Abstract
The Drought Code (DC) is a moisture code of the Canadian Forest Fire Weather Index System underlain by a hydrological water balance model in which drying occurs in a negative exponential pattern with a relatively long timelag. The model derives from measurements from an evaporimeter and no soil parameters are specified, leaving its physical nature uncertain. One way to approximate the attributes of a “DC equivalent soil” is to compare its drying timelag with measurements of known soils. In situ measurements of timelag were made over the course of a fire season in a black spruce-feathermoss forest floor underlain by permafrost in Interior Alaska, USA. On a seasonally averaged basis, timelag was 28 d. The corresponding timelag of the DC water balance model was 60 d. Water storage capacity in a whole duff column 200 mm deep was 31 mm. Using these figures and a relationship between timelag, water storage capacity, and the potential evaporation rate, a “DC equivalent soil” was determined to be capable of storing 66 mm of water. This amount of water would require a soil 366 mm deep, suggesting a revision of the way fire managers in Alaska regard the correspondence between soil and the moisture codes of the FWI. Nearly half of the soil depth would be mineral rather than organic. Much of the soil water necessary to maintain a 60 d timelag characteristic of a “DC equivalent soil” is frozen until after the solstice. Unavailability of frozen water, coupled with a June peak in the potential evaporation rate, appears to shorten in situ timelags early in the season.
Highlights
Wildland fuels dry in a negative exponential manner as internal bulk diffusion experiences increasing resistance with moisture loss [1]
Timelag in a negative exponential system can be expressed as the time it would take to empty the full capacity of stored water at the potential evaporation rate or the time to empty current water storage, S0, at the actual evaporation rate [5]: Fire 2020, 3, 25; doi:10.3390/fire3020025
Almost half the water storage capacity of the duff is held in the bottom 50 mm
Summary
Wildland fuels dry in a negative exponential manner as internal bulk diffusion experiences increasing resistance with moisture loss [1]. In fire danger rating moisture codes and indices, timelag is most often presented in terms of the logarithmic drying rate equation [3,4]. In this context, it is the time it takes for a fuel to lose 1 − 1e or ≈ 63% of its free moisture. Free moisture is the water content in a soil or fuel above equilibrium that is available for drying. Timelag in a negative exponential system can be expressed as the time it would take to empty the full capacity of stored water at the potential evaporation rate or the time to empty current water storage, S0 , at the actual evaporation rate [5]: Fire 2020, 3, 25; doi:10.3390/fire3020025 www.mdpi.com/journal/fire
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
