest of its kind in the world. The accelerator is used to produce streams of electrons and positrons, which collide at a combined energy of 100 GeV (Giga electron Volts). This massive energy is sufficient to produce Z-zero particles in the collision. The Z-zero is one of the mediators of the weak nuclear force, the force behind radioactive decay, and was first discovered at CERN, Geneva, in 1983. The first Z-zero at SLC was produced on 11 April 1989.](https://www.menzelphoto.com/img-get2/I0000b_6f7D1iczA/fill=/fit=180x180/I0000b_6f7D1iczA.jpg)
![Physics: Aligning Magnets in the 3 km tunnel of the Stanford Linear Accelerator Center (SLAC), Menlo Park, California. Reverse Bend SLC Experiment, [1986].Technicians making final alignment checks in the tunnel of the Stanford Linear Collider (SLC). The SLC was built from the 3km linear accelerator at Stanford, California. In the SLC, electrons and positrons are accelerated to energies of 50 giga electron volts (GeV) before being forced to collide. In this collision, a Z-nought particle may be produced. The Z-nought is the mediator of the electroweak nuclear force, the force behind radioactive decay. The first Z-nought was detected at SLC on 11 April 1989, six years after its discovery at the European LEP accelerator ring, near Geneva..](https://www.menzelphoto.com/img-get2/I00003t1ljYgF5oI/fill=/fit=180x180/I00003t1ljYgF5oI.jpg)
![Physics: Stanford Linear Accelerator Center (SLAC), Menlo Park, California. Control Room..Instrumentation displays inside the control room of the Stanford Linear Collider (SLC) experiment, California. With a length of 3km, the Stanford Linear Accelerator is the largest of its kind in the world. The accelerator is used to produce streams of electrons and positrons, which collide at a combined energy of 100 GeV (Giga electron Volts). This massive energy is sufficient to produce Z-zero particles in the collision. The Z-zero is one of the mediators of the weak nuclear force, the force behind radioactive decay, and was first discovered at CERN, Geneva, in 1983. The first Z-zero at SLC was produced on 11 April 1989. [1988]](https://www.menzelphoto.com/img-get2/I0000j1jacgZEQp8/fill=/fit=180x180/I0000j1jacgZEQp8.jpg)
![Physics: Stanford Linear Accelerator Center (SLAC). Electronics Trailer. J. Chapman checks myriad connections..Stanford Linear Collider (SLC) experiment, Menlo Park, California. With a length of 3km, the Stanford Linear Accelerator is the largest of its kind in the world. The accelerator is used to produce streams of electrons and positrons, which collide at a combined energy of 100 GeV (Giga electron Volts). This massive energy is sufficient to produce Z-zero particles in the collision. The Z-zero is one of the mediators of the weak nuclear force, the force behind radioactive decay, and was first discovered at CERN, Geneva, in 1983. The first Z-zero at SLC was produced on 11 April 1989. [1988]](https://www.menzelphoto.com/img-get2/I0000bLq9F4lmj04/fill=/fit=180x180/I0000bLq9F4lmj04.jpg)
![Physics: Stanford Linear Accelerator Center (SLAC). Rafe Schindler and Iris Abt with detector insert. Stanford Linear Collider (SLC) experiment, Menlo Park, California. With a length of 3km, the Stanford Linear Accelerator is the largest of its kind in the world. The accelerator is used to produce streams of electrons and positrons, which collide at a combined energy of 100 GeV (Giga electron Volts). This massive energy is sufficient to produce Z-zero particles in the collision. The Z-zero is one of the mediators of the weak nuclear force, the force behind radioactive decay, and was first discovered at CERN, Geneva, in 1983. The first Z-zero at SLC was produced on 11 April 1989. [1988]](https://www.menzelphoto.com/img-get2/I00002qZ5_N6ncO4/fill=/fit=180x180/I00002qZ5_N6ncO4.jpg)
![Physics: Stanford Linear Accelerator Center (SLAC). Large Detector construction: sorting through the tens of thousands of fittings. Stanford Linear Collider (SLC) experiment, Menlo Park, California. With a length of 3km, the Stanford Linear Accelerator is the largest of its kind in the world. The accelerator is used to produce streams of electrons and positrons, which collide at a combined energy of 100 GeV (Giga electron Volts). This massive energy is sufficient to produce Z-zero particles in the collision. The Z-zero is one of the mediators of the weak nuclear force, the force behind radioactive decay, and was first discovered at CERN, Geneva, in 1983. The first Z-zero at SLC was produced on 11 April 1989. [1988]](https://www.menzelphoto.com/img-get2/I000074_5qLYMp6o/fill=/fit=180x180/I000074_5qLYMp6o.jpg)
![Physics: Stanford Linear Accelerator Center (SLAC) Martin Perl, Physicist at SLAC..Stanford Linear Collider (SLC) experiment, Menlo Park, California. With a length of 3km, the Stanford Linear Accelerator is the largest of its kind in the world. The accelerator is used to produce streams of electrons and positrons, which collide at a combined energy of 100 GeV (Giga electron Volts). This massive energy is sufficient to produce Z-zero particles in the collision. The Z-zero is one of the mediators of the weak nuclear force, the force behind radioactive decay, and was first discovered at CERN, Geneva, in 1983. The first Z-zero at SLC was produced on 11 April 1989. MODEL RELEASED [1988]](https://www.menzelphoto.com/img-get2/I0000cptTX3uukG8/fill=/fit=180x180/I0000cptTX3uukG8.jpg)
![Matthew Jones, wearing 3-D glasses to view computer simulations, from the Stanford Linear Collider (SLC) experiment, seen with a computer-simulated collision event between an electron and a positron. The SLC produces Z-zero particles by this collision process, which takes place at extremely high energies. The Z-zero is one of the mediators of the weak nuclear force, the force behind radioactive decay, and was discovered at CERN in 1983. The scientist is seen wearing special glasses that enable viewing of computer- generated stereoscopic images of the particle tracks following the collision inside the Large Detector. The first Z-zero seen at SLC was detected on 11 April 1989. MODEL RELEASED [1988]](https://www.menzelphoto.com/img-get2/I0000QJ0Xl7YU5SQ/fill=/fit=180x180/I0000QJ0Xl7YU5SQ.jpg)
![Physics: Stanford Linear Accelerator Center (SLAC), Menlo Park, California. Large Detector Control Room. Instrumentation displays inside the control room of the Stanford Linear Collider (SLC) experiment, California. With a length of 3km, the Stanford Linear Accelerator is the largest of its kind in the world. The accelerator is used to produce streams of electrons and positrons, which collide at a combined energy of 100 GeV (Giga electron Volts). This massive energy is sufficient to produce Z-zero particles in the collision. The Z-zero is one of the mediators of the weak nuclear force, the force behind radioactive decay, and was first discovered at CERN, Geneva, in 1983. The first Z-zero at SLC was produced on 11 April 1989. [1988]](https://www.menzelphoto.com/img-get2/I00005dkpQGtnHOo/fill=/fit=180x180/I00005dkpQGtnHOo.jpg)
![Physics: Pat Burchat, with a computer simulation reflected in her glasses at the Stanford Linear Accelerator Center (SLAC) Large Detector. Computer Simulated Event. Stanford Linear Collider (SLC) experiment, Menlo Park, California. With a length of 3km, the Stanford Linear Accelerator is the largest of its kind in the world. The accelerator is used to produce streams of electrons and positrons, which collide at a combined energy of 100 GeV (Giga electron Volts). This massive energy is sufficient to produce Z-zero particles in the collision. The Z-zero is one of the mediators of the weak nuclear force, the force behind radioactive decay, and was first discovered at CERN, Geneva, in 1983. The first Z-zero at SLC was produced on 11 April 1989. MODEL RELEASED [1988]](https://www.menzelphoto.com/img-get2/I0000rpufq2Zpf.A/fill=/fit=180x180/I0000rpufq2Zpf.A.jpg)
