--- title: "Lawson criterion" sort_title: "Lawson criterion" date: 2021-10-06 categories: - Physics - Plasma physics layout: "concept" --- For sustained nuclear fusion to be possible, the **Lawson criterion** must be met, from which some required properties of the plasma and the reactor chamber can be deduced. Suppose that a reactor generates a given power $$P_\mathrm{fus}$$ by nuclear fusion, but that it leaks energy at a rate $$P_\mathrm{loss}$$ in an unusable way. If an auxiliary input power $$P_\mathrm{aux}$$ sustains the fusion reaction, then the following inequality must be satisfied in order to have harvestable energy: $$\begin{aligned} P_\mathrm{loss} \le P_\mathrm{fus} + P_\mathrm{aux} \end{aligned}$$ We can rewrite $$P_\mathrm{aux}$$ using the definition of the **energy gain factor** $$Q$$, which is the ratio of the output and input powers of the fusion reaction: $$\begin{aligned} Q \equiv \frac{P_\mathrm{fus}}{P_\mathrm{aux}} \quad \implies \quad P_\mathrm{aux} = \frac{P_\mathrm{fus}}{Q} \end{aligned}$$ Returning to the inequality, we can thus rearrange its right-hand side as follows: $$\begin{aligned} P_\mathrm{loss} \le P_\mathrm{fus} + \frac{P_\mathrm{fus}}{Q} = P_\mathrm{fus} \Big( 1 + \frac{1}{Q} \Big) = P_\mathrm{fus} \Big( \frac{Q + 1}{Q} \Big) \end{aligned}$$ We assume that the plasma has equal species densities $$n_i = n_e$$, so its total density $$n = 2 n_i$$. Then $$P_\mathrm{fus}$$ is as follows, where $$f_{ii}$$ is the frequency with which a given ion collides with other ions, and $$E_\mathrm{fus}$$ is the energy released by a single fusion reaction: $$\begin{aligned} P_\mathrm{fus} = f_{ii} n_i E_\mathrm{fus} = \big( n_i \Expval{\sigma v} \big) n_i E_\mathrm{fus} = \frac{n^2}{4} \Expval{\sigma v} E_\mathrm{fus} \end{aligned}$$ Where $$\Expval{\sigma v}$$ is the mean product of the velocity $$v$$ and the collision cross-section $$\sigma$$. Furthermore, assuming that both species have the same temperature $$T_i = T_e = T$$, the total energy density $$W$$ of the plasma is given by: $$\begin{aligned} W = \frac{3}{2} k_B T_i n_i + \frac{3}{2} k_B T_e n_e = 3 k_B T n \end{aligned}$$ Where $$k_B$$ is Boltzmann's constant. From this, we can define the **confinement time** $$\tau_E$$ as the characteristic lifetime of energy in the reactor, before leakage. Therefore: $$\begin{aligned} \tau_E \equiv \frac{W}{P_\mathrm{loss}} \quad \implies \quad P_\mathrm{loss} = \frac{3 n k_B T}{\tau_E} \end{aligned}$$ Inserting these new expressions for $$P_\mathrm{fus}$$ and $$P_\mathrm{loss}$$ into the inequality, we arrive at: $$\begin{aligned} \frac{3 n k_B T}{\tau_E} \le \frac{n^2}{4} \Expval{\sigma v} E_\mathrm{fus} \Big( \frac{Q + 1}{Q} \Big) \end{aligned}$$ This can be rearranged to the form below, which is the original Lawson criterion: $$\begin{aligned} n \tau_E \ge \frac{Q}{Q + 1} \frac{12 k_B T}{\Expval{\sigma v} E_\mathrm{fus}} \end{aligned}$$ However, it turns out that the highest fusion power density is reached when $$T$$ is at the minimum of $$T^2 / \Expval{\sigma v}$$. Therefore, we multiply by $$T$$ to get the Lawson triple product: $$\begin{aligned} \boxed{ n T \tau_E \ge \frac{Q}{Q + 1} \frac{12 k_B T^2}{\Expval{\sigma v} E_\mathrm{fus}} } \end{aligned}$$ For some reason, it is often assumed that the fusion is infinitely profitable $$Q \to \infty$$, in which case the criterion reduces to: $$\begin{aligned} n T \tau_E \ge \frac{12 k_B T^2}{\Expval{\sigma v} E_\mathrm{fus}} \end{aligned}$$ ## References 1. M. Salewski, A.H. Nielsen, *Plasma physics: lecture notes*, 2021, unpublished.