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1. Evaluating the Drought Code for lowland taiga of Interior Alaska using eddy covariance measurements

   https://doi.org/10.1071/WF22165  

   Miller, Eric A; Iwata, Hiroki; Ueyama, Masahito; Harazono, Yoshinobu; Kobayashi, Hideki; Ikawa, Hiroki; Busey, Robert; Iwahana, Go; Euskirchen, Eugénie S (January 2023, International Journal of Wildland Fire)

   Background The Drought Code (DC) of the Canadian Fire Weather Index System (CFWIS) has been intuitively regarded by fire managers in Alaska, USA, as poorly representing the moisture content in the forest floor in lowland taiga forests on permafrost soils. Aims The aim of this study was to evaluate the DC using its own framework of water balance as cumulative additions of daily precipitation and substractions of actual evaporation. Methods We used eddy covariance measurements (EC) from three flux towers in Interior Alaska as a benchmark of natural evaporation. Key results The DC water balance model overpredicted drought for all 14 site-years that we analysed. Errors in water balance cumulated to 109 mm by the end of the season, which was 54% of the soil water storage capacity of the DC model. Median daily water balance was 6.3 times lower than that measured by EC. Conclusions About half the error in the model was due to correction of precipitation for canopy effects. The other half was due to dependence of the actual evaporation rate on the proportional ‘fullness’ of soil water storage in the DC model. Implications Fire danger situational awareness is improved by ignoring the DC in the CFWIS for boreal forests occurring on permafrost. 

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2. The bedrock of forest drought

   https://doi.org/10.1038/s41561-022-01015-z  

   Tague, Christina (September 2022, Nature Geoscience)
3. Is a drought a drought in grasslands? Productivity responses to different types of drought

   https://doi.org/10.1007/s00442-020-04793-8  

   Carroll, Charles J.; Slette, Ingrid J.; Griffin-Nolan, Robert J.; Baur, Lauren E.; Hoffman, Ava M.; Denton, Elsie M.; Gray, Jesse E.; Post, Alison K.; Johnston, Melissa K.; Yu, Qiang; et al (January 2021, Oecologia)

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4. Automated Analysis of the US Drought Monitor Maps With Machine Learning and Multiple Drought Indicators

   https://doi.org/10.3389/fdata.2021.750536  

   Hatami Bahman Beiglou, Pouyan; Luo, Lifeng; Tan, Pang-Ning; Pei, Lisi (October 2021, Frontiers in Big Data)

   The US Drought Monitor (USDM) is a hallmark in real time drought monitoring and assessment as it was developed by multiple agencies to provide an accurate and timely assessment of drought conditions in the US on a weekly basis. The map is built based on multiple physical indicators as well as reported observations from local contributors before human analysts combine the information and produce the drought map using their best judgement. Since human subjectivity is included in the production of the USDM maps, it is not an entirely clear quantitative procedure for other entities to reproduce the maps. In this study, we developed a framework to automatically generate the maps through a machine learning approach by predicting the drought categories across the domain of study. A persistence model served as the baseline model for comparison in the framework. Three machine learning algorithms, logistic regression, random forests, and support vector machines, with four different groups of input data, which formed an overall of 12 different configurations, were used for the prediction of drought categories. Finally, all the configurations were evaluated against the baseline model to select the best performing option. The results showed that our proposed framework could reproduce the drought maps to a near-perfect level with the support vector machines algorithm and the group 4 data. The rest of the findings of this study can be highlighted as: 1) employing the past week drought data as a predictor in the models played an important role in achieving high prediction scores, 2) the nonlinear models, random forest, and support vector machines had a better overall performance compared to the logistic regression models, and 3) with borrowing the neighboring grid cells information, we could compensate the lack of training data in the grid cells with insufficient historical USDM data particularly for extreme and exceptional drought conditions. 

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5. The Unstable Relationship Between Drought Status and Leaf Water Content Complicates the Remote Sensing of Tree Drought Stress

   https://doi.org/10.1111/gcb.70188  

   Boving, Indra; Allen, Jean; Brodrick, Philip_G; Chadwick, K_Dana; Trugman, Anna; Anderegg, Leander_DL (April 2025, Global Change Biology)

   ABSTRACT Remote sensing holds promise for ecosystem‐level monitoring of plant drought stress but is limited by uncertain linkages between physiological stress and remotely sensed metrics of water content. Here, we investigate the stability of relationships between water potential (Ψ) and water content (measured in situ and via repeat airborne VSWIR imaging) over diel, seasonal, and spatial variation in two xeric oak tree species. We also compare these field‐based relationships with ones established in laboratory settings that might be used as calibration. Due to confounding physiological processes related to growth, both in situ and remotely sensed metrics lacked consistent relationships with stress when measured across space or through time. Relationships between water content and physiological drought stress measured over the growing season were stronger and more closely related to established laboratory‐based drydown methods than those measured across space (i.e., between wet trees and dry trees). These results provide insight into the utility of “space for time” approaches in remote sensing and demonstrate both important limitations and the potential power of high temporal resolution remote sensing for detecting drought stress. 

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