Today the desert margins of northwest India are dry and unable to support large populations, but were densely occupied by the populations of the Indus Civilization during the middle to late Holocene. The hydroclimatic conditions under which Indus urbanization took place, which was marked by a period of expanded settlement into the Thar Desert margins, remains poorly understood. We measured the isotopic values (δ18O and δD) of gypsum hydration water in paleolake Karsandi sediments in northern Rajasthan to infer past changes in lake hydrology, which is sensitive to changing amounts of precipitation and evaporation. Our record reveals that relatively wet conditions prevailed at the northern edge of Rajasthan from ~5.1 ± 0.2 ka BP, during the beginning of the agricultural-based Early Harappan phase of the Indus Civilization. Monsoon rainfall intensified further between 5.0 and 4.4 ka BP, during the period when Indus urban centres developed in the western Thar Desert margin and on the plains of Haryana to its north. Drier conditions set in sometime after 4.4 ka BP, and by ~3.9 ka BP an eastward shift of populations had occurred. Our findings provide evidence that climate change was associated with both the expansion and contraction of Indus urbanism along the desert margin in northwest India.
Abstract. The plains of northwest South Asia receive rainfall during both the Indian
summer (June–September) and winter (December–March) monsoon. Researchers
have long attempted to deconstruct the influence of these precipitation
regimes in paleoclimate records, in order to better understand regional
climatic drivers and their potential impact on human populations. The
mid–late Holocene transition between 5.3 and 3.3 ka is of particular
interest in this region because it spans the period of the Indus Civilization
from its early development, through its urbanization, and onto eventual
transformation into a rural society. An oxygen isotope record of the
surface-dwelling planktonic foraminifer Globigerinoides ruber from
the northeast Arabian Sea provided evidence for an abrupt decrease in
rainfall and reduction in Indus River discharge at 4.2 ka, which the authors
linked to the decline in the urban phase of the Indus Civilization
(Staubwasser et al., 2003). Given the importance of this study, we used the
same core (63KA) to measure the oxygen isotope profiles of two other
foraminifer species at decadal resolution over the interval from 5.4 to
3.0 ka and to replicate a larger size fraction of G. ruber than
measured previously. By selecting both thermocline-dwelling
(Neogloboquadrina dutertrei) and shallow-dwelling
(Globigerinoides sacculifer) species, we provide enhanced detail of
the climatic changes that occurred over this crucial time interval. We found
evidence for a period of increased surface water mixing, which we suggest was
related to a strengthened winter monsoon with a peak intensity over 200 years
from 4.5 to 4.3 ka. The time of greatest change occurred at 4.1 ka when
both the summer and winter monsoon weakened, resulting in a reduction in
rainfall in the Indus region. The earliest phase of the urban Mature Harappan
period coincided with the period of inferred stronger winter monsoon between
4.5 and 4.3 ka, whereas the end of the urbanized phase occurred some time
after the decrease in both the summer and winter monsoon strength by 4.1 ka.
Our findings provide evidence that the initial growth of large Indus urban
centers coincided with increased winter rainfall, whereas the contraction of
urbanism and change in subsistence strategies followed a reduction in
rainfall of both seasons.
The development, floruit and decline of the urban phase of the Indus Civilisation (c.2600/2500-1900 BC) provide an ideal opportunity to investigate social resilience and transformation in relation to a variable climate. The Indus Civilisation extended over most of the Indus River Basin, which includes a mix of diverse environments conditioned, among other factors, by partially overlapping patterns of winter and summer precipitation. These patterns likely changed towards the end of the urban phase (4.2 ka BP event), increasing aridity. The impact of this change appears to have varied at different cities and between urban and rural contexts. We present a simulation approach using agent-based modelling to address the potential diversity of agricultural strategies adopted by Indus settlements in different socio-ecological scenarios in Haryana, NW India. This is an ongoing initiative that consists of creating a modular model, Indus Village, that assesses the implications of trends in cropping strategies for the sustainability of settlements and the resilience of such strategies under different regimes of precipitation. The model aims to simulate rural settlements structured into farming households, with sub-models representing weather and land systems, food economy, demography, and land use. This model building is being carried out as part of the multi-disciplinary TwoRains project. It brings together research on material culture, settlement distribution, food production and consumption, vegetation and paleoenvironmental conditions.
The 4.2-kiloyear event has been described as a global megadrought that transformed multiple Bronze Age complex societies, including the Indus Civilization, located in a sensitive transition zone with a bimodal (summer and winter) rainfall regime. Here we reconstruct changes in summer and winter rainfall from trace elements and oxygen, carbon, and calcium isotopes of a speleothem from Dharamjali Cave in the Himalaya spanning 4.2–3.1 thousand years ago. We find a 230-year period of increased summer and winter drought frequency between 4.2 and 3.97 thousand years ago, with multi-decadal aridity events centered on 4.19, 4.11, and 4.02 thousand years ago. The sub-annually resolved record puts seasonal variability on a human decision-making timescale, and shows that repeated intensely dry periods spanned multiple generations. The record highlights the deficits in winter and summer rainfall during the urban phase of the Indus Civilization, which prompted adaptation through flexible, self-reliant, and drought-resistant agricultural strategies.
The start and end of the urban phase of the Indus civilization (IC; c. 2500 to 1900 BC) are often linked with climate change, specifically regarding trends in the intensity of summer and winter precipitation and its effect on the productivity of local food economies. The Indus Village is a modular agent-based model designed as a heuristic “sandbox” to investigate how IC farmers could cope with diverse and changing environments and how climate change could impact the local and regional food production levels required for maintaining urban centers. The complete model includes dedicated submodels about weather, topography, soil properties, crop dynamics, food storage and exchange, nutrition, demography, and farming decision-making. In this paper, however, we focus on presenting the parts required for generating crop dynamics, including the submodels involved (weather, soil water, land, and crop models) and how they are combined progressively to form two integrated models (land water and land crop models). Furthermore, we describe and discuss the results of six simulation experiments, which highlight the roles of seasonality, topography, and crop diversity in understanding the potential impact of environmental variability, including climate change, in IC food economies. We conclude by discussing a broader consideration of risk and risk mitigation strategies in ancient agriculture and potential implications to the sustainability of the IC urban centres.
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