Product Code Database
Example Keywords: sail -e-readers $25-110
   » » Wiki: Himalayas
Tag Wiki 'Himalayas'.
Tag

Himalayas
Search for himalayas climate
 (

 C O N T E N T S 
Rank: 100%
Bluestar Bluestar Bluestar Bluestar Blackstar
  1. Wiki
  2. Comments
  3. Media

The Himalayas, or Himalaya ( ), is a in Asia, separating the of the Indian subcontinent from the . The range has some of the 's highest peaks, including the highest, . More than 100 peaks exceeding elevations of above lie in the Himalayas.

The Himalayas abut on or cross territories of : , , , , and . The sovereignty of the range in the region is disputed among , , and . The Himalayan range is bordered on the northwest by the and ranges, on the north by the Tibetan Plateau, and on the south by the Indo-Gangetic Plain. Some of the world's major , the , the , and the Tsangpo–Brahmaputra, rise in the vicinity of the Himalayas, and their combined is home to some 600 million people; 53 million people live in the Himalayas.

(2019). 9783030296841, Springer Nature. .
The Himalayas have profoundly shaped the cultures of and . Many Himalayan peaks are sacred in and . The summits of several— (from the Indian side), , , , and in the Tibetan —are off-limits to climbers.

The Himalayas were after the collision of the with the , specifically, by the folding, or -formation of the uppermost Indian crust, even as a lower layer continued to push on into Tibet and add thickness to its plateau; the still lower crust, along with the mantle, however, under Eurasia. The Himalayan mountain range runs west-northwest to east-southeast in an arc long. Its western anchor, , lies just south of the northernmost bend of the Indus river. Its eastern anchor, , lies immediately west of the great bend of the Yarlung Tsangpo River. The Indus-Yarlung suture zone, along which the headwaters of these two rivers flow, separates the Himalayas from the Tibetan plateau; the rivers also separate the Himalayas from the Karakorams, the Hindu Kush, and the Transhimalaya. The range varies in width from in the west to in the east.

Etymology
The name of the range hails from the Himālaya ( 'abode of snow'), from hima ( 'frost/cold') and ālaya ( 'dwelling/house'). They are now known as "", usually shortened to "the Himalayas".

The mountains are known as the Himālaya in and (both written हिमालय), Hinvāl (हिंवाळ) in Garhwali, Himāl (हिमाल) in , the Himalaya (ཧི་མ་ལ་ཡ་) or 'The Land of Snow' (གངས་ཅན་ལྗོངས་) in , also known as Himālaya in (written as හිමාලය), the Himāliya Mountain Range () in , the Himaloẏ Porbōtmala (হিমালয় পর্বতমালা) in , and the Ximalaya Mountain Range (山脉]]) in .

The name of the range is sometimes also given as in older writings, including the Sanskrit epic .

(2025). 9788184752779, . .
Entry: "Himavan" (: हिमवत् ) or Himavan Himavān (: हिमवान्) is a Hindu deity who is the personification of the Himalayan Mountain Range. Other epithets include Himaraja (: हिमराज, ) or Parvateshwara (: पर्वतेश्वर, ).

In western literature, some writers refer to it as the Himalaya the Himalaya, Himalayatra, Feel the Soul of Himalaya. This was also previously transcribed as Himmaleh, as in 's poetry. and Henry David Thoreau's essays..

Geography and key features
The Himalayas consists of four parallel from south to north: the on the south; the Lower Himalayan Range; the , which is the highest and central range; and the Tibetan Himalayas on the north. The are generally considered separate from the Himalayas.

In the middle of the great curve of the Himalayan mountains lie the peaks of and in , separated by the Kali Gandaki Gorge. The gorge splits the Himalayas into Western and Eastern sections, both ecologically and orographically – the pass at the head of the Kali Gandaki, the , is the lowest point on the ridgeline between Everest and K2 (the highest peak of the Karakoram range). To the east of Annapurna are the peaks of and across the border in Tibet, . To the south of these lies , the capital of Nepal and the largest city in the Himalayas. East of the lies the valley of the Bhote/ river which rises in Tibet and provides the main overland route between Nepal and China – the /China National Highway 318. Further east is the with four of the world's six highest mountains, including the highest: , , , and . The region, popular for trekking, is found here on the south-western approaches to Everest. The Arun river drains the northern slopes of these mountains, before turning south and flowing to the range to the east of Makalu.

In the far east of Nepal, the Himalayas rise to the massif on the border with India, the third-highest mountain in the world, the most easterly summit and the highest point of . The eastern side of Kangchenjunga is in the Indian state of . Formerly an independent Kingdom, it lies on the main route from India to , Tibet, which passes over the pass into Tibet. East of Sikkim lies the ancient Buddhist Kingdom of . The highest mountain in Bhutan is , which is also a strong candidate for the highest unclimbed mountain in the world. The Himalayas here are becoming increasingly rugged, with heavily forested steep valleys. The Himalayas continue, turning slightly northeast, through the Indian State of Arunachal Pradesh as well as Tibet, before reaching their easterly conclusion in the peak of , situated in Tibet, inside the great bend of the Yarlang Tsangpo river. On the other side of the Tsangpo, to the east, are the mountains. The high mountains to the north of the Tsangpo, including , however, are also sometimes included in the Himalayas.

Going west from Dhaulagiri, Western Nepal is somewhat remote and lacks major high mountains, but is home to , the largest lake in Nepal. The rises in Tibet but cuts through the centre of the region. Further west, the border with India follows the and provides a trade route into China, where on the Tibetan plateau lies the high peak of . Just across from this lies the sacred in the , which stands close to the source of the four main rivers of Himalayas and is revered in Hinduism, , , Sufism and Bonpo. In , the Himalayas are regionally divided into the and Himalayas with the high peaks of and . The state is also home to the important pilgrimage destinations of Chota Chaar Dhaam, with , the source of the holy river , , the source of the river , and the temples at and .

The next Himalayan Indian state, , is noted for its hill stations, particularly , the summer capital of the , and Dharamsala, the centre of the Tibetan community and government in exile in India. This area marks the start of the and the , the most easterly of the five tributaries of the , cuts through the range here. Further west, the Himalayas form much of the disputed Indian-administered union territory of Jammu and Kashmir where lie the mountainous and the renowned with the town and lakes of . The Himalayas form most of the south-west portion of the disputed Indian-administered union territory of . The twin peaks of are the only mountains over in this part of the Himalayas. Finally, the Himalayas reach their western end in the dramatic 8000 m peak of , which rises over above the Indus valley and is the most westerly of the 8000 m summits. The western end terminates at a magnificent point near Nanga Parbat where the Himalayas intersect with the Karakoram and ranges, in the disputed Pakistani-administered territory of . Some portion of the Himalayas, such as the , , and tract, extend into the Pakistani provinces of Khyber Pakhtunkhwa and Punjab.

Geology
, the recurring physical changes that affect the arrangement of the Earth's crust, and , the movement of large regions of the Earth's crust in the manner of planar rigid bodies, are key to understanding the formation of the Himalayas. The Earth's crust rests directly on its mantle. , comprising the crust and the upper portions of their underlying mantle, are moved around by convection in the . The , found beneath oceans, is, on average, 7 km thick. It is created from magma at and predominantly consists of , the principal igneous rock on Earth. In contrast, the continental crust underlying dry land has an average thickness of 35 km and is rich in , which is less dense than basalt. It makes the continental tectonic plates more buoyant than the oceanic.

India's defining geologic processes, which began 70 million years ago, had involved India rifting, or splitting away, from , and the along with the above it jointly moving northward. As these eventually reached the , the less buoyant oceanic plate , or slid under Eurasia and was carried into the deeper asthenosphere. In contrast, the was obstructed because of its thickness and buoyancy. The lateral compression generated by the obstruction caused the plate to be sheared horizontally. Its lower crust and mantle slid under, but one layer of the upper crust piled up in sheets (called ) ahead of the subduction zone. Geophysicist Peter Molnar noted that most of the Himalayas are "slices of rock that once were the top part of India's crust." This is the process of mountain building, or , in the Himalayas.

Before the orogeny, the Eurasian coastline had been similar to today's Central Andes. Along such coastlines, the adjoining oceanic plate subducts and erupts as volcanoes. , which eventually crystallizes into granite, rises into the Earth's crust below the active volcanoes but not to the surface. When India's continental plate pushed against Eurasia, not only did a part of the upper crust fold in nappes, but another stiffer part began to push against (or drag) Eurasia's ancient volcanic mountains farther north. As a result, the crust of this formerly coastal region shortened under compression and thickened to become what is today the . Isostatic equilibrium, or the balance between the gravitational force pulling down on the crust and the force of buoyancy pushing up from the mantle, gives the Tibetan Plateau its notable thickness and altitude.

The Indian plate was not the only landmass that had rifted from and drifted northward toward Eurasia. Before the India-Eurasia collision in (60 Mya) and subsequent Himalayan orogeny, two other landmasses, the Qiangtang terrane and , had drifted up from Gondwana. Qiangtang, a geological region in what is today northern Tibet, had done so in (237–201 Mya). The Lhasa terrane collided with the southern boundary of the Qiangtang in the (145–100 Mya). The collision caused the lithospheric mantle of the Lhasa terrane to thicken and shorten, forming a barrier that later prevented the Indian lithosphere from fully subducting under Tibet and leading to further thickening of the Tibetan plateau. The suture zones, or remains of the and the that are joined, are found in the Tibetan plateau. The Qiantang and Lhasa terranes were part of the string of microcontinents Cimmeria, today constituting parts of , , , , , and , which had rifted from Gondwana earlier, closing the Paleo-Tethys Ocean above them and opening the Neo-Tethys Ocean between them and Gondwana, eventually colliding with Eurasia, and creating the Cimmerian Orogeny.

After the Lhasa terrane had adjoined Eurasia, an active continental margin opened along its southern flank, below which the Neo-Tethys oceanic plate had begun to subduct. Magmatic activity along this flank produced the Gangdese batholith in what is today the . Another subduction zone opened to the west, in the ocean basin above the Kohistan-Ladakh . This island arc—formed by one oceanic plate subducting beneath another, its magma rising and creating continental crust—drifted north, closed its ocean basin and collided with Eurasia.

The collision of India with Eurasia closed the Neo-Tethys Ocean. The suture zone (in this instance, the remnants of the Neo-Tethys subduction zone pinched between the two continental crusts), which marks India's welding to Eurasia, is called the Indus-Yarlung suture zone. It lies north of the Himalayas. The headwaters of the and the (later in its course, the ) flow along this suture zone. These two Eurasian rivers, whose courses were continually diverted by the rising Himalayas, define the western and eastern limits, respectively, of the Himalayan mountain range.

During the India-Eurasia collision, two elongated protrusions located on either side of the northern border of the Indian continent generated areas of extreme deformation. A point where mountain ranges with different directions of extension, and thus formed by tectonic forces at varying angles, converge is called a ( Greek: convergence). The two syntaxes, and , on the northwestern and northeastern corners of the Indian continent, respectively, are characterized by the quick upward movement of land or rocks that were once deeply buried and significantly altered by extreme heat and pressure. Geologists have estimated the rate of uplift of these rocks to be per year, or per million years. The protruding regions have some of the highest mountain peaks at and , respectively. The regions also have the greatest in the interior of a continent, approximately over a horizontal distance of . Nanga Parbat has a narrow, , or arch-shaped fold whose crest dips sharply to the north, perpendicular to the general direction along which the Himalayas extend. The Indus and Yarlung Tsangpo, which originally emptied into the New-Tethys, now bend around the Nanga Parbat and Namche Barwa, respectively, to eventually empty into the Indian Ocean.

Geologists Wolfgang Frisch, Martin Meschede, and Ronand Blakey write, "India rapidly marched northward towards Asia with a velocity of ca. 20 cm/yr, a plate velocity that exceeds any modern example. This velocity considerably slowed to ca. 5 cm/yr following the collision, yet India continued to protrude into Asia for more than 2000 km. ... The irregular northern margin of the Indian continental crust first came into contact with Eurasia along its northwestern corner, approximately 55 Ma. As a consequence, India underwent a counter-clockwise rotation to close the remaining part of the Neotethys in scissor-like fashion from west to east. The closure of the Neotethys was completed approximately 40 Ma."

Today, the Indian plate continues to be driven horizontally at the Tibetan Plateau, which forces the plateau to continue to move upwards. The Indian plate is moving at per year, and over the next 10 million years, it will travel into Asia. Approximately 20 mm per year of the India-Asia convergence is absorbed by along the Himalaya southern front. This leads to the Himalayas rising by about 5 mm annually, making them geologically active. The movement of the Indian plate into the Asian plate also makes this region active, leading to earthquakes from time to time.

The Himalayan mountain range consists of three sub-ranges: (1) the Higher- or "Tethys" Himalayas, (2) the Lesser Himalayas, and (3) the Siwaliks. The nappes—large, stacked sheets of rock—found in the Tethys Himalayan mountain range, are primarily composed of sedimentary rocks, such as formed from the accumulation and compression of sediments like sand, mud, and shells deposited in the Neo-Tethys seabed during the " (66 Mya–23 Mya). Below the sedimentary rocks in the Higher and Lesser Himalayas is a bottom layer, or basement, composed of formed much earlier during the Pan-African- between 650 Mya and 550 Mya. The lowest subrange, the Siwaliks, represents the sedimentary rock deposits washed off the rising Himalayas in a , a low-lying crustal region, at their foot. It primarily consists of sandstones, shales, and conglomerates formed during the period (23 Mya to 2.6 Mya).

Geologists Wolfgang Frisch, Martin Meschede, and Ronand Blakey further write, "The Siwaliks are both underlain and overlain by thrusts; they have been overridden by the nappe stack of the Higher and Lesser Himalayas and, in turn, are thrust over more interior parts of the Indian continent. Each of the three mega-units is internally imbricated into several individual nappes. Fensters (windows) and klippen provide important structural information regarding the thrust belts and help document the existence of broad thrust sheets, some of which record thrust distances in excess of 100 km. A fenster or window is an erosional hole through a thrust sheet that exposes a tectonically lower unit framed by a higher unit; a klippe is detached by erosion and forms a remnant of a nappe or higher thrust sheet that rests on top of a lower unit."

Hydrology
Despite their scale, the Himalayas do not form a major continental divide, and a number of rivers cut through the range, particularly in the eastern part of the range. As a result, the main ridge of the Himalayas is not clearly defined, and mountain passes are not as significant for traversing the range as with other mountain ranges. Himalayas' rivers drain into two large systems:
  • The western rivers combine into the Indus Basin. The itself forms the northern and western boundaries of the Himalayas. It begins in Tibet, at the confluence of Sengge and Gar rivers, and flows north-west through India into Pakistan before turning south-west to the . It is fed by several major tributaries draining the southern slopes of the Himalayas, including the , , , , and rivers, the five rivers of the Punjab.
  • The other Himalayan rivers drain the Ganges-Brahmaputra Basin. Its main rivers are the , the , and the , as well as other tributaries. The Brahmaputra originates as the Yarlung Tsangpo River in western Tibet, and flows east through Tibet and west through the plains of . The Ganges and the Brahmaputra meet in and drain into the Bay of Bengal through the world's largest river delta, the .

The northern slopes of and the peaks beyond the Tsangpo, sometimes included in the Himalayas, drain into the , which originates in eastern Tibet and flows south through Myanmar to drain into the . The , , , and all originate from parts of the Tibetan Plateau that are geologically distinct from the Himalaya mountains and are therefore not considered true Himalayan rivers. Some geologists refer to all the rivers collectively as the circum-Himalayan rivers.

Glaciers
The great ranges of central Asia, including the Himalayas, contain the third-largest deposit of ice and snow in the world, after and the . Some even refer to this region as the "Third Pole". The Himalayan range encompasses about 15,000 glaciers, which store about , or 3600–4400 (10 kg) of fresh water. Its glaciers include the and () and glaciers ( region), glacier ( region), and ().

Owing to the mountains' latitude near the Tropic of Cancer, the permanent is among the highest in the world, at typically around . In contrast, equatorial mountains in , the , and have a snow line some lower.

(2025). 9780123869173, Elsevier.
The higher regions of the Himalayas are snowbound throughout the year, in spite of their proximity to the tropics, and they form the sources of several large . In recent years, scientists have monitored a notable increase in the rate of glacier retreat across the region as a result of climate change. For example, glacial lakes have been forming rapidly on the surface of debris-covered glaciers in the Bhutan Himalaya during the last few decades. Studies have measured an approximately 13% overall decrease in glacial coverage in the Himalayas over the last 40–50 years. Local conditions play a large role in glacial retreat, however, and glacial loss can vary locally from a few m/yr to 61 m/yr. A marked acceleration in glacial mass loss has also been observed since 1975, from about 5–13 Gt/yr to 16–24 Gt/yr. Although the effect of this will not be known for many years, it potentially could mean disaster for the hundreds of millions of people who rely on the glaciers to feed the rivers during the dry seasons. The global climate change will affect the water resources and livelihoods of the Greater Himalayan region.
(2025). 9780309260985, National Academies Press. .

Lakes
The Himalayan region is dotted with hundreds of lakes. , which is spread across the border between India and China, at the far western end of Tibet, is among the largest with a surface area of .

South of the main range, the lakes are smaller. in Nepal, in the Annapurna massif, is one of the highest lakes in the world. Other lakes include in western Nepal, in the Shey Phoksundo National Park of Nepal, , in , in district of , and , near the Indo-China border in Sikkim.

Some of the lakes present the danger of a glacial lake outburst flood. The glacier lake in the , in the of Nepal, is rated as the most dangerous. The lake, which is located at an altitude of , has grown considerably over the last 50 years due to glacial melting.Tsho Rolpa The mountain lakes are known to geographers as tarns if they are caused by glacial activity. Tarns are found mostly in the upper reaches of the Himalaya, above .

Temperate Himalayan wetlands provide important habitat and layover sites for migratory birds. Many mid and low altitude lakes remain poorly studied in terms of their hydrology and biodiversity, like Khecheopalri in the Sikkim Eastern Himalayas.

Climate
Temperature
The physical factors determining the climate in any location in the Himalayas include latitude, altitude, and the relative motion of the Southwest monsoon. From north to south, the mountains cover more than eight degrees of latitude, spanning temperate to subtropical zones. The colder air of Central Asia is prevented from blowing down into South Asia by the physical configuration of the Himalayas. This causes the tropical zone to extend farther north in South Asia than anywhere else in the world. The evidence is unmistakable in the Brahmaputra valley as the warm air from the Bay of Bengal bottlenecks and rushes up past , the eastern anchor of the Himalayas, and into southeastern Tibet. Temperatures in the Himalayas cool by 2.0 degrees C (3.6 degrees F) for every increase of altitude. As the physical features of mountains are irregular, with broken jagged contours, there can be wide variations in temperature over short distances. Temperature at a location on a mountain depends on the season of the year, the bearing of the sun with respect to the face on which the location lies, and the mass of the mountain, i.e. the amount of in the mountain. As the temperature is directly proportional to received radiation from the sun, the faces that receive more direct sunlight also have a greater heat buildup. In narrow valleys—lying between steep mountain faces—there can be dramatically different weather along their two margins. The side to the north with a mountain above facing south can have an extra month of the growing season. The mass of the mountain also influences the temperature, as it acts as a , in which more heat is absorbed and retained than the surroundings, and therefore influences the or the amount of heat needed to raise the temperature from the winter minimum to the summer maximum.

The immense scale of the Himalayas means that many summits can create their own weather, the temperature fluctuating from one summit to another, from one face to another, and all may be quite different from the weather in nearby plateaus or valleys.

Precipitation
The Himalayan hydroclimate is crucial for South Asia, where annual summer monsoon floods impact millions.

A critical influence on the Himalayan climate is the Southwest Monsoon. Variability in monsoon rainfall, influenced by local Hadley circulation and tropical sea surface temperatures, is the main factor behind wet and dry years. This is not so much the rain of the summer months as the wind that carries the rain. Different rates of heating and cooling between the Central Asian continent and the create large differences in the atmospheric pressure prevailing above each. In the winter, a high-pressure system forms and remains suspended above Central Asia, forcing air to flow in the southerly direction over the Himalayas. But in Central Asia, as there is no substantial source for water to be diffused as vapour, the winter winds blowing across South Asia are dry. In the summer months, the Central Asian plateau heats up more than the ocean waters to its south. As a result, the air above it rises higher and higher, creating a . Off-shore high-pressure systems in the Indian Ocean push the moist summer air inland toward the low-pressure system. When the moist air meets mountains, it rises and upon subsequent cooling, its moisture condenses and is released as rain, typically heavy rain. The wet summer monsoon winds cause precipitation in India and all along the layered southern slopes of the Himalayas. This forced lifting of air is called the orographic effect.

Winds
The vast size, huge altitude range, and complex topography of the Himalayas mean they experience a wide range of climates, from humid subtropical in the foothills, to cold and dry desert conditions on the Tibetan side of the range. For much of the Himalayas—in the areas to the south of the high mountains, the is the most characteristic feature of the climate and causes most of the precipitation, while the western disturbance brings winter precipitation, especially in the west. Heavy rain arrives on the southwest monsoon in June and persists until September. The monsoon can seriously impact transport and cause major landslides. It restricts tourism – the trekking and mountaineering season is limited to either before the monsoon in April/May or after the monsoon in October/November (autumn). In Nepal and Sikkim, there are often considered to be five seasons: summer, , autumn, (or post-monsoon), winter, and spring.

Using the Köppen climate classification, the lower elevations of the Himalayas, reaching in mid-elevations in central Nepal (including the Kathmandu valley), are classified as Cwa, Humid subtropical climate with dry winters. Higher up, most of the Himalayas have a subtropical highland climate ( Cwb).

The intensity of the southwest monsoon diminishes as it moves westward along the range, with as much as of rainfall in the monsoon season in in the east, compared to only during the same period in Shimla in the west.

The northern side of the Himalayas, also known as the Tibetan Himalaya, is dry, cold, and generally windswept, particularly in the west where it has a cold desert climate. The vegetation is sparse and stunted and the winters are severely cold. Most of the precipitation in the region is in the form of snow during the late winter and spring months.

Local impacts on climate are significant throughout the Himalayas. Temperatures fall by 0.2 to 1.2 °C for every rise in altitude. This gives rise to a variety of climates, from a nearly tropical climate in the foothills, to and permanent snow and ice at higher elevations. Local climate is also affected by the topography: The leeward side of the mountains receive less rain while the well-exposed slopes get heavy rainfall and the of large mountains can be significant, for example, leading to near desert conditions in the , which is sheltered from the monsoon rains by the and massifs and has annual precipitation of around , while on the southern side of the massifs has substantial rainfall ( a year). Thus, although annual precipitation is generally higher in the east than in the west, local variations are often more important.

The Himalayas have a profound effect on the climate of the Indian subcontinent and the Tibetan Plateau. They prevent frigid, dry winds from blowing south into the subcontinent, which keeps South Asia much warmer than corresponding regions in the other continents. It also forms a barrier for the monsoon winds, keeping them from traveling northwards, and causing heavy rainfall in the region. The of Himalayas are also believed to play an important part in the formation of Central Asian deserts, such as the and .

Ecology
The flora and fauna of the Himalayas vary with climate, rainfall, altitude, and soils. The climate ranges from tropical at the base of the mountains to permanent ice and snow at the highest elevations. The amount of yearly rainfall increases from west to east along the southern front of the range. This diversity of altitude, rainfall, and soil conditions, combined with the very high snow line, supports a variety of distinct plant and animal communities. The extremes of high altitude (low atmospheric pressure), combined with extreme cold, favor organisms.

At high altitudes, the elusive and previously endangered is the main predator. Its prey includes members of the goat family grazing on the alpine pastures and living on the rocky terrain, notably the endemic or Himalayan blue sheep. The Himalayan musk deer is also found at high altitudes. Hunted for its musk, it is now rare and endangered. Other endemic or near-endemic herbivores include the , the , the , and the . The critically endangered Himalayan subspecies of the is found sporadically across the range, as is the Asian black bear. In the mountainous mixed deciduous and conifer forests of the eastern Himalayas, feed in the dense understories of bamboo. Lower down, the forests of the foothills are inhabited by several different primates, including the endangered Gee's golden langur and the Kashmir gray langur, with highly restricted ranges in the east and west of the Himalayas, respectively.

The unique floral and faunal wealth of the Himalayas is undergoing structural and compositional changes due to . is an example of floral species that can be found in this area. The increase in temperature is shifting various species to higher elevations. The oak forest is being invaded by pine forests in the Garhwal Himalayan region. There are reports of early flowering and fruiting in some tree species, especially , apple, and . The highest known tree species in the Himalayas is Juniperus tibetica, located at in Southeastern Tibet.

Climate-related concerns
Similar to the mountains, the communities living near the Himalayas are experiencing climate change and its negative impacts significantly more than other parts of the world. Some of the impacts that the communities are facing include erratic rainfall, flooding, rising temperatures, and landslides. These impacts can have extreme negative effects on the villages living in the area especially as the temperatures rise at higher rates than many other places in the world (Alexander et al., 2014). There are more than 1.9 million people who are highly vulnerable due to climate change with an additional 10 million people at risk in Nepal. Nepal is among the top ten most vulnerable Global South countries due to climate change in the world, standing at number 4 as of 2010 according to the climate change risk atlas. According to NAPA (National Adaptation Program of Action) of Nepal, many threats including floods, droughts, and landslides are an imminent threat to the glacial lake area. With this in consideration, climate change policy and framework for LAPA (Local Adaptation Plans of Action) were prepared in 2011 primarily focusing on addressing climatic hazards.

Health impacts
Local communities are suffering from food scarcity and malnutrition as well as an increasing risk to diseases such as malaria and dengue fever as temperatures rise and allow these diseases to migrate further north. There is also an increasing risk of water borne illnesses accompanied by an increasing lack of safe drinking water. Illness is not the only danger to the communities as temperatures sky rocket. With the climate changing weather patterns are also changing and more extreme weather events are occurring putting local communities more at risk to physical harm and death during erratic weather events. Marginalized groups including children and women are experiencing more severe impacts from climate change and are often more exposed to disease and injury. Over the last couple years these health impacts have gotten increasingly worse and more common. Recent studies have shown that dengue fever has had a consistent pattern of epidemic in Nepal in the years 2010, 2013, 2016, 2017, 2019, 2022 with the largest in terms of severity occurring in 2022. 54,784 reported cases were recorded from all 77 districts in seven provinces. These diseases are simply in addition to other diseases that can be seen with the rise of global temperatures and air pollution. Many vulnerable groups are experiencing an increase in respiratory illness, cardiac illnesses, and asthma. The heat can lead to issues such as a strain on respiratory illnesses, heat stroke, and fever. There is also the increased risk of cancer. Many lower income communities such as the himalayan villages suffer from exposure to more pollution or in some cases exposure to toxic chemicals which has led to an increased rate of cancer in these communities as well as an increased risk of death.

Agricultural impacts
The increasing temperatures are also leading to a decrease in territory for local wildlife. This trend has decreased the prey populations of at-risk predators, such as snow leopards. Seeking alternative food sources, snow leopards and other predators attack local farmers' livestock. This livestock consists of yaks, oxen, horses, and goats. Snow leopards have killed about 2.6% of the local livestock per year in response to their shrinking habitat. The overall loss, about a quarter of the average income of local farmers, has had a major impact on the local economy. In retaliation, farmers have begun killing snow leopards, seeking to protect their livestock and their livelihoods.

Policy changes
Nepal is a part of the Paris agreement and thus is required to have a climate action plan and is being tracked by the Climate Action Tracker. According to the Climate Action Tracker, Nepal is "almost sufficient" on its track to reach the goals set by the Paris Agreement. There are two factors that hold Nepal back from reaching sufficient status and thus stand out. There is no Climate Finance Plan and emissions and temperature rising rate ranking at critically insufficient. Nepal has many goals, however, that are on track with the Paris Agreement. The first of note being a goal of net-zero emissions by 2045. To reach this goal Nepal submitted two separate plans to account for whatever future they experience the first being WAM (with additional measures) and the second being WEM (with existing measures). WEM is based primarily on already existing policies and highlights the energy sector as the main target for CO2 reduction. The WAM scenario introduces a far more ambitious strategy for reducing emissions. In this scenario the focus is primarily on an intervention method and disruption of the energy sector reducing the use of fossil fuels and the incorporation of renewable energy sources. This pathway heavily relies on reducing emissions from energy sources while preserving the carbon-absorbing capacity of the LULUCF (Land Use, Land-Use Change and Forestry) sector. Under this scenario, it is anticipated that net CO2 emissions will remain negative from 2020 to 2030, approach 'zero' between 2035 and 2045, and then revert to negative values by 2050. The goal of this scenario is to accelerate the journey toward achieving carbon neutrality before 2045. These policies along with many more have Nepal on track to stay beneath the 1.5 threshold set by the Paris Agreement.

In May 2025 the representatives of himalayan nations, experts met in for the first "Sagarmatha Sambaad" (Everest Dialog) about stopping climate change and its effects on the region. Minister Deuba remarked "Climate change is a global crisis transcending national boundaries. Nothing less than a global alliance based on and solidarity can hope to make a dent on the existential crisis that climate change brings in its wake". The leader send a message to the conference in which he reminded that glaciers giving water to rivers are metling in a fast and increasing rate and "reduced water flow in river systems such as the , Brahmaputra and threatens not only water but also food production for nearly two billion people across South Asia". The conference issued a "Sagarmatha Call for Action" to protect the region from climate change. One of the proposals is a common for Himalayan nations. criticized the outcomes, saying that the real challenge is to implement the decisions. Also the conference only addressed the issue of glacier melt, while in recent times, climate migration due to lack of rainfall also became a major concern.

Local adaptation
In recent years many citizens of these Himalayan communities have started to notice the extreme effects of climate change by experiencing nature itself. They have noticed a decrease in precipitation especially in lowland districts, fluctuating temperatures during months of the year that are typically cooler, and changes in weather patterns even compared to early 2000s weather. Many local villagers have identified climate change simply through the availability of certain native plants decreasing or shifting seasons. The concept of climate change has now been aligned with the risk of natural disasters and has increased awareness in the local communities. These impacts of climate change have greatly affected agriculture in the area and has forced farmers to change crops and when they plant them. In response to this rather than push for policy change, citizens have begun to adapt to climate change. According to Dhungana, 91.94% of the respondents experienced drought as major climatic hazards then floods at 83.87%, landslides at 70.97%, and forest fires at 67.74%. In response to this citizens have begun adapting and adopting new practices. As a response to drought at the high altitudes, plantations are planting more protective trees, drought resistant plants, and have begun adopting irrigation practices drawing from nearby streams. In response to flooding, farmers have created more basins, dam construction, and small drainage canals.

The response to landslides includes plantation grasses in previously barren areas, Gabion wall construction, avoiding livestock grazing in landslide-prone areas, and a prohibition on tillage in areas at risk of landslides. To fight the increased rate of forest fires, citizens have begun beating the fires with green branches and mud, construction of fire lines, and are raising awareness about the wildfires. Fire lines are lines of varying width built through the leaf litter of a forest floor down to the soil and minerals to prevent a spread of fire past the line. The main reason for these adaptations is to decrease the risk that climate change poses over these marginalized communities while taking advantage of the moment and allowing for a positive change towards a more sustainable or adaptable future. Major barriers to these adaptations include a lack of funds, a lack of knowledge, a lack of technology, a lack of time, and lack of mandatory policy.

Religions
There are many cultural and mythological aspects associated with the Himalayas. In , Mount Ashtapada of the Himalayan mountain range is a sacred place where the first Jain , , attained . It is believed that after Rishabhanatha attained , his son, Bharata, had constructed three stupas and twenty four shrines of the 24 with their idols studded with precious stones over there and named it Sinhnishdha.
(2025). 9788178357232, Gyan Publishing House. .
For the Hindus, the Himalayas are personified as , the king of all mountains and the father of the goddess . The Himalayas are also considered to be the father of the goddess Ganga (the personification of river Ganges).
(2025). 9780500510889, National Geographic Books. .
Two of the most sacred places of pilgrimage for the Hindus are the temple complex in Pashupatinath and , also known as Shaligrama because of the presence of the sacred black rocks called .

The also lay a great deal of importance on the Himalayas. Paro Taktsang is the holy place where started in . The Muktinath is also a place of pilgrimage for the Tibetan Buddhists. They believe that the trees in the poplar grove came from the walking sticks of eighty-four ancient Indian Buddhist magicians or mahasiddhas. They consider the saligrams to be representatives of the Tibetan serpent deity known as Gawo Jagpa. The Himalayan people's diversity shows in many different ways. It shows through their architecture, their languages, and dialects, their beliefs and rituals, as well as their clothing. The shapes and materials of the people's homes reflect their practical needs and beliefs. Another example of the diversity amongst the Himalayan peoples is that handwoven textiles display colors and patterns unique to their ethnic backgrounds. Finally, some people place great importance on jewelry. The Rai and Limbu women wear big gold earrings and nose rings to show their wealth through their jewelry. Several places in the Himalayas are of religious significance in, , , , and . A notable example of a religious site is , where is said to have founded in .

(2025). 9789622178106, Odyssey Books and Guides.

A number of sites are situated in the Himalayas, in , , and in the Indian regions of , Sikkim, Arunachal Pradesh, , and . There were over 6,000 monasteries in Tibet, including the residence of the . , , and are also dotted with numerous monasteries.

Resources
The Himalayas are home to a diversity of medicinal resources. Plants from the forests have been used for millennia to treat conditions ranging from simple coughs to snake bites. Different parts of the plants – root, flower, stem, leaves, and bark – are used as remedies for different ailments. For example, a bark extract from an tree is used to treat coughs and bronchitis. Leaf and stem paste from an is used for wounds and as an antidote for snake bites. The bark of a is used for skin ailments. Nearly a fifth of the , , and in the Himalayas are found to have medicinal properties, and more are likely to be discovered.

Most of the population in some Asian and African countries depends on medicinal plants rather than prescriptions and such.

(2025). 9788132219255, Springer Briefs in Environmental Science.
Since so many people use medicinal plants as their only source of healing in the Himalayas, the plants are an important source of income. This contributes to economic and modern industrial development both inside and outside the region. The only problem is that locals are rapidly clearing the forests on the Himalayas for wood, often illegally.

See also
  • and
  • Indian Himalayan Region
  • List of Himalayan peaks and passes
  • List of Himalayan topics
  • List of mountains in India, Pakistan, Bhutan, Nepal and China
  • List of Ultras of the Himalayas

Notes
Sources
General
Geography
Geology

Climate
Ecology
Society
Pilgrimage and Tourism
Mountaineering and Trekking
Further reading
  • Aitken, Bill, Footloose in the Himalaya, Delhi, Permanent Black, 2003. .
  • Berreman, Gerald Duane, Hindus of the Himalayas: Ethnography and Change, 2nd rev. ed., Delhi, Oxford University Press, 1997.
  • Edmundson, Henry, Tales from the Himalaya, Vajra Books, Kathmandu, 2019. .
  • Everest, the IMAX movie (1998). .
  • Fisher, James F., Sherpas: Reflections on Change in Himalayan Nepal, 1990. Berkeley, University of California Press, 1990. .
  • Gansser, Augusto, , Olschak, Blanche C., Himalayas. Growing Mountains, Living Myths, Migrating Peoples, New York, Oxford: Facts On File, 1987. and New Delhi: Bookwise, 1987.
  • Gupta, Raj Kumar, Bibliography of the Himalayas, Gurgaon, Indian Documentation Service, 1981.
  • Hunt, John, Ascent of Everest, London, Hodder & Stoughton, 1956. .
  • and Weaver, Stewart, Fallen Giants: The History of Himalayan Mountaineering from the Age of Empire to the Age of Extremes. Yale University Press, 2008. .
  • Ives, Jack D. and Messerli, Bruno, The Himalayan Dilemma: Reconciling Development and Conservation. London / New York, Routledge, 1989. .
  • Lall, J.S. (ed.) in association with Moddie, A.D., The Himalaya, Aspects of Change. Delhi, Oxford University Press, 1981. .
  • Nandy, S.N., Dhyani, P.P. and Samal, P.K., Resource Information Database of the Indian Himalaya, Almora, GBPIHED, 2006.
  • Swami Sundaranand, Himalaya: Through the Lens of a Sadhu. Published by Tapovan Kuti Prakashan (2001). .
  • Swami , Wanderings in the Himalayas, English Edition, Madras, Chinmaya Publication Trust, 1960. Translated by T.N. Kesava Pillai.
  • , Mount Everest, 1938, Cambridge University Press, 1948.
  • Turner, Bethan, et al. Seismicity of the Earth 1900–2010: Himalaya and Vicinity. Denver, United States Geological Survey, 2013.

External links

: , , , , , , , , , , ,
Page 1 of 1
1
Page 1 of 1
1

Account

Social:
Pages:  ..   .. 
Items:  .. 
Click to view the UPC Scavenger App on google play.

Navigation

General: Atom Feed Atom Feed  .. 
Help:  ..   .. 
Category:  ..   .. 
Media:  ..   .. 
Posts:  ..   ..   .. 

Statistics

Page:  .. 
Summary:  .. 
1 Tags
10/10 Page Rank
5 Page Refs
8s Time