Twenty years ago, the construction of Joint European Torus (JET) began and 5 years later, the first plasma pulses were obtained. A highly successful series of high temperature plasma experiments which addressed all important issues of fusion physics, such as energy confinement, plasma heating and plasma--wall interaction, laid the foundation for a Preliminary Tritium Experiment in l99l, a three stage programme of progressively more closed divertors from l992 to l999, and an extended experimental campaign in deuterium--tritium (D--T) in autumn l997. The key physics results from JET are presented, emphasising the synergy between progress in physics and engineering, and the impact of the results on improving physics understanding and predictive capability. The physics discussion concentrates on confinement and performance issues in the H-mode and optimised shear regimes, the development of closed, highly radiating divertors, and results from the recent broad-based series of D--T experiments. The latter include records in fusion performance, the first clear demonstration of alpha particle heating, the testing of ion cyclotron resonance frequency heating scenarios in D--T and the characterisation of the ELMy H-mode in D--T, allowing more accurate predictions for the performance of the International Thermonuclear Experimental Reactor or any other Next Step device.
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