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Winter (January – March) precipitation averaged over 2046-2065 from the general circulation model PCM1 (Washington et al. 2000; Meehl et al. 2003) under the A2 emission scenario with a grid cell size of 10 km x 10km. References: Meehl, G.A., W.M. Washington, T.M.L. Wigley, J.M. Arblaster, and A. Dai. 2003. Solar and greenhouse gas forcing and climate response in the twentieth century. J Climate 16:426–444. Washington, W.M., J.W. Weatherly, G.A. Meehl, A.J. Semtner, T.W. Bettge, A.P. Craig, W.G. Stran, J. Arblaster, V.B. Wayland, R. James , and Y. Zhang. 2000. Parallel climate model (PCM) control and transient simulations. Clim Dyn 16: 755–774.
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Simulated understory index (fraction of grass vegetation carbon in forest, ((aglivcx + bglivcx) / frstc)) averaged over 2046-2065 simulated by MC1 (Lenihan et al. 2008) at a 10 km x 10 km grid cell size under general circulation model PCM1 (Washington et al. 2000; Meehl et al. 2003) under the A2 emission scenario. References: Meehl, G.A., W.M. Washington, T.M.L. Wigley, J.M. Arblaster, and A. Dai. 2003. Solar and greenhouse gas forcing and climate response in the twentieth century. J Climate 16:426–444. Washington, W.M., J.W. Weatherly, G.A. Meehl, A.J. Semtner, T.W. Bettge, A.P. Craig, W.G. Stran, J. Arblaster, V.B. Wayland, R. James , and Y. Zhang. 2000. Parallel climate model (PCM) control and transient simulations....
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Mean minimum temperature (°C) averaged over 2076-2095 from the general circulation model PCM1 (Washington et al. 2000; Meehl et al. 2003) under the A2 emission scenario with a grid cell size of 10 km x 10km. References: Meehl, G.A., W.M. Washington, T.M.L. Wigley, J.M. Arblaster, and A. Dai. 2003. Solar and greenhouse gas forcing and climate response in the twentieth century. J Climate 16:426–444. Washington, W.M., J.W. Weatherly, G.A. Meehl, A.J. Semtner, T.W. Bettge, A.P. Craig, W.G. Stran, J. Arblaster, V.B. Wayland, R. James , and Y. Zhang. 2000. Parallel climate model (PCM) control and transient simulations. Clim Dyn 16: 755–774.
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Mean minimum temperature (°C) averaged over 2046-2065 from the general circulation model PCM1 (Washington et al. 2000; Meehl et al. 2003) under the A2 emission scenario with a grid cell size of 10 km x 10km. References: Meehl, G.A., W.M. Washington, T.M.L. Wigley, J.M. Arblaster, and A. Dai. 2003. Solar and greenhouse gas forcing and climate response in the twentieth century. J Climate 16:426–444. Washington, W.M., J.W. Weatherly, G.A. Meehl, A.J. Semtner, T.W. Bettge, A.P. Craig, W.G. Stran, J. Arblaster, V.B. Wayland, R. James , and Y. Zhang. 2000. Parallel climate model (PCM) control and transient simulations. Clim Dyn 16: 755–774.
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Mean maximum temperature (°C) averaged over 2046-2065 from the general circulation model PCM1 (Washington et al. 2000; Meehl et al. 2003) under the A2 emission scenario with a grid cell size of 10 km x 10km. References: Meehl, G.A., W.M. Washington, T.M.L. Wigley, J.M. Arblaster, and A. Dai. 2003. Solar and greenhouse gas forcing and climate response in the twentieth century. J Climate 16:426–444. Washington, W.M., J.W. Weatherly, G.A. Meehl, A.J. Semtner, T.W. Bettge, A.P. Craig, W.G. Stran, J. Arblaster, V.B. Wayland, R. James , and Y. Zhang. 2000. Parallel climate model (PCM) control and transient simulations. Clim Dyn 16: 755–774.
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Mean annual precipitation (mm) averaged over 2046-2065 from the general circulation model PCM1 (Washington et al. 2000; Meehl et al. 2003) under the A2 emission scenario with a grid cell size of 10 km x 10km. References: Meehl, G.A., W.M. Washington, T.M.L. Wigley, J.M. Arblaster, and A. Dai. 2003. Solar and greenhouse gas forcing and climate response in the twentieth century. J Climate 16:426–444. Washington, W.M., J.W. Weatherly, G.A. Meehl, A.J. Semtner, T.W. Bettge, A.P. Craig, W.G. Stran, J. Arblaster, V.B. Wayland, R. James , and Y. Zhang. 2000. Parallel climate model (PCM) control and transient simulations. Clim Dyn 16: 755–774.
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Modal vegetation class over 1986 – 2005, simulated with MC1 (Lenihan et al. 2008) and a 10 km x 10 km grid cell size. Grid Value: Vegetation Type 1: ALPINE 2: SUBALPINE FOREST 3: COAST EVERGREEN FOREST 11: PINYON-JUNIPER 4: SIERRAN EVERGREEN FOREST 6: MIXED EVERGREEN FOREST 15: GREAT BASIN EVERGREEN WOODLAND 10: MIXED EVERGREEN WOODLAND 20: SAGEBRUSH STEPPE 17: C3 GRASSLAND 18: C4 GRASSLAND 19: CHAPARRAL 17: C3 GRASSLAND 18: C4 GRASSLAND 21: DESERT
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Future modal vegetation class over 2046-2065, simulated with MC1 (Lenihan et al. 2008) and a 10 km x 10 km grid cell size under the A2 emissions scenario with the PCM1 GCM (Washington et al. 2000; Meehl et al. 2003). Grid Value: Vegetation Type 1: ALPINE 2: SUBALPINE FOREST 3: COAST EVERGREEN FOREST 11: PINYON-JUNIPER 4: SIERRAN EVERGREEN FOREST 6: MIXED EVERGREEN FOREST 15: GREAT BASIN EVERGREEN WOODLAND 10: MIXED EVERGREEN WOODLAND 20: SAGEBRUSH STEPPE 17: C3 GRASSLAND 18: C4 GRASSLAND 19: CHAPARRAL 17: C3 GRASSLAND 18: C4 GRASSLAND 21: DESERT References: Meehl, G.A., W.M. Washington, T.M.L. Wigley, J.M. Arblaster, and A. Dai. 2003. Solar and greenhouse gas forcing and climate response in...
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Simulated fraction of vegetation carbon in forest averaged over 2046-2065 simulated by MC1 (Lenihan et al. 2008) at a 10 km x 10 km grid cell size under general circulation model PCM1 (Washington et al. 2000; Meehl et al. 2003) under the A2 emission scenario. References: Meehl, G.A., W.M. Washington, T.M.L. Wigley, J.M. Arblaster, and A. Dai. 2003. Solar and greenhouse gas forcing and climate response in the twentieth century. J Climate 16:426–444. Washington, W.M., J.W. Weatherly, G.A. Meehl, A.J. Semtner, T.W. Bettge, A.P. Craig, W.G. Stran, J. Arblaster, V.B. Wayland, R. James , and Y. Zhang. 2000. Parallel climate model (PCM) control and transient simulations. Clim Dyn 16: 755–774.
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Winter (January – March) minimum temperature (°C) averaged over 2076-2095 from the general circulation model PCM1 (Washington et al. 2000; Meehl et al. 2003) under the A2 emission scenario with a grid cell size of 10 km x 10km. References: Meehl, G.A., W.M. Washington, T.M.L. Wigley, J.M. Arblaster, and A. Dai. 2003. Solar and greenhouse gas forcing and climate response in the twentieth century. J Climate 16:426–444. Washington, W.M., J.W. Weatherly, G.A. Meehl, A.J. Semtner, T.W. Bettge, A.P. Craig, W.G. Stran, J. Arblaster, V.B. Wayland, R. James , and Y. Zhang. 2000. Parallel climate model (PCM) control and transient simulations. Clim Dyn 16: 755–774.
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Winter (January – March) minimum temperature (°C) averaged over 2046-2065 from the general circulation model PCM1 (Washington et al. 2000; Meehl et al. 2003) under the A2 emission scenario with a grid cell size of 10 km x 10km. References: Meehl, G.A., W.M. Washington, T.M.L. Wigley, J.M. Arblaster, and A. Dai. 2003. Solar and greenhouse gas forcing and climate response in the twentieth century. J Climate 16:426–444. Washington, W.M., J.W. Weatherly, G.A. Meehl, A.J. Semtner, T.W. Bettge, A.P. Craig, W.G. Stran, J. Arblaster, V.B. Wayland, R. James , and Y. Zhang. 2000. Parallel climate model (PCM) control and transient simulations. Clim Dyn 16: 755–774.
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Future (2046-2065) predicted probability of marten year-round occurrence projected under the A2 emissions scenario with the PCM1 GCM (Washington et al. 2000; Meehl et al. 2003). The projected marten distribution was created with Maxent (Phillips et al. 2006) using marten detections (N = 302, spanning 1990 – 2011) and nine predictor variables: mean annual precipitation, mean summer (July – September) precipitation, mean summer temperature amplitude, mean annual temperature maximum, mean fraction of vegetation carbon burned, mean understory index, mean vegetation carbon (g C m2), modal vegetation class, and average maximum tree LAI. Predictor variables had a grid cell size of 10 km, vegetation variables were simulated...
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Winter (January – March) precipitation averaged over 2076-2095 from the general circulation model PCM1 (Washington et al. 2000; Meehl et al. 2003) under the A2 emission scenario with a grid cell size of 10 km x 10km. References: Meehl, G.A., W.M. Washington, T.M.L. Wigley, J.M. Arblaster, and A. Dai. 2003. Solar and greenhouse gas forcing and climate response in the twentieth century. J Climate 16:426–444. Washington, W.M., J.W. Weatherly, G.A. Meehl, A.J. Semtner, T.W. Bettge, A.P. Craig, W.G. Stran, J. Arblaster, V.B. Wayland, R. James , and Y. Zhang. 2000. Parallel climate model (PCM) control and transient simulations. Clim Dyn 16: 755–774.
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Simulated fraction of vegetation carbon burned averaged over 2046-2065 simulated by MC1 (Lenihan et al. 2008) at a 10 km x 10 km grid cell size under general circulation model PCM1 (Washington et al. 2000; Meehl et al. 2003) under the A2 emission scenario. References: Meehl, G.A., W.M. Washington, T.M.L. Wigley, J.M. Arblaster, and A. Dai. 2003. Solar and greenhouse gas forcing and climate response in the twentieth century. J Climate 16:426–444. Washington, W.M., J.W. Weatherly, G.A. Meehl, A.J. Semtner, T.W. Bettge, A.P. Craig, W.G. Stran, J. Arblaster, V.B. Wayland, R. James , and Y. Zhang. 2000. Parallel climate model (PCM) control and transient simulations. Clim Dyn 16: 755–774.
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Simulated understory index (fraction of grass vegetation carbon in forest, ((aglivcx + bglivcx) / frstc)) averaged over 2076-2095 simulated by MC1 (Lenihan et al. 2008) at a 10 km x 10 km grid cell size under general circulation model PCM1 (Washington et al. 2000; Meehl et al. 2003) under the A2 emission scenario. References: Meehl, G.A., W.M. Washington, T.M.L. Wigley, J.M. Arblaster, and A. Dai. 2003. Solar and greenhouse gas forcing and climate response in the twentieth century. J Climate 16:426–444. Washington, W.M., J.W. Weatherly, G.A. Meehl, A.J. Semtner, T.W. Bettge, A.P. Craig, W.G. Stran, J. Arblaster, V.B. Wayland, R. James , and Y. Zhang. 2000. Parallel climate model (PCM) control and transient simulations....
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Simulated vegetation carbon (g C m2) averaged over 2076-2095 simulated by MC1 (Lenihan et al. 2008) at a 10 km x 10 km grid cell size under general circulation model PCM1 (Washington et al. 2000; Meehl et al. 2003) under the A2 emission scenario. References: Meehl, G.A., W.M. Washington, T.M.L. Wigley, J.M. Arblaster, and A. Dai. 2003. Solar and greenhouse gas forcing and climate response in the twentieth century. J Climate 16:426–444. Washington, W.M., J.W. Weatherly, G.A. Meehl, A.J. Semtner, T.W. Bettge, A.P. Craig, W.G. Stran, J. Arblaster, V.B. Wayland, R. James , and Y. Zhang. 2000. Parallel climate model (PCM) control and transient simulations. Clim Dyn 16: 755–774.
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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,...
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Simulated fraction of vegetation carbon in forest averaged over 2076-2095 simulated by MC1 (Lenihan et al. 2008) at a 10 km x 10 km grid cell size under general circulation model PCM1 (Washington et al. 2000; Meehl et al. 2003) under the A2 emission scenario. References: Meehl, G.A., W.M. Washington, T.M.L. Wigley, J.M. Arblaster, and A. Dai. 2003. Solar and greenhouse gas forcing and climate response in the twentieth century. J Climate 16:426–444. Washington, W.M., J.W. Weatherly, G.A. Meehl, A.J. Semtner, T.W. Bettge, A.P. Craig, W.G. Stran, J. Arblaster, V.B. Wayland, R. James , and Y. Zhang. 2000. Parallel climate model (PCM) control and transient simulations. Clim Dyn 16: 755–774.
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Mean summer (July – September) precipitation averaged over 2046-2065 from the general circulation model PCM1 (Washington et al. 2000; Meehl et al. 2003) under the A2 emission scenario with a grid cell size of 10 km x 10km. References: Meehl, G.A., W.M. Washington, T.M.L. Wigley, J.M. Arblaster, and A. Dai. 2003. Solar and greenhouse gas forcing and climate response in the twentieth century. J Climate 16:426–444. Washington, W.M., J.W. Weatherly, G.A. Meehl, A.J. Semtner, T.W. Bettge, A.P. Craig, W.G. Stran, J. Arblaster, V.B. Wayland, R. James , and Y. Zhang. 2000. Parallel climate model (PCM) control and transient simulations. Clim Dyn 16: 755–774.
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Mean annual precipitation averaged over 2076-2095 from the general circulation model PCM1 (Washington et al. 2000; Meehl et al. 2003) under the A2 emission scenario with a grid cell size of 10 km x 10km. References: Meehl, G.A., W.M. Washington, T.M.L. Wigley, J.M. Arblaster, and A. Dai. 2003. Solar and greenhouse gas forcing and climate response in the twentieth century. J Climate 16:426–444. Washington, W.M., J.W. Weatherly, G.A. Meehl, A.J. Semtner, T.W. Bettge, A.P. Craig, W.G. Stran, J. Arblaster, V.B. Wayland, R. James , and Y. Zhang. 2000. Parallel climate model (PCM) control and transient simulations. Clim Dyn 16: 755–774.


map background search result map search result map Mean winter (January – March) minimum temperature, 2076-2095, PCM1 A2, 10 km resolution Mean winter (January – March) minimum temperature, 2046-2065, PCM1 A2, 10 km resolution Mean winter (January – March) precipitation, 2076-2095, PCM1 A2, 10 km resolution Mean winter (January – March) precipitation, 2046-2065, PCM1 A2, 10 km resolution Mean minimum temperature, 2076-2095, PCM1 A2, 10 km resolution Mean minimum temperature, 2046-2065, PCM1 A2, 10 km resolution Mean maximum temperature, 2046-2065, PCM1 A2, 10 km resolution Mean summer (July – September) precipitation, 2046-2065, PCM1 A2, 10 km resolution Mean annual precipitation, 2076 – 2095, PCM1 A2, 10 km resolution Mean annual precipitation, 2046-2065, PCM1 A2, 10 km resolution Simulated vegetation carbon (g C m2), 2076-2095, PCM1 A2, 10 km resolution Simulated vegetation class (mode), 2046-2065, PCM1 A2, 10 km resolution Simulated vegetation class (mode), 1986-2005, PCM1 A2, 10 km resolution Simulated understory index (fraction of grass vegetation carbon in forest, ((aglivcx + bglivcx) / frstc)), 2076-2095, PCM1 A2, 10 km resolution Simulated understory index (fraction of grass vegetation carbon in forest, ((aglivcx + bglivcx) / frstc)), 2046-2065, PCM1 A2, 10 km Simulated fraction of vegetation carbon in forest, 2076-2095, PCM1 A2, 10 km resolution Simulated fraction of vegetation carbon in forest, 2046-2065, PCM1 A2, 10 km resolution Simulated fraction of vegetation carbon burned, 2046-2065, PCM1 A2, 10 km resolution Predicted probability of marten year-round occurrence, 2046-2065, PCM1 A2, 10 km resolution PCM1 A2 future climate scenario: annual output of potential natural vegetation for California Mean winter (January – March) minimum temperature, 2076-2095, PCM1 A2, 10 km resolution Mean winter (January – March) minimum temperature, 2046-2065, PCM1 A2, 10 km resolution Mean winter (January – March) precipitation, 2076-2095, PCM1 A2, 10 km resolution Mean winter (January – March) precipitation, 2046-2065, PCM1 A2, 10 km resolution Mean minimum temperature, 2076-2095, PCM1 A2, 10 km resolution Mean minimum temperature, 2046-2065, PCM1 A2, 10 km resolution Mean maximum temperature, 2046-2065, PCM1 A2, 10 km resolution Mean summer (July – September) precipitation, 2046-2065, PCM1 A2, 10 km resolution Mean annual precipitation, 2076 – 2095, PCM1 A2, 10 km resolution Mean annual precipitation, 2046-2065, PCM1 A2, 10 km resolution Simulated vegetation carbon (g C m2), 2076-2095, PCM1 A2, 10 km resolution Simulated vegetation class (mode), 2046-2065, PCM1 A2, 10 km resolution Simulated vegetation class (mode), 1986-2005, PCM1 A2, 10 km resolution Simulated understory index (fraction of grass vegetation carbon in forest, ((aglivcx + bglivcx) / frstc)), 2076-2095, PCM1 A2, 10 km resolution Simulated understory index (fraction of grass vegetation carbon in forest, ((aglivcx + bglivcx) / frstc)), 2046-2065, PCM1 A2, 10 km Simulated fraction of vegetation carbon in forest, 2076-2095, PCM1 A2, 10 km resolution Simulated fraction of vegetation carbon in forest, 2046-2065, PCM1 A2, 10 km resolution Simulated fraction of vegetation carbon burned, 2046-2065, PCM1 A2, 10 km resolution Predicted probability of marten year-round occurrence, 2046-2065, PCM1 A2, 10 km resolution PCM1 A2 future climate scenario: annual output of potential natural vegetation for California