An "observational large ensemble" to compare observed and modeled temperature trend uncertainty due to internal variability

Estimates of the climate response to anthropogenic forcing contain irreducible uncertainty due to the presence of internal variability. Accurate quantification of this uncertainty is critical for both contextualizing historical trends and determining the spread of climate projections. The contribution of internal variability to uncertainty in trends can be estimated in models as the spread across an initial condition ensemble. However, internal variability simulated by a modelmay be inconsistent with observations due tomodel biases. Here, statistical resamplingmethods are applied to observations in order to quantify uncertainty in historical 50-yr (1966-2015) winter near-surface air temperature trends over NorthAmerica related to incomplete sampling of internal variability. This estimate is compared with the simulated trend uncertainty in the NCAR CESM1 Large Ensemble (LENS). The comparison suggests that uncertainty in trends due to internal variability is largely overestimated in LENS, which has an average amplification of variability of 32% across NorthAmerica. The amplification of variability is greatest in the westernUnited States and Alaska. The observationally derived estimate of trend uncertainty is combined with the forced signal from LENS to produce an "Observational Large Ensemble" (OLENS). The members of OLENS indicate the range of observationally constrained, spatially consistent temperature trends that could have been observed over the past 50 years if a different sequence of internal variability had unfolded. The smaller trend uncertainty in OLENS suggests that is easier to detect the historical climate change signal in observations than in any given member of LENS.