A 424-year tree-ring-based Palmer Drought Severity Index reconstruction of &amp;lt;i&amp;gt;Cedrus deodara&amp;lt;/i&amp;gt; D. Don from the Hindu Kush range of Pakistan: linkages to ocean oscillations

Ahmad, Sarir; Zhu, Liangjun; Yasmeen, Sumaira; Zhang, Yuandong; Li, Zongshan; Ullah, Sami; Han, Shijie; Wang, Xiaochun

doi:10.5194/cp-16-783-2020

Cited by 19 publications

(20 citation statements)

References 93 publications

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“…A significant positive correlation of our reconstructed PPT JJA with reconstructed JJA PDSI (r = 0.20, p < 0.001) from monsoon Asia during the period 1780-2005 (Cook et al, 2010) and May-September precipitation (r = 0.14, p < 0.05) from Bhutan Himalaya (Sano et al, 2013) during the period 1780-2011 further indicates regional linkages. The late 18th century droughts from 1785 to 1794s in JJA PDSI (Cook et al, 2010), March-September precipitation (Sano et al, 2013), March-September PDSI (Ahmad et al, 2020), and March-July precipitation (Singh et al, 2009), as well as historical East India Drought (1790-1796), are also common in our reconstructed precipitation data (Figure 8). Similarly, the dry episodes of 1830-1836 synchronize with May-September precipitation reconstruction (Sano et al, 2013).…”

Section: Salient Features Of Reconstructed Ppt Jjamentioning

confidence: 67%

“…Similarly, the dry episodes of 1830-1836 synchronize with May-September precipitation reconstruction (Sano et al, 2013). The other common dry phase of 1865-1875 in March-September PDSI (Ahmad et al, 2020), MS precipitation (Sano et al, 2013), May-June PDSI (He et al, 2018), and the previous year October to current year September precipitation reconstruction (Singh et al, 2021) FIGURE 8 Comparison of (A) reconstructed PPT JJA with (B) JJA PDSI reconstruction from Asia (Cook et al, 2010), (C) May-September (MS) precipitation reconstruction from Bhutan Himalaya (Sano et al, 2013), and (D) previous October-Current September (pOcS) precipitation reconstruction from Indian Western Himalaya (Singh et al, 2021). All the line plots are smoothed by a 10-year low-pass smoothing filter.…”

Section: Salient Features Of Reconstructed Ppt Jjamentioning

confidence: 71%

“…During the monsoon season, years with high snowfall in the preceding winter and spring are followed by summer with less monsoon rain (Blanford, 1884;Bamzai and Kinter, 1997). This is further reinforced by the idea that greater wetness in the northwestern Himalayas has influenced anomalous glacier progress in recent years and that increasing snowfall may contribute to dry conditions in summer (Yadav et al, 2017;Ahmad et al, 2020). Interestingly, since 2010, an increase in Indian summer rainfall has been reported in several gridded and observed datasets throughout the Indian subcontinent (Jin and Wang, 2017).…”

Section: Salient Features Of Reconstructed Ppt Jjamentioning

confidence: 92%

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Tree rings of Rhododendron arboreum portray signal of monsoon precipitation in the Himalayan region

Dhyani¹,

Bhattacharyya²,

Joshi³

et al. 2023

Front. For. Glob. Change

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The Himalayas has a significant impact not just on the Indian subcontinent’s monsoon patterns but also on the global climate. Monsoon failure causing drought has become more common in recent years. As a result, it poses a major threat to ecosystem sustainability. We reported for the first time, a climatic-sensitive tree ring chronology of a broadleaf tree, Rhododendron arboreum, spanning 1732–2017 CE from the Himalayan region. We discovered that the climate during the monsoon season limits the growth of this tree in this region. The correlation analysis between tree ring chronology and climate revealed a significant positive relationship with precipitation (r = 0.63, p < 0.001) and a negative relationship with temperature (r = −0.48, p < 0.01) during the months of June–August (JJA). This strong relationship allowed us to reconstruct monsoon precipitation spanning 1780 to 2017 CE which explained 40% of the variance of the observed climate data for the calibration period. The reconstructed data are validated by the existence of a significant association with the gridded JJA precipitation data of the Climate Research Unit (CRU) of this region. The monsoon rainfall record captured extremely wet years during 1793, 1950, 2011, 2013, and 2017 and extremely dry years during 1812, 1833, 1996, 2002, 2004, and 2005. The extremely dry and wet years well coincided with major catastrophic historical and instrumental droughts and floods in the region. Furthermore, the reconstructed data are also validated by the significant positive correlation (r = 0.36, p < 0.001, n = 163) with the all Indian summer monsoon rainfall series. Such data will be useful to predict the incidence of future droughts, which can help to assess the vulnerability of the forest ecosystem to extreme events.

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Section: Salient Features Of Reconstructed Ppt Jjamentioning

confidence: 67%

Section: Salient Features Of Reconstructed Ppt Jjamentioning

confidence: 71%

Section: Salient Features Of Reconstructed Ppt Jjamentioning

confidence: 92%

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Tree rings of Rhododendron arboreum portray signal of monsoon precipitation in the Himalayan region

Dhyani¹,

Bhattacharyya²,

Joshi³

et al. 2023

Front. For. Glob. Change

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“…The SPI12‐May reconstruction revealed relatively wetter conditions in the early 17th to the mid‐18th century (1613–1750s CE), where SPI values are close to the long‐term mean, however, the late 18th to the early 21st century (1760s–2017 CE) showed repeated occurrence of mega‐droughts over the region (Figure 3b). The long‐term drought records from the Himalaya, though limited (Ahmad et al., 2020; Bhandari et al., 2019; Cook et al., 2010; Gaire et al., 2019; Panthi et al., 2017; Ram, 2012; Singh et al., 2017; Yadav, 2013; Yadav et al., 2015, 2017), show large‐scale spatial hydroclimatic variability. A comparison of present SPI12‐May series with other drought records developed from the high‐altitude western Himalayan region where precipitation is largely governed by the midlatitude westerlies during winter and spring seasons was done.…”

Section: Resultsmentioning

confidence: 99%

Increasing Incidence of Droughts Since Later Part of Little Ice Age Over North‐Western Himalaya, India

et al. 2022

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“…However, this statement varies from species to species and even from site to site. For example, in a dry region the species mostly grow at medium altitudes and show marks linked with rainfall and drought (Ahmad et al 2020). In general, concerning the radial growth with increasing altitude, the positive effect of precipitation in the lowlands changes to the negative effect in mountainous areas (Sidor et al 2015;Putalová et al 2019;Vacek et al 2019).…”

Section: Discussionmentioning

confidence: 99%

Radial growth, present status and future prospects of west Himalayan fir (Abies pindrow Royle) growing in the moist temperate forest of Himalayan mountains of Pakistan

Rauf¹,

Khan²,

Siddiqui³

et al. 2022

J. For. Sci.

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Forests play a significant role for maintaining the biodiversity. In order to manage sustainable forests, tree species history, distribution, and their future prospects are vital. Using standardized quantitative approaches, the age, radial growth, and size class distribution of Abies pindrow (Himalayan fir) were determined from three different altitudinal sites (i.e. high, middle, and lower). The results indicate that Himalayan fir growing in the high-altitude site (Ayubia, 2 917 m a.s.l.) of moist temperate forests of the Himalayan mountains showed lower radial growth (0.13 cm) than in the middle (Bara Gali, 2 617 m a.s.l.; radial growth = 0.13 cm) and lower (Kuldana, 2 455 m a.s.l.; radial growth = 0.22 cm) altitude sites. Correlation analysis demonstrated that age showed a significant positive correlation (P < 0.001) with diameter at breast height. The tree-ring width chronology (totally 80 core samples) of Himalayan fir was developed from moist temperate forests of Himalayan mountains of Pakistan. At Ayubia site it possesses a long time-span (1703–2020 C.E.), followed by Bara Gali (1862–2020 C.E.) and Kuldana (1864–2020 C.E.). Further, the tree-ring width (TRW) chronology of Ayubia showed a significant positive correlation (P < 0.05) with May and June temperature, and a significant negative correlation (P < 0.05) with June and October precipitation, indicating that summer temperatures are the key factor for the radial growth of Himalayan fir. For the Kuldana site, the response of TRW chronology to temperature and precipitation was the same, however, it was significant only for June temperature at Bara Gali. The size class distribution of the high-altitude region (Ayubia) showed a higher number of individuals than the lower altitude region, indicating the lowest disturbance conditions. The absence of individuals in the early size classes and the gap in middle and mature size classes indicate a lower regeneration potential and anthropogenic impact. The pointer year analysis indicated that the Bara Gali forest is more sensitive to abnormal climate events than the other sites. Based on the present study, we suggest that proper attention and conservation strategy should be provided to Himalayan fir growing in the moist temperate forests of Pakistan.

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A 424-year tree-ring-based Palmer Drought Severity Index reconstruction of <i>Cedrus deodara</i> D. Don from the Hindu Kush range of Pakistan: linkages to ocean oscillations

Cited by 19 publications

References 93 publications

Tree rings of Rhododendron arboreum portray signal of monsoon precipitation in the Himalayan region

Tree rings of Rhododendron arboreum portray signal of monsoon precipitation in the Himalayan region

Increasing Incidence of Droughts Since Later Part of Little Ice Age Over North‐Western Himalaya, India

Radial growth, present status and future prospects of west Himalayan fir (Abies pindrow Royle) growing in the moist temperate forest of Himalayan mountains of Pakistan

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