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<strong class="journal-contentHeaderColor">Abstract.</strong> Targeted contrail avoidance consists of rerouting aircraft to minimise the formation of contrails whose warming of the climate system can be much larger than that due to the CO<sub>2</sub> emitted for some of the flights. A commonly proposed strategy is to reroute all flights for which the trade-off between additional CO<sub>2</sub> emissions and reduction in contrail warming leads to a climate benefit. However, current predictions of contrail climate impact are highly uncertain. In this study, we describe a framework to integrate the risk of unintentionally damaging the climate in the contrail avoidance decision-making process, using the Contrail Cirrus Prediction model (CoCiP) and operational ensemble weather forecasts. Optimising trajectories around a best estimate of contrail radiative forcing then including weather and parametric uncertainties in that predicted forcing in a second step reveals that 55 % of the reroutings have a higher-than-5 % risk of unintentionally damaging the climate compared to a standard risk-unaware avoidance strategy. This fraction increases to 76 % when choosing to reject any risk. However, the reroutings that are the least risky to operate are also those with the highest potential climate benefit, often referred to as ‘big hits’. Alternatively, accounting for uncertainties from the start of trajectory optimisation allows to mitigate the risk directly when planning the flight. This strategy would even result in a 52 % higher potential climate benefit compared to the risk-unaware avoidance strategy, when choosing to reject any risk. Our results thus demonstrate that the risk of unintentionally damaging the climate can and should be included in the decision-making of contrail avoidance, in particular in the context of early adoption policies.