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<b>Q, Break-even and the Lawson Diagram for Transient Fusion Plasmas
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Author: Dale M. Meade

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Q, break-even and the Lawson [n(tau)<sub>E</sub>] diagram are well defined and understood for steady-state fusion plasma conditions. Since many fusion experiments are transient, it is necessary to clarify the definitions for instantaneous Q values and break-even so that the Lawson diagram can be interpreted for transient plasma conditions. This discussion shows that there are two mathematically correct methods to describe the Lawson diagram for a transient plasma. The Lawson/TFTR method which is consistent with previous analyses of the Lawson cycle, and prior definitions for Q and break-even describes a transient fusion plasma in terms of Q = P<sub>fusion</sub>/P<sub>aux</sub> with the plasma energy confinement time for the n(tau) diagram given by (tau)<sub>E</sub><super>*</super> = W<sub>p</sub>/ P<sub>heat</sub> where W<sub>p</sub> is the total plasma kinetic energy and P<sub>heat</sub> = P<sub>aux</sub> + P<sub>alpha</sub> - P<sub>brem</sub> is the net power heating the plasma. In the Lawson/TFTR definition break-even (P<sub>fusion</sub> = P<sub>aux</sub>) occurs at Q = 1, ignition occurs at Q = infinity and the n(tau)<sub>E</sub><super>*</super> values required to achieve a given Q are the same in transient and steady-state plasmas. The JET/JT-60 method uses the definitions of Q* = P<sub>fusion</sub>/(P<sub>aux</sub> - dW<sub>p</sub>/dt) and (tau)<sub>E</sub> = W<sub>p</sub>/(P<sub>heat</sub> - dW<sub>p</sub>/dt). This method produces the confusing result that break-even requires Q* = P<sub>aux</sub>/(P<sub>aux</sub> - dW<sub>p</sub>/dt) which is >1 for many cases of interest. In addition, the Lawson value required to achieve break-even depends on dW<sub>p</sub>/dt and therefore experimental data points with different dW<sub>p</sub>/dt must be compared to different Q* curves on the Lawson diagram. For a pulsed plasma, this issue can be avoided by using the definition of fusion gain first introduced by Lawson, namely Q = fusion energy per pulse divided by auxiliary plasma heating energy supplied per pulse.