a. Heat wave and precipitation deficit flash droughts

b. Intensification rate–based flash droughts

Following the suggestion of Otkin et al. (2018), here we propose a quantitative method to identify flash droughts by focusing on the rate of intensification (RI). Unlike a more traditional, slowly evolving drought, flash drought is characterized by the rapid depletion of soil moisture resulting from a period of abnormally warm and dry weather conditions. In this sense, flash drought can be viewed as a subset of all droughts (e.g., meteorological, agricultural, and hydrological droughts), and which is most likely to occur in the onset-development phase of the drought event. As shown in Fig. 2a, suppose t₁ is the onset time that the soil layer is experiencing the “abnormally dry” conditions and has the potential to precede a drought, and the time node t₅ represents the stationary point that moisture deficits suffer abrupt changes from rapid decline to smooth fluctuations (e.g., t₆–t₁₅ in Fig. 2a) or even present an increased pattern (e.g., t₁₅–t₁₈ in Fig. 2a). In other words, the stationary point can be viewed as the termination of rapid soil moisture reduction, which may emerge at or before the peak of drought intensity. With this in mind, the identification of flash droughts is further generalized as two questions: how to extract the onset–development phase (i.e., the time period from t₁–t₅) of droughts, and how fast should the intensification be to be recognized a flash drought?

(a) Schematic overview of the evolution process of flash drought indicated by soil moisture percentile; t₁ represents the onset time; t₅ denotes the stationary point where rapid depletion of soil moisture ends; the period from t₆ to t₁₈ represents the recovery stage where soil moisture increases gradually then returns to the normal condition. (b) Generalized flowchart of identifying flash drought based on intensification rate. The left dashed rectangle shows how find the stationary point with the polynomial fitting method. The left rectangle gives the formulas for calculating the rate of intensification.

Citation: Journal of Hydrometeorology 21, 4; 10.1175/JHM-D-19-0088.1

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(a) Schematic overview of the evolution process of flash drought indicated by soil moisture percentile; t₁ represents the onset time; t₅ denotes the stationary point where rapid depletion of soil moisture ends; the period from t₆ to t₁₈ represents the recovery stage where soil moisture increases gradually then returns to the normal condition. (b) Generalized flowchart of identifying flash drought based on intensification rate. The left dashed rectangle shows how find the stationary point with the polynomial fitting method. The left rectangle gives the formulas for calculating the rate of intensification.

Citation: Journal of Hydrometeorology 21, 4; 10.1175/JHM-D-19-0088.1

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(a) Schematic overview of the evolution process of flash drought indicated by soil moisture percentile; t₁ represents the onset time; t₅ denotes the stationary point where rapid depletion of soil moisture ends; the period from t₆ to t₁₈ represents the recovery stage where soil moisture increases gradually then returns to the normal condition. (b) Generalized flowchart of identifying flash drought based on intensification rate. The left dashed rectangle shows how find the stationary point with the polynomial fitting method. The left rectangle gives the formulas for calculating the rate of intensification.

Citation: Journal of Hydrometeorology 21, 4; 10.1175/JHM-D-19-0088.1

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In this study, we use weekly soil moisture percentiles to depict the drought process (Fig. 2b). Specifically, drought events are extracted when the soil moisture falls below a predetermined value. Similar to previous studies, the threshold adopted here is twofold: 1) soil moisture is less than the 40th percentile, and 2) the peak drought intensity must fall below the 20th percentile (Ford and Labosier 2017; Otkin et al. 2018). The onset time (i.e., t₁ in Fig. 2a) of a flash drought event, therefore, is defined as the first week when the soil moisture falls below the 40% percentile. As for the stationary point (i.e., t₅ in Fig. 2a), a univariate polynomial function is employed to determine its location along the horizontal axis (viz., the date in Fig. 2a). Figure 3 presents four typical examples of the attenuation process of soil moisture percentiles under drought. All points between the onset time and peak of intensity are used when searching for the fitting equation. When a linear regression function is employed, the peak of drought intensity is chosen as the stationary point (Fig. 3a). With respect to the nonlinear case, we increase the order of the polynomial in sequence (e.g., linear polynomials, quadratic, cubic, ..., nth-order polynomial) until a minimum value of 0.95 for the deterministic coefficient R² of fitting polynomial is attained (Figs. 3b–d). In calculus, the stationary point (i.e., t₅ in Fig. 2a) can be located when the first derivative of the constructed polynomial equals zero (i.e., ∂Y/∂X = 0). In other words, the polynomial function is only used to judge when the flash drought event terminates but would not participate in estimating the magnitude of the flash drought intensification. With the extracted stationary point, the mean intensification rate (RI_mean) of a drought event during its onset–development phase can be calculated as

${\text{RI}}_{\text{mean}}={\displaystyle \frac{1}{n}}\hspace{0.17em}{\displaystyle \sum _{i=1}^n\left[{\displaystyle \frac{\text{SM}\left(t_{i+1}\right)-\text{SM}\left(t_i\right)}{t_{i+1}-t_i}}\right]},t_1\le t_i\le t_n,$(3)

where t₁ denotes the onset time, and t_n represents the stationary point. A similar concept of RI_mean is also employed in several previous studies. For instance, Ford and Labosier (2017) recommended that the soil moisture content dropping from the 40th percentile to below the 20th percentile in no less than 4 pentads (equivalent to a RI_mean value of 6.5 percentile per week) could be recognized as flash droughts. Given the similar climatic characteristics between the YRB and their research area (i.e., Oklahoma, United States), in this study we use the same metric to identify flash droughts, which puts more emphasis on the overall declining rate of soil moisture during the whole onset-development period. However, in reality, there may exist some exceptional cases that their RI_mean is lower than the predetermined value (i.e., 6.5 percentile per week) but have rather high instantaneous RI_i values at a certain moment. We determined that such cases should also be considered flash droughts. On these grounds, the instantaneous maximum intensification rate (RI_max) during the onset–development phase is introduced:

${\text{RI}}_{\max }=\max \left[{\displaystyle \frac{\text{SM}\left(t_{i+1}\right)-\text{SM}\left(t_i\right)}{t_{i+1}-t_i}}\right],t_1\le t_i\le t_{\mathit{n}}.$(4)

Four typical examples of the attenuation process of soil moisture percentile (from the onset time to the peak of drought intensity) under drought. Based on the trajectories of soil moisture percentile, we use different order polynomials to fit these samples, and the red circles can be derived as the stationary point (when the partial derivative of the fitted polynomial equation is 0) of the established polynomial. When a linear regression function is employed, the peak of drought intensity is the stationary point.

Citation: Journal of Hydrometeorology 21, 4; 10.1175/JHM-D-19-0088.1

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Four typical examples of the attenuation process of soil moisture percentile (from the onset time to the peak of drought intensity) under drought. Based on the trajectories of soil moisture percentile, we use different order polynomials to fit these samples, and the red circles can be derived as the stationary point (when the partial derivative of the fitted polynomial equation is 0) of the established polynomial. When a linear regression function is employed, the peak of drought intensity is the stationary point.

Citation: Journal of Hydrometeorology 21, 4; 10.1175/JHM-D-19-0088.1

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Four typical examples of the attenuation process of soil moisture percentile (from the onset time to the peak of drought intensity) under drought. Based on the trajectories of soil moisture percentile, we use different order polynomials to fit these samples, and the red circles can be derived as the stationary point (when the partial derivative of the fitted polynomial equation is 0) of the established polynomial. When a linear regression function is employed, the peak of drought intensity is the stationary point.

Citation: Journal of Hydrometeorology 21, 4; 10.1175/JHM-D-19-0088.1

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A flash drought is recognized when either the condition of RI_mean or RI_max is met over a sufficiently long enough period of time. For RI_max selection, we make a sensitivity test on the frequency of occurrence (FOC; the percent of weeks under flash drought) of flash droughts to varied RI_mean and RI_max. As shown in Fig. 4, smaller values of RI_mean and RI_max would correspond to higher FOC, and vice versa. When RI_mean is set to 6.5 percentile per week, the FOC of flash droughts mainly varies between 4% and 12% depending on different RI_max values. In this study, a value of 10 percentiles per week is selected for RI_max, with corresponding FOC approximate to 10%. This frequency is generally in accordance with Mo and Lettenmaier (2015, 2016), which ensures the significance of comparison between the two different methods. The flash drought based on the modified rate of intensification approach (i.e., RI_mean > 6.5 percentile per week or RI_max > 10 percentile per week) is denoted as RIFD.

Sensitivity analysis on the frequency of occurrence (FOC) of flash droughts to varied RI_mean and RI_max. The gray solid lines show the relationship between RI_max and FOC under different values of RI_mean (increasing gradually from 0.5 to 40 percentile per week). Likewise, the red solid line gives the case when RI_mean = 6.5 percentile per week.

Citation: Journal of Hydrometeorology 21, 4; 10.1175/JHM-D-19-0088.1

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Sensitivity analysis on the frequency of occurrence (FOC) of flash droughts to varied RI_mean and RI_max. The gray solid lines show the relationship between RI_max and FOC under different values of RI_mean (increasing gradually from 0.5 to 40 percentile per week). Likewise, the red solid line gives the case when RI_mean = 6.5 percentile per week.

Citation: Journal of Hydrometeorology 21, 4; 10.1175/JHM-D-19-0088.1

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Sensitivity analysis on the frequency of occurrence (FOC) of flash droughts to varied RI_mean and RI_max. The gray solid lines show the relationship between RI_max and FOC under different values of RI_mean (increasing gradually from 0.5 to 40 percentile per week). Likewise, the red solid line gives the case when RI_mean = 6.5 percentile per week.

Citation: Journal of Hydrometeorology 21, 4; 10.1175/JHM-D-19-0088.1

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In the following section, we will compare RIFD against HWFD and PDFD, and explore the underlying reasons for their differences.

a. Comparison of identified flash drought events

Based on the approaches described above, a cross comparison of flash droughts identified from two different methods is conducted. As a subset of drought, one basic feature of flash droughts is that the event should fall into drought during the evolution process. Although both methods employed the 40th percentile of soil moisture to identify the onset of flash drought, it actually only represents a drier condition than normal but not drought. For soil moisture drought, conditions less than the 30th percentile are commonly recognized as mildly dry, and less than the 20th percentile for moderate drought (Ford et al. 2015). In this sense, the RIFD method meets the condition of moisture limitation due to its secondary threshold, namely the soil moisture should be lower than the 20th percentile for at least one week. In contrast, the HWFD and PDFD make no such restrictions on soil moisture, which may lead to misjudgment of the results. Given this, we further extracted the nondrought events (i.e., for an event, the soil moisture is higher than the 30th percentile during each week) and nonmoderate drought events (higher than the 20th percentile) from HWFD and PDFD. As shown in Fig. 5, approximately 7%–40% of the identified flash drought events by HWFD and PDFD were nondrought (i.e., soil moisture of such events are above the 30th percentile), and 20%–69% were nonmoderate drought (i.e., soil moisture of such events are above the 20th percentile). This suggests that the HWFD and PDFD method could not guarantee that all of the identified events fall into drought. From the perspective of drought characteristic, these improperly recognized flash droughts were mostly minor events with their duration no more than 4 weeks. In the following section, we will remove these minor events from further analysis.

(a) The ratio of nondrought events (viz., for an identified flash drought event, the soil moisture values at each week are all higher than the 30th percentile) to all events identified by HWFD and PDFD. (b) As in (a), but for the ratio of nonmoderate drought events (higher than the 20th percentile) to all events.

Citation: Journal of Hydrometeorology 21, 4; 10.1175/JHM-D-19-0088.1

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(a) The ratio of nondrought events (viz., for an identified flash drought event, the soil moisture values at each week are all higher than the 30th percentile) to all events identified by HWFD and PDFD. (b) As in (a), but for the ratio of nonmoderate drought events (higher than the 20th percentile) to all events.

Citation: Journal of Hydrometeorology 21, 4; 10.1175/JHM-D-19-0088.1

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(a) The ratio of nondrought events (viz., for an identified flash drought event, the soil moisture values at each week are all higher than the 30th percentile) to all events identified by HWFD and PDFD. (b) As in (a), but for the ratio of nonmoderate drought events (higher than the 20th percentile) to all events.

Citation: Journal of Hydrometeorology 21, 4; 10.1175/JHM-D-19-0088.1

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Another important feature of flash drought lies in the unusually rapid intensification rate of soil moisture deficit (i.e., the “flash” characteristic). Figure 6 presents the variation of soil moisture percentile for major flash drought events (events with duration less than 4 weeks were excluded) of all grids in the study region. For RIFD, most of the events present sharp declines in soil moisture with the moisture condition changing from normal status (above the 40th percentile) to moderate drought (below the 20th percentile) within two weeks (Fig. 6a). As for HWFD and PDFD, it on average takes five weeks (from T_t−1 to T_t+4) for soil moisture to decrease from the 18th to 10th percentile (the dark solid line in Fig. 6b). According to Eqs. (3) and (4), this depletion rate of soil moisture is equivalent to −1.6 percentile per week, which is far slower than the intensification rate of RIFD (i.e., −6.5 percentile per week). Figure 7 further shows the frequency distributions of the mean and maximum rate of intensification for HWFD and PDFD events. Generally, the HWFD statistics presented a quasi-normal distribution where approximately 80% of the events had a negative value of RI_mean (i.e., RI_mean < 0), but only 24% of the events identified fell below the threshold of RIFD (i.e., RI_mean < −6.5). In addition, a small percentage amount (approximately 20%) of RI_mean still presented positive values (i.e., RI_mean > 0), implying that the HWFD events defined by Mo and Lettenmaier (2015) may have occurred in the recovery phase where an incremental increase in soil moisture emerges. Similar patterns were also observed in RI_max of HWFD, and RI_mean and RI_max of PDFD (Fig. 7b). These phenomena are not limited to our study domain (YRB). Wang and Yuan (2018) found that 10%–18% of HWFD and PDFD happened in the recovery phase of seasonal droughts over China.

Variation of soil moisture percentile for major flash drought events (light colored lines; excludes drought duration less than 4 weeks) of all grids in the study region identified by (a) RIFD and (b) HWFD and PDFD. The dark color line represents the ensemble-mean of all flash drought events. The t represents the time when the flash droughts occur. The t − 2 and t − 1 denote the 1 week and 2 weeks prior to t, while t + 1–t + 4 represent the lagged 1–4 weeks of t, respectively.

Citation: Journal of Hydrometeorology 21, 4; 10.1175/JHM-D-19-0088.1

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Variation of soil moisture percentile for major flash drought events (light colored lines; excludes drought duration less than 4 weeks) of all grids in the study region identified by (a) RIFD and (b) HWFD and PDFD. The dark color line represents the ensemble-mean of all flash drought events. The t represents the time when the flash droughts occur. The t − 2 and t − 1 denote the 1 week and 2 weeks prior to t, while t + 1–t + 4 represent the lagged 1–4 weeks of t, respectively.

Citation: Journal of Hydrometeorology 21, 4; 10.1175/JHM-D-19-0088.1

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Variation of soil moisture percentile for major flash drought events (light colored lines; excludes drought duration less than 4 weeks) of all grids in the study region identified by (a) RIFD and (b) HWFD and PDFD. The dark color line represents the ensemble-mean of all flash drought events. The t represents the time when the flash droughts occur. The t − 2 and t − 1 denote the 1 week and 2 weeks prior to t, while t + 1–t + 4 represent the lagged 1–4 weeks of t, respectively.

Citation: Journal of Hydrometeorology 21, 4; 10.1175/JHM-D-19-0088.1

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(a) The frequency distributions of the mean (the green bar) and maximum (the orange bar) rate of soil moisture decline for all heat wave flash droughts (HWFD) during 1961–2012 over the entire domain. (b) As in (a), but for the P-deficit flash droughts (PDFD). The dotted red and yellow lines in (a) and (b) show the two metrics of RI_max (−10 percentile per week) and RI_mean (−6.5 percentile per week), respectively, for identifying flash droughts.

Citation: Journal of Hydrometeorology 21, 4; 10.1175/JHM-D-19-0088.1

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(a) The frequency distributions of the mean (the green bar) and maximum (the orange bar) rate of soil moisture decline for all heat wave flash droughts (HWFD) during 1961–2012 over the entire domain. (b) As in (a), but for the P-deficit flash droughts (PDFD). The dotted red and yellow lines in (a) and (b) show the two metrics of RI_max (−10 percentile per week) and RI_mean (−6.5 percentile per week), respectively, for identifying flash droughts.

Citation: Journal of Hydrometeorology 21, 4; 10.1175/JHM-D-19-0088.1

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(a) The frequency distributions of the mean (the green bar) and maximum (the orange bar) rate of soil moisture decline for all heat wave flash droughts (HWFD) during 1961–2012 over the entire domain. (b) As in (a), but for the P-deficit flash droughts (PDFD). The dotted red and yellow lines in (a) and (b) show the two metrics of RI_max (−10 percentile per week) and RI_mean (−6.5 percentile per week), respectively, for identifying flash droughts.

Citation: Journal of Hydrometeorology 21, 4; 10.1175/JHM-D-19-0088.1

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The above comparison demonstrates the sensitivity of results to the method of flash drought identification. Since the way for extracting HWFD and PDFD (Mo and Lettenmaier 2015; 2016) only focuses on the threshold of related variables (e.g., precipitation and temperature) and neglects changes in soil moisture with time (Otkin et al. 2018), the method can hardly ensure that the identified events satisfy the moisture limitation (i.e., the drought) and have the characteristic of rapid intensification (i.e., the flash).

b. Frequency of flash droughts

Figure 8 shows the spatial distribution of the FOC (the ratio of weeks under flash drought) indicated by these two methods. For RIFD, the FOC on average varied between 3% and 10%, with high occurrence of flash drought concentrated in the northwestern, southeastern, and southern of source regions (Fig. 8a). As for the two types of flash drought defined by Mo and Lettenmaier (2015, 2016), different patterns of FOC were observed both in the magnitude and spatial distributions. Specifically, the FOC of HWFD on average was less than 3%, with high values located in the southern region. With respect to the PDFD type, the magnitude of FOC increased to 4%–6%, and spatially the source region experienced a lower flash drought frequency. Taking HWFD and PDFD as a whole (i.e., events of HWFD and PDFD were merged into a new sample for calculating FOC), the FOC ranged between 5% and 10%, and presented an increased pattern from northwest to southeast (Fig. 8d). This suggests that different ways for identifying flash droughts would affect drought frequency to some extent. In addition, Wang and Yuan (2018) also analyzed flash drought frequency in China based on the method of Mo and Lettenmaier (2015, 2016), and suggested a similar spatial distribution of HWFD and PDFD with our results, but the values of FOC were generally higher. The different source of soil moisture dataset (global reanalysis products were employed in their study) might be one possible reason. The time period of interest may be another possible reason (Liu et al. 2016) because their study mainly reflects the overall dry status during 1979–2010, which has a different climate condition from 1961 to 2012.

Spatial distribution of the FOC for flash droughts indicated by (a) RIFD, (b) HWFD, (c) PDFD, and (d) sum of HWFD and PDFD (i.e., events of HWFD and PDFD were merged into a new sample for calculating FOC).

Citation: Journal of Hydrometeorology 21, 4; 10.1175/JHM-D-19-0088.1

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Spatial distribution of the FOC for flash droughts indicated by (a) RIFD, (b) HWFD, (c) PDFD, and (d) sum of HWFD and PDFD (i.e., events of HWFD and PDFD were merged into a new sample for calculating FOC).

Citation: Journal of Hydrometeorology 21, 4; 10.1175/JHM-D-19-0088.1

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Spatial distribution of the FOC for flash droughts indicated by (a) RIFD, (b) HWFD, (c) PDFD, and (d) sum of HWFD and PDFD (i.e., events of HWFD and PDFD were merged into a new sample for calculating FOC).

Citation: Journal of Hydrometeorology 21, 4; 10.1175/JHM-D-19-0088.1

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c. Behavior in tracking flash drought

The 1991 flash drought event is selected to explore how the two methods behave in monitoring the spatial evolution of soil moisture. As shown in Fig. 9a, the drought event indicated by soil moisture percentile experienced continuous reduction starting in June 1991 and sustains a rather low value (approximately one-third of the basin area is below the 10th percentile) until the next year. During this process, the period from June to July exhibits a rapid rate of intensification during which the soil moisture percentile sharply decreases from above the 40th percentile to below the 20th percentile over four weeks. Meanwhile, a spatial migration pattern is apparent for the dry condition. As shown in Fig. 9b, the drought center generally experiences a western–eastern–northern shifting mode, with the vegetation types of grassland, cropland, and shrubland suffering in sequence. This spatial variation of vegetation condition is also reflected by the 15-day NDVI anomalies (Fig. 9c). In the following section, we pay special attention to the abilities of each methods to depict the drought migration pattern, as well as in capturing the instantaneous variation of soil moisture.

(a) Time series of weekly soil moisture percentile in 1991. The gray and blue shadows denote the 75th–90th percentile range of soil moisture values over YRB. (b) The three circles with numbers in the middle indicate the moving path of the drought center during June–July in 1991. (c) Spatial evolution of NDVI anomalies (dimensionless; minus the mean then divided by the standard deviation) in June and July 1991. (d) Spatial evolution of the mean and maximum intensification rate of soil moisture, two types of flash droughts defined by Mo and Lettenmaier (2015, 2016), and soil moisture percentile in June and July 1991.

Citation: Journal of Hydrometeorology 21, 4; 10.1175/JHM-D-19-0088.1

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(a) Time series of weekly soil moisture percentile in 1991. The gray and blue shadows denote the 75th–90th percentile range of soil moisture values over YRB. (b) The three circles with numbers in the middle indicate the moving path of the drought center during June–July in 1991. (c) Spatial evolution of NDVI anomalies (dimensionless; minus the mean then divided by the standard deviation) in June and July 1991. (d) Spatial evolution of the mean and maximum intensification rate of soil moisture, two types of flash droughts defined by Mo and Lettenmaier (2015, 2016), and soil moisture percentile in June and July 1991.

Citation: Journal of Hydrometeorology 21, 4; 10.1175/JHM-D-19-0088.1

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(a) Time series of weekly soil moisture percentile in 1991. The gray and blue shadows denote the 75th–90th percentile range of soil moisture values over YRB. (b) The three circles with numbers in the middle indicate the moving path of the drought center during June–July in 1991. (c) Spatial evolution of NDVI anomalies (dimensionless; minus the mean then divided by the standard deviation) in June and July 1991. (d) Spatial evolution of the mean and maximum intensification rate of soil moisture, two types of flash droughts defined by Mo and Lettenmaier (2015, 2016), and soil moisture percentile in June and July 1991.

Citation: Journal of Hydrometeorology 21, 4; 10.1175/JHM-D-19-0088.1

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The initial drought patches, as indicated by the soil moisture percentile, emerge in the source region of YRB on 11 June (Fig. 9d). This dry signal is also captured by RI_mean and RI_max but missed by HWFD and PDFD. In the following week (18 June), the latter method again fails to display dry conditions. According to the NDVI anomalies (Fig. 9c), some parts of the source region exhibited negative values on 21 June, implying that the vegetation health starts to decline, which also signifies the onset of this flash drought event. In such cases, we consider that the ways of defining HWFD and PDFD are less competent to provide early warning for flash drought.

In addition, the HWFD and PDFD may separate a continuous process of flash drought into several independent events and can hardly characterize the spatiotemporal variation of moisture dynamics. For example, both HWFD and PDFD indicate droughts in the source region on 25 June, which is in agreement with the pattern of soil moisture percentile. But in the following week (2 July), the lower values of soil moisture move farther eastward; HWFD and PDFD by contrast, indicate nondrought and fail to capture the spatial migration of this event.

d. Roles of hydrometeorological variables in formulating flash droughts

A potential reason for the unsatisfying performance of the HWFD and PDFD methods could be attributed to the thresholds of hydrometeorological variables that they employ. As mentioned in section 3a, except for soil moisture, their method involves: P anomaly < 0 or P percentile < 40%; T_mean anomaly > 1 standard deviation; AET anomaly > 0 for HWFD, and AET anomaly < 0 for PDFD. In recent papers, other variables such as PET and maximum air temperature (T_max) are also recommended as indicators (Hobbins et al. 2016; Zhang et al. 2017; Otkin et al. 2018). Given this, an investigation on the anomalies (percentile) of related hydrometeorological variables is conducted.

Figure 10 shows the hydrometeorological anomaly values in adjacent weeks of the onset of all flash drought events during 1961–2012 extracted from all grid cells over YRB. The anomalies of all meteorological variables were derived by subtracting the climatological (1961–2012) mean then divided by the standard deviation of that calendar week. As shown in Fig. 10a, the P anomalies are all negative and below 0.5 standard deviation at the week t (i.e., the first week when flash drought occurs), which is consistent with the condition (i.e., P anomaly < 0) set in Mo and Lettenmaier (2015, 2016). Moreover, for 1 week prior to t (i.e., t − 1), more than 75% of flash drought events are under negative P anomalies, suggesting that this threshold can provide some utility for flash drought early warning. The case of the 40th P percentile, in contrast, presents considerable spatial variability and does not work well for all regions of YRB. In Fig. 10b, it can be seen that there exist some cases when precipitation is above the 40th percentile and flash drought occurred. In fact, this phenomenon is not limited to the P percentile; similar patterns are also observed in T_mean and T_max but in a more significant way. As shown in Figs. 10c and 10d, for the majority of flash drought events in the YRB, corresponding air temperature values rarely exceed one standard deviation. This means substantial flash drought events would be excluded by this truncated level. To verify this conjecture, the spatial variation of these thresholds during June–July in 1991 is investigated (Fig. 11). Obviously, the T_mean anomaly is the main factor for the poor performance of the HWFD and PDFD. In contrast, the AET anomaly is generally above normal in the early period of flash drought (11 June in Fig. 11) and exhibits negative values when the conditions become water limited (the P anomaly is significantly negative and the PET anomaly is positive). This indicates that AET may not be a good indicator of flash drought. It plays a minimal role in judging whether or not flash drought occurs; however, it does have some implications for understanding the physical mechanisms of heat wave and precipitation deficit flash droughts (Figs. 10f and 11). A similar phenomenon was also found in the central United States, where the anomalies of evaporation do not appear to be stronger during the flash drought onset (Koster et al. 2019). From the perspective of atmospheric evaporative demand, PET integrates the effects of wind, humidity, temperature, and solar radiation, which can be viewed as a more comprehensive indicator of how much moisture is consumed. As shown in Fig. 10e, more than half of the PET anomalies exhibit positively biased patterns at week t − 1, then the evaporative demand quickly expands and reaches the peak at the onset of flash drought. In other words, PET anomalies can vary synchronously with the soil moisture dynamics during the flash drought process and could be viewed as a driver in the changes of soil moisture (Hobbins et al. 2016; Otkin et al. 2018).

Boxplots of the anomaly values of hydrometeorological variables in adjacent weeks of the onset of all flash drought events during 1961–2012 extracted from all grid cells over YRB. The red solid lines in each panel indicate the thresholds given by Mo and Lettenmaier (2015, 2016). The t represents the time node when the flash droughts occur. The t − 2 and t − 1 denote the 1 week and 2 weeks prior to t, while t + 1– t + 4 represent the delayed 1–4 weeks of t, respectively. The anomalies of all meteorological variables were dimensionless and derived by subtracting the climatological (1961–2012) mean then dividing by the standard deviation of that calendar week.

Citation: Journal of Hydrometeorology 21, 4; 10.1175/JHM-D-19-0088.1

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Boxplots of the anomaly values of hydrometeorological variables in adjacent weeks of the onset of all flash drought events during 1961–2012 extracted from all grid cells over YRB. The red solid lines in each panel indicate the thresholds given by Mo and Lettenmaier (2015, 2016). The t represents the time node when the flash droughts occur. The t − 2 and t − 1 denote the 1 week and 2 weeks prior to t, while t + 1– t + 4 represent the delayed 1–4 weeks of t, respectively. The anomalies of all meteorological variables were dimensionless and derived by subtracting the climatological (1961–2012) mean then dividing by the standard deviation of that calendar week.

Citation: Journal of Hydrometeorology 21, 4; 10.1175/JHM-D-19-0088.1

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Boxplots of the anomaly values of hydrometeorological variables in adjacent weeks of the onset of all flash drought events during 1961–2012 extracted from all grid cells over YRB. The red solid lines in each panel indicate the thresholds given by Mo and Lettenmaier (2015, 2016). The t represents the time node when the flash droughts occur. The t − 2 and t − 1 denote the 1 week and 2 weeks prior to t, while t + 1– t + 4 represent the delayed 1–4 weeks of t, respectively. The anomalies of all meteorological variables were dimensionless and derived by subtracting the climatological (1961–2012) mean then dividing by the standard deviation of that calendar week.

Citation: Journal of Hydrometeorology 21, 4; 10.1175/JHM-D-19-0088.1

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Spatial anomalies of related meteorological variables for the 1991 flash drought.

Citation: Journal of Hydrometeorology 21, 4; 10.1175/JHM-D-19-0088.1

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Spatial anomalies of related meteorological variables for the 1991 flash drought.

Citation: Journal of Hydrometeorology 21, 4; 10.1175/JHM-D-19-0088.1

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Spatial anomalies of related meteorological variables for the 1991 flash drought.

Citation: Journal of Hydrometeorology 21, 4; 10.1175/JHM-D-19-0088.1

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In general, the unsatisfying performance of HWFD and PDFD can be attributed to two aspects, that is, the variable selection and corresponding thresholds. The case study in YRB suggests the overly rigid threshold of temperature (i.e., T_mean anomaly > 1 standard deviation) may lead to some omission in capturing the onset of the event. Some trials by lowering the threshold of the temperature anomaly (e.g., relaxing from one standard deviation to a half standard deviation or other values according to the climate conditions and soil moisture dynamics of the study region) can be made in future studies to improve the performance of HWFD and PDFD. In contrast, PET exhibits the potential of being a precursor signal for indicating drought and can be employed as an alternative in future studies. In addition, since more attention is given to the occurrences of flash drought in determining the thresholds of related variables, the approach proposed by Mo and Lettenmaier (2016) can hardly guarantee the identified events all have the rapid intensification characteristic. An improved flash drought identification result would be expected by introducing the intensification rate in their objective function of threshold selection.