Recreating the California New Year's flood event of 1997 in a regionally
refined Earth system model
The 1997 New Year’s flood event was the most costly in California’s
This compound extreme event was driven by a category 5 atmospheric river
that led to widespread snowmelt.
Extreme precipitation, snowmelt, and saturated soils produced heavy
runoff causing widespread inundation in the Sacramento Valley.
This study recreates the 1997 flood using the Regionally Refined Mesh
capabilities of the Energy Exascale Earth System Model (RRM-E3SM) under
prescribed ocean conditions.
Understanding the processes causing extreme events inform practical
efforts to anticipate and prepare for such events in the future, and
also provides a rich context to evaluate model skill in representing
Three California-focused RRM grids, with horizontal resolution
refinement of 14km down to 3.5km, and six forecast lead times, 28
December 1996 at 00Z through 30 December 1996 at 12Z, are assessed for
their ability to recreate the 1997 flood.
Planetary to synoptic scale atmospheric circulations and integrated
vapor transport are weakly influenced by horizontal resolution
refinement over California.
Topography and mesoscale circulations, such as the Sierra barrier jet,
are prominently influenced by horizontal resolution.
The finest resolution RRM-E3SM simulation best represents storm total
precipitation and storm duration snowpack changes.
Traditional time-series and causal analysis frameworks are used to
examine runoff sensitivities state-wide and above major reservoirs.
These frameworks show that horizontal resolution plays a more prominent
role in shaping reservoir inflows, namely the magnitude and time-series
shape, than forecast lead time, 2-to-4 days prior to the 1997 flood