This
product is one of a set of mapped model simulation results generated for a
project called “Global Climate Change and California: Potential
Implications for
Ecosystems, Health, and the Economy”. The project was conducted by the
Electrical Power Research Institute (EPRI) and funded by the California Energy
Commission’s Public Interest Energy Research (PIER) Program. The project was the most detailed
study ever undertaken on the potential effect of climate change on California.
The work examined a broad array of potentially affected sectors as well as the
interactions between climate change and increased population, economic growth,
and technological change. It considered a wide range of climate change
scenarios, ranging from warmer and much wetter to warmer and much drier (http://www.energy.ca.gov/pier/project_reports/500-03-058cf.html).
Lenihan et al. used a dynamic general vegetation
model (MC1), which estimated both the distribution and the productivity of
terrestrial ecosystems such as forests, grasslands, and deserts at a scale of
100 km2 (39 square miles), the highest resolution at which a dynamic model had
been applied in California. They estimated that under all climate change
scenarios, forests and other types of vegetation will migrate to higher
elevations as warmer temperatures make those areas more suitable for survival.
For example, with higher temperatures, the area of alpine and subalpine forests
will be reduced as evergreen forests and shrublands migrate to higher
altitudes. They estimated that if it gets wetter, forests would expand in
northern California and grasslands would expand in southern California. If it
gets drier, areas of grasslands would increase across the state. Both wetter
and drier scenarios resulted in increases in carbon storage (biomass) in
California vegetation of between 3% and 6%. Wetter conditions generally allow
for more biomass. Under drier conditions, grasslands, which store a relatively
high amount of carbon below ground, expand. Lenihan et al. found that the
frequency and the size of fires would increase under most scenarios; however,
the change is not significant until the latter part of the century. The drier
scenarios result in more frequent fires and more area consumed by fires. The
wetter scenarios result in fires of greater intensity than those in the dry
scenarios because more fuel (vegetation) would grow when it is wet to be
consumed by fire during occasional dry periods.
This map shows the future distribution
of potential natural vegetation types in California simulated by the MC1 DGVM
as a function of climatic thresholds, tree and grass productivity, and fire
effects. The simulated vegetation type
with the highest annual frequency over the future (2070-2099) period is mapped
at each cell. The climate scenario was generated by the Hadley Climate Centre’s
HADCM2 General Circulation Model forced with the IS92a emission scenario (i.e.,
CO2 atmospheric concentration at 712 ppm by 2100).