@article{crowley1986role,
author = "Crowley, Thomas J. and Short, David A. and Mengel, John G. and North, Gerald R.",
title = "Role of Seasonality in the Evolution of Climate During the Last 100 Million Years",
year = "1986",
journal = "Science",
abstract = {A simple climate model has been used to calculate the effect of past changes in the land-sea distribution on the seasonal cycle of temperatures during the last 100 million years. Modeled summer temperatures decreased over Greenland by more than 10°C and over Antarctica by 5° to 8°C. For the last 80 million years, this thermal response is comparable in magnitude to estimated atmospheric carbon dioxide effects. Analysis of paleontological data provides some support for the proposed hypothesis that large changes due to seasonality may have sometimes resulted in an ice-free state due to high summer temperatures rather than year-round warmth. Such "cool" non-glacials may have prevailed for as much as one-third of the last 100 million years.},
url = "https://doi.org/10.1126/science.231.4738.579",
doi = "10.1126/science.231.4738.579",
number = "4738",
pages = "579-584",
volume = "231"
}
@misc{crowley1986role1,
author = "Crowley, T. J. et al",
title = "Role of seasonality in the evolution of climate during the last 100 million years",
year = "1986",
howpublished = "Science, v. 231, p. 579-584",
note = "talkorigins\_source = {true}; raw\_reference = {Crowley, T. J. et al., 1986, Role of seasonality in the evolution of climate during the last 100 million years: Science, v. 231, p. 579-584.}"
}
@article{doi101126science2314738579,
author = "Crowley, T J and Short, D A and Mengel, J G and North, G R",
title = "Role of seasonality in the evolution of climate during the last 100 million years.",
year = "1986",
journal = "Science (New York, N.Y.)",
abstract = {A simple climate model has been used to calculate the effect of past changes in the land-sea distribution on the seasonal cycle of temperatures during the last 100 million years. Modeled summer temperatures decreased over Greenland by more than 10 degrees C and over Antarctica by 5 degrees to 8 degrees C. For the last 80 million years, this thermal response is comparable in magnitude to estimated atmospheric carbon dioxide effects. Analysis of paleontological data provides some support for the proposed hypothesis that large changes due to seasonality may have sometimes resulted in an ice-free state due to high summer temperature rather than year-round warmth. Such "cool" non-glacials may have prevailed for as much as one-third of the last 100 million years.},
url = "https://pubmed.ncbi.nlm.nih.gov/17750969/",
doi = "10.1126/science.231.4738.579",
pmid = "17750969"
}
@article{clark2012global,
author = "Clark, Peter U. and Shakun, Jeremy D. and Baker, Paul A. and Bartlein, Patrick J. and Brewer, Simon and Brook, Ed and Carlson, Anders E. and Cheng, Hai and Kaufman, Darrell S. and Liu, Zhengyu and Marchitto, Thomas M. and Mix, Alan C. and Morrill, Carrie and Otto-Bliesner, Bette L. and Pahnke, Katharina and Russell, James M. and Whitlock, Cathy and Adkins, Jess F. and Blois, Jessica L. and Clark, Jorie and Colman, Steven M. and Curry, William B. and Flower, Ben P. and He, Feng and Johnson, Thomas C. and Lynch-Stieglitz, Jean and Markgraf, Vera and McManus, Jerry and Mitrovica, Jerry X. and Moreno, Patricio I. and Williams, John W.",
title = "Global climate evolution during the last deglaciation",
year = "2012",
journal = "Proceedings of the National Academy of Sciences",
abstract = "Deciphering the evolution of global climate from the end of the Last Glacial Maximum approximately 19 ka to the early Holocene 11 ka presents an outstanding opportunity for understanding the transient response of Earth’s climate system to external and internal forcings. During this interval of global warming, the decay of ice sheets caused global mean sea level to rise by approximately 80 m; terrestrial and marine ecosystems experienced large disturbances and range shifts; perturbations to the carbon cycle resulted in a net release of the greenhouse gases CO 2 and CH 4 to the atmosphere; and changes in atmosphere and ocean circulation affected the global distribution and fluxes of water and heat. Here we summarize a major effort by the paleoclimate research community to characterize these changes through the development of well-dated, high-resolution records of the deep and intermediate ocean as well as surface climate. Our synthesis indicates that the superposition of two modes explains much of the variability in regional and global climate during the last deglaciation, with a strong association between the first mode and variations in greenhouse gases, and between the second mode and variations in the Atlantic meridional overturning circulation.",
url = "https://doi.org/10.1073/pnas.1116619109",
doi = "10.1073/pnas.1116619109",
number = "19",
volume = "109"
}
@misc{neupane2019tectonics,
author = "Neupane, Bhupati and Zhao, Junmeng and Dhakal, Sanjev",
title = "Tectonics Influence The Climate Change In The Himalayan Orogenic Belt",
year = "2019",
publisher = "Zenodo",
abstract = "Introduction
The high altitude mountain system (i.e., Himalaya) and the Tibetan Plateau region formed after the intracontinental collision of the Indian and Eurasian plates during 55–50 Ma (Neupane et al., 2017 and reference therein). The Himalayan range, separating the plains of the Indian subcontinent from the Tibetan Plateau, extends 2,400 km-long from east - Namcha Barwa and west Nanga Parbat south of the northernmost bend of Indus river. The entire Himalayan region divided into four tectonostratigraphic zones from south to north;the Tethys Himalaya, Higher Himalaya, Lesser Himalaya, and Sub Himalayan which are bounded and separated by several south propagating,north-dipping thrust/fault systems in different time spans (Neupane et al., 2018 and reference therein). The significant climate change occurred in Tibetan Plateau after rapidly uplifted at 7-8 Ma (Kappa et al., 2008; Murphy et al., 1997). The mechanics of the fold-and-thrust belts that flank many collisional mountain ranges, where the role of erosion in the tectonic evolution of mountain ranges was well known in the mid-1980s (Whipple, 2009). Dahlen et al. (1984), Davis et al. (1983) Stockmal (1983) described tapering wedges theory, a combination of sandbox experiments, analytical treatments of stress state and field observations which explained that fold-and-thrust belts form tapering wedges. After the advancement of critical-taper theory, researchers applied the rate and pattern of erosion of critical-taper orogenic wedges effectively dictates many aspects of the tectonic and structural evolution of mountain belts.Erosional efficiency determines the rate of erosion for a particulartopography and depends on rock type, debris size, and climate(Whipple, 2009). The deformational and exhumation response to induced by enhanced precipitation on windward slopes and rainshadow development on leeward slopes, which is well matched by near-surface rock-uplift patterns and the metamorphic grade of exposed rocks in several active mountain ranges.
Recently, Mountainous Region suffers several climatic impacts on several sectors like water availability, biodiversity, high-elevation ecosystem changes, monsoonal shifts, and loss of soil carbon (Xu et al., 2008). Mountainous region is sensitive indicators of climate change (Nijssen et al., 2001). These are also vulnerable to soil erosion, landslides, GLOF, and the rapid loss of habitat and genetic diversity. In several developing countries, in part because of the degradation of the natural environment, there is widespread unemployment, poverty, poor health and bad sanitation (Price et al., 2000).
Fig.1: a) Location map of the Greater Himalayan region showing all areas with alpine (red), montane (yellow) zones, major river system and has impacts on lowland areas (light green) (adapted from (Qiu, 2008; Xu, 2008). b) General geological map of Himalaya (modified after Neupane et al., 2018)
There are several researchers studies in the Himalayas and found that glaciers in the region have retreated significantly in the last two decades (Owen et al., 2002; Parmesan, 2006; Price et al., 2000; Qiu, 2008). Recently, some researchers identified the formation and growth of a number of glacial lakes, possibility to retreat of glaciers, which could lead to the catastrophic outburst,floods (Owen et al., 2005). Some of the researchers believed that the main cause of Glacier retreat is global warming. Fluctuations in air temperature and precipitation also affect the glacier fluctuation over the last decade (Owen et al., 1998). The climatic impact caused the Himalayan glaciers have been retreating since 1850 A.D. It is possible that the cooling in 1940 observed in the global record caused reformed of these glaciers, and the warming after the mid-1970s resulted in accelerated shrinking in the past two decades (Owen et al., 2000). The Himalaya and Tibetan Plateau play a significant role in regional climate, which affect the monsoon circulation. Associations of the monsoon and other global-scale phenomena extend the implications of climatic variations in the Himalaya and in the Tibetan Plateau beyond the regional scale (Bolch et al., 2012; Immerzeel et al., 2010). The analysis of climatic variables showed a considerable increase in minimum and maximum temperature during the last century (i.e. 1901–2017) coupled with a continuous increase in solid precipitation (Taloor et al., 2018).
The Greater Himalayan region is also known as the Water Tower of Asia, covers approximately 7 million km2(Xu et al., 2008) (Fig. 1). They are the source of 10 of the largest rivers in Asia (Fig. 1). Therefore, these basins provide water for about 1.3 billion people who stay near this area (Paul A and Jeschke, 1979). All over the world the mountains area like Andes Himalayas, from Southeast Asia to East and Central Africa, there is serious ecological deterioration. Mainly the mountain areas are experiencing environmental degradation. About 40\% of the global population lives in the watersheds of rivers originating in the planet's different mountain ranges (Benn and Owen, 1998). Mountains also symbolize the unique areas for the detection of climatic change and the assessment of climate-related impacts.
The great climatic impact on the climate of the Himalayan regions caused the effects on glacier mountains, cascading effects on river flows, groundwater recharge, natural hazards, and biodiversity; ecosystem composition, structure, and function; and human livelihoods (Nijssen et al., 2001; Parmesan, 2006).
2. Overview of recent climate change study in the greater Himalaya region
There are several researchers involved to explain the problem and they applied different methods to acquire some concept about climate change and its impact on Greater Himalayan region.Owen et al. (2002) reconstructed the different numerical data and Barnard and Owen et al. ( 2000) reviewed the glacial geology of other Himalayan regions and for a selective bibliography for Late Quaternary glaciations in Tibet and the bordering mountains. They also used the optically stimulated luminescence (OSL) and cosmogenic radionuclide (CRN) surface exposure dating of moraines and their associated landforms.For the similar purposed Paul and Jeschke, (1979)studied on the topic of the Himalaya and trans- Himalaya glacier fluctuation since AD 1812. They update previous summaries and introduce an additional 27 glaciers for a total of 112 records of glacier fluctuations in the Himalayan and Trans – Himalayan area. Data used in this synthesis are presented in the form of frequency diagrams of glacier activity in which glacier activity is plotted for 10-yr periods.
Fig. 2: The current elevational distribution of life zones in the central Himalayas (top) showing the future climate distribution (bottom) with a 5 ◦C temperature rise (Xu et al., 2008).
Similarly, Xu et al. (2008)described the issue of Melting Himalayas; cascading Effects of Climate Change on Water, Biodiversity, and Livelihoods. They compiled data on temperature and Precipitation, Glacial Response, Runoff and River Responses, Water-Related Hazards, Phenology, Pollination, and Predator-Prey Interactions, Endemism, and Extinction, Shifting Tree Lines, Ecosystem Composition and Dynamics, Cascading Effects, Effects on Ecosystems and Livelihoods, Downstream and Global Effects (Fig. 2).
Bolch et al. (2012) worked on the Himalayan Glaciers trend to used mainly historic data; vary between 43,178 km2 and 49,650 km2. The researcher used the recent satellite images and remote sensing for mapping purposed. They described some model for the glacier, which discusses projections of possible future changes, summarize important implications for water resources and natural hazards, and close by sketching a framework for integrated cryosphere research needed to fill the most critical gaps.Impact of warmer climate on melt and evaporation for the rainfed, snowfield and glacier-fed basins in the Himalayan region, Singh and Bengtsson (2005) used the different method for this research. Researchers mention the different parameters during the research, projected climatic changes over Indian sub-continent and India, hydrological models and structure of snowmelt model.
Zhisheng et al. (2001) proposed climate-model simulations, which show that continued uplift andexpansion of the plateau along its northern and eastern margins increases both summer and winter monsoons in the region of the Loess plateau/East Asia and continues the drying trend in central Asia. Where a little change in the general Asian summer monsoon circulation or the Indian monsoon precipitation. In the central Himalaya (Nepal), Blythe et al. (2007) and Huntington et al. (2006), have documented an acceleration of long-term rock cooling rates starting between 0.9 and 2.5 Myr, roughly coincident with the onset of Quaternary glaciations. Due to the absence of evidence for far-field tectonic change and for a change in structural geometry over this time interval, Huntington et al. (2006)suggested that this change in cooling rate represents a climatically triggered acceleration of exhumation rate. Taloor et al. (2018) studied in the Tectono-climatic response to landscape changes in the glaciated Durung Drung basin, Zanskar Himalaya, India, and they analyzed through quantitative morphometric analysis emphasizing on topography and landscape changes in glaciated that basin.
3. Discussion and interpretation
From the above results of Owen at al. (2002), obtained results indicate that the similar pattern of glaciation occurred in each study area and local LGM occurred early in the last glacial cycle. Similar hypothesis purposed by (Gillespie and Molnar, 1995) and (Benn and Owen, 1998), the maximum extent of glaciation in the Himalaya occurred before then the LGM spaced along the length of the Himalaya. It suggests that restricted glacier advance during the LGM is characteristic of the entire Himalaya. The nature of glaciations of the Himalaya controls the dominant climatic system of South Asian summer monsoon (Benn and Owen, 1998). (Benn and Lehmkuhl, 2000), have warned of the difficulties of determining ELAs on the steep debris-covered glaciers in the high-altitude Himalaya where the relationship between glacier mass-balance characteristics and climatic variables such as precipitation and air temperature is very complex in these situations.
The fluctuation records of glaciers in the Himalayas differ from those of glaciers in the Trans-Himalayas (Paul A and Jeschke, 1979). Most of the glaciers in the Himalayas have been in a general state of retreat since AD 1850. In the same task, sampling a much smaller number of glaciers than the number sampled, (Tewari, 1971), found the similar result of that the Himalayan glaciers were in a general state of retreat while the Trans-Himalayan glaciers have a more complicated record.
The obtained results in (Fig. 2), the current elevation distribution of life zones in the Himalayas and their distribution with a 50C temperature rise (Xu et al., 2009), indicated that elevational distribution of life zones would shift significantly. An additional effect on alpine vegetation shrank, evergreen forest decreased significantly, and tropical lowland forest increased. The effect of warm climate is the region of temperature increases, shifts in ecosystems, and increased frequency and duration of extreme events. This research deals three types of adaptation occurred in Himalayan regions; local community, urban and rural, and regional and transboundary.
(Bolch et al., 2012) observed the change of length more than 100 glaciers in Himalaya and Karakoram(H-K), suggest that most Himalayan glaciers have been retreating since the mid-19th century, except for 1920 to 1940. In the eastern Hindu Kush, west of the Karakoram, 25\% of the glaciers were stable or advancing from 1976 to 2007. North of the Karakoram, in the Wakhan Pamir, glaciers were retreating during a similar period.
Thousands of glaciers in H-K were changed the original position due to the warm climate. Therefore, the area change data shows that the Yarkant basin north of the main ridge, loss rate was \textasciitilde 0.1\% year−1 between 1962 and 1999. Similarly, high-altitude glaciers in the Transhimalaya of Ladakh had a shrinkage rate of \textasciitilde 0.4\% year−1 from 1969 to 2010 and the Indian Himalaya, shrinkage rates are regionally variable: \textasciitilde 0.2 to \textasciitilde 0.7\% year−1, the 1960s to 2001– 2004. Likewise, (von Cvitković et al., 1935)and (Mayewski and Jeschke, 1979) deals the same trend of results. The above result indicates that the warm and diverse climate directly affect the Glacier.
(Singh and Bengtsson, 2005) explained the current effect in Himalayan regions which shows a comparison of the annual evaporation occurred in different types of basins under current temperature (T + 20C) condition and warmer climate (T + 2 0C) scenario.
Fig. 3:Uplifted tectonic of the Himalaya – Tibetan Plateau influence by erosion. a, Schematic paleogeographic cross-sections of the Himalaya and Tibetan Plateau modified from Neupane et al. (2017); MCT, Main Central Thrust; GT, Gangdese thrust; STDS, South Tibetan Detachment System; GCB, Gangrinboche Conglomerates; TTS, Tanggula Thrust System; NKLF, North Kunlun Fault; SQF, South Qilian Mountain Fault; NQF, North Qilian Mountain Fault; MBT, Main Boundary Thrust; GCT, Great Counter-Thrust; MFT, Main Frontal Thrust. IGP, Sw, LH, GHS, THS refer to Indo Gangetic Plain, Siwalik, Lesser Himalaya, Grater Himalaya sequences, Tethyan Himalayan sequences. b, the uplifted grater Himalayan metamorphic rocks are experiences rapid erosion and removal of material at the southern margin of the Himalayan flank allows the movement of a channel of hot, weak ductile rock (pink regions).
Therefore, an increase in temperature from 1 to 30 C for the rainfed basin, the increase in annual evaporation was computed to be about 6–18\% for the rainfed basin and 13–35\% for the snowfield basin. The adverse effect on river runoff is likely to affect the watersheds within the mountains that create the problems in lowland regions, which are heavily dependent on this mountain resource (Singh and Bengtsson, 2005). Because these systems are sensitive to climatic factors and are likely to have different vulnerability thresholds according to the species, the amplitude, and the rate of climatic change (Dale et al., 2001).
The climatic model results (Zhisheng et la., 2001)suggested that the relatively large high-elevation area that we insert in the model in going from stage, presumably reflecting elevation changes that occurred no later than about 8 Myr ago, are sufficient to alter significantly the thermally forced circulation and establish strong continent-scale summer and winter monsoons and central Asian aridity.The channel-flow model (Whipple, 2009) suggest a number of key attributes of Himalayan geology; extrusion of the GHS by means of contemporaneous slip. Between the MCT and STD, the conditions and timing of metamorphism in the GHS and LHS and, the formation of the chain of gneiss domes north of the Himalaya (Fig. 3).
The monsoon in Himalaya was well established in the Miocene (Huntington et al., 2006; Kroon et al., 1991) which indicate that vigorous glacial erosion in the higher and drier mountain peaks to the north was important: consistent with the argument above that vigorous glacial erosion may counterbalance the northward decline in precipitation through the Himalaya. A large number of glaciers now terminate on such slopes in a state of gravitational disequilibrium.Similarly, recent climate change impact in the Greater Himalayan region affected by several sectors. Hydrological cycle will be affected by the absence of snow and ice. Therefore, the current distribution, seasonality, and the amount of precipitation may experience significant changes in various geographical regions.
The current evidence from the above review suggests that climate change affects the entire Himalayan region; temperature increases, shifts in ecosystems, and increased frequency and duration of extreme events. It will be significant changes in volumes and timing of river flows and freshwater sources.The complex geological structure, the rugged and steep topography, insufficient exposures, dense forests, and high altitude are a major problem in the Himalayas. There was not much research carried out the region and contains many research gap from East to west Himalaya.
4. Conclusions and future works
Although many field observation, experiments, and hypothesis (erosion-induced channel-flow hypothesis) existed, it is quite complicated to make arguments that erosional control of deformation rates and patterns is shown in the topography, geology and thermal history of the Himalayan regions. Erosion and deformation rate in the mountain system have arisen in the scope of studies aiming to test the hypothesis that climate can significantly influence the tectonic and structural evolution of mountain ranges.The measurable climate parameters and erosional efficiency relation should be studied well. The above results and models related to tectonic–surface process predict that the tectonic and structural evolution of a mountain belt is sensitive to spatial and temporal variations in erosional efficiency. The erosional efficiency is directly linked with precipitation, whenever this link has been quantitatively established can the assessment of spatial correlations between climate and deformation rates and patterns move beyond speculation.There are several basins located tectonically active mountain fronts which are overfilled by sediments detritus, where precipitation and erosion play the major role for sedimentation in the regions where erosion controls the tectonics.Different drainage basin asymmetry of the Himalaya suggests tilting, active upliftment, and dynamic incision.
Glacier is the most important part of the Greater Himalayan regions. Recently, the global warming effect shown in the period of glaciations, affect the nature of environmental change and the landscape evolution in the mountains of Central Asia. It shows the essential relations between climate change and glaciation in the Himalaya. The rate of accumulation of glaciers is less than the rate of retreat, effects on the South Asian summer monsoon system. The historical records of glacier fluctuations in the Himalayas and Trans-Himalayas extend back over 150 years. Recent deglaciation triggered the Catastrophic events consist of ice avalanches, landslides and slope instability caused by debuttressing, and outburst floods from moraine- and glacier-dammed lakes.
To addressing the research gaps, we recommend, more widespread and long-term tracking of glacial ice volumes, studying the paleoclimate for greater Himalayan regions, further work is required to synthesize a set of testable hypotheses to guide field evaluation of the potential role of climate and erosion in shaping the evolution of such systems.
Acknowledgments
We would like to thanks a number of scientists whose work we have referenced here. This study was funded by the National Natural Science Foundation of China (Grant No.41661144026), and the major program of the National Natural Science Foundation of China (Grant No. 41490611).",
url = "https://zenodo.org/record/3250423",
doi = "10.5281/zenodo.3250423"
}
@inproceedings{andrincon2020natural,
author = "Rincon, Aldo and Arjona, Luis A. and Gasson, Rafael and Pirlo, Jeanette and Hulbert, Richard C. and Martin, Juan",
title = "NATURAL HERITAGE: LANDSCAPE EVOLUTION OF TROPICAL AMERICA DURING THE LAST 23 MILLION YEARS",
year = "2020",
booktitle = "Geological Society of America Abstracts with Programs",
url = "https://doi.org/10.1130/abs/2020am-355414",
doi = "10.1130/abs/2020am-355414"
}
@inproceedings{andscotese2021phanerozoic,
author = "Scotese, Christopher",
title = "PHANEROZOIC PALEOTEMPERATURES: THE EARTH’S CHANGING CLIMATE DURING THE LAST 540 MILLION YEARS",
year = "2021",
booktitle = "Geological Society of America Abstracts with Programs",
url = "https://doi.org/10.1130/abs/2021am-371083",
doi = "10.1130/abs/2021am-371083"
}
@article{doi101038s41586021041957,
author = "Beaufort, Luc and Bolton, Clara T and Sarr, Anta-Clarisse and Suchéras-Marx, Baptiste and Rosenthal, Yair and Donnadieu, Yannick and Barbarin, Nicolas and Bova, Samantha and Cornuault, Pauline and Gally, Yves and Gray, Emmeline and Mazur, Jean-Charles and Tetard, Martin",
title = "Cyclic evolution of phytoplankton forced by changes in tropical seasonality.",
year = "2022",
journal = "Nature",
abstract = "Although the role of Earth's orbital variations in driving global climate cycles has long been recognized, their effect on evolution is hitherto unknown. The fossil remains of coccolithophores, a key calcifying phytoplankton group, enable a detailed assessment of the effect of cyclic orbital-scale climate changes on evolution because of their abundance in marine sediments and the preservation of their morphological adaptation to the changing environment1,2. Evolutionary genetic analyses have linked broad changes in Pleistocene fossil coccolith morphology to species radiation events3. Here, using high-resolution coccolith data, we show that during the last 2.8 million years the morphological evolution of coccolithophores was forced by Earth's orbital eccentricity with rhythms of around 100,000 years and 405,000 years-a distinct spectral signature to that of coeval global climate cycles4. Simulations with an Earth System Model5 coupled with an ocean biogeochemical model6 show a strong eccentricity modulation of the seasonal cycle, which we suggest directly affects the diversity of ecological niches that occur over the annual cycle in the tropical ocean. Reduced seasonality in surface ocean conditions favours species with mid-size coccoliths, increasing coccolith carbonate export and burial; whereas enhanced seasonality favours a larger range of coccolith sizes and reduced carbonate export. We posit that eccentricity pacing of phytoplankton evolution contributed to the strong 405,000-year cyclicity that is seen in global carbon cycle records.",
url = "https://pmc.ncbi.nlm.nih.gov/articles/6748936/",
doi = "10.1038/s41586-021-04195-7",
pmcid = "6748936",
pmid = "34853471"
}