Periodic climate change and human adaptation

doi:10.16359/j.1000-3193/AAS.2022.0029

Abstract

Abstract:

Since ancient times, climate change, especially periodic oscillation, has profoundly affected the transformation and development of human society. Periodic climate change left its imprints in the origins and migration of humans in the Paleolithic Age, the evolution of culture and civilization in the Neolithic Age, the rise and fall of dynasties in historical periods, the socio-economic turmoils in the era of industrialization, and all other anthropological issues. On the basis of new evidence and progresses in paleoclimatology, paleoanthropology, and environmental archaeology in recent years, this paper examines climatic characteristics at various development stages and key nodes of human society from the perspective of periodic climate change. Using typical study cases, it introduces and analyzes the complex interaction between periodic climate change and human activities at different temporal and spatial scales in the Paleolithic, Neolithic and historical periods, involving the link of periodic climate change to human evolution and migration during the Paleolithic Age, the association of periodic climate change with cultural succession as well as the origin and development of agriculture during the Neolithic Age, complex relationship between periodic climate change and human activities since the historical period, and new viewpoints on the mechanisms of periodic climate change and human social adaptability; it also discusses the similarities and differences between natural and social sciences in understanding the mechanisms underlying the relationship of climate change to human activities, and expounds a new paradigm to study of the relationship between climate change and human activities under the background of interdisciplinary research.

This new research paradigm involves progresses and breakthroughs in theories, methods, technologies, and applications of climate change and social-cultural development. The following aspects thus must be considered in future studies: 1) transforming the traditional and scattered evidence of qualitative description into continuous temporal-spatial sequences of quantitative parameters (e,g., rate of change, speed, amplitude, threshold) and, and taking into account the multi-source, multi-scale, high-dimensional and complex spatio-temporal dependence of data; 2) merging the case study into the statistical test of big data, and distinguishing the climate-culture phenomena and nodes associated with periodic changes and event superpositions at different time scales through statistical methods such as Bayesian probability and probability inference; 3) carrying out systematical studies on the representative signs of cultures and their quantitative methods in different scenes of history and prehistoric periods, and establishing linear-nonlinear relationships models among human activities, cultural changes, and variations of temperature, precipitation and ecological environment; and 4) having a clear understanding that the studies of paleoclimate changes are providing evidence of multi-layered interaction for the study of earth system science together with the studies of archaeological culture instead of just serving for interpreting past human activities.

Key words: climate change, periodically, human activities, cultural succession, Interdisciplinarity, human-environment interaction

CLC Number:

P532
Q981

LYU Houyuan. Periodic climate change and human adaptation[J]. Acta Anthropologica Sinica, 2022, 41(04): 731-748.

Figures/Tables 5

Fig.1 Synchronous changes of Holocene 500 year periodic climate and human activities in Northeast Asia（by [29]）

Fig.2 Possible mechanism of climate cycle superposition driving the origin of agriculture in East Asia[15,16,75-78,83]

Fig.3 Temperature changes since 5350 years ago revealed by annual stratigraphy pollen analysis in Xiaolongwan Lake, Eastern China indicating a warming process in the last 100 years, which is located in the warming phase of the 500-year natural cycle. a. spectrum analysis results; b. Climate change curve (by [103])

Fig.4 Panarchy connections, linked adaptive cycles at multiple scales[23] Originally published in Panarchy: Understanding transformations in human and natural systems, Edited by Lance H. Gunderson and C.S. Holling 2002. Permission Island Press[23]）. r, K, Ω and α Explanation: r stage (growth), the connectivity and stability of the system increase in r stage, and begin to accumulate natural resources and social capital; K-stage (accumulation), the resources gathered in stage K are increasingly fixed by the system, and the control force becomes increasingly stronger with the increase of the connection degree of the system; Ω stage (reorganization) with the over connection and rigid control in K state, the resilience of the system decreases and the accumulation becomes very weak, under insignificant interference, it will lead to great crisis and transformation of the system; α stage (update) system is reorganized, and the process is highly uncertain, it is possible to repeat the previous cycle or enter a new and different cycle.

Fig.5 The adaptive cycle model used to analyze the role of climate in the macro-economic and dynastic cycles in China over the past 2000 a[22] From top to bottom: 1) α, r, K, and Ω represent four phases of the adaptive cycle, respectively[23]; here, they also refer to the dynasties identified in the second row of the figure; 2) the colored bar indicates centennial-scale warm/cold periods in China[18]; 3) the phase of each major dynasty in the adaptive cycle; 4) the phase of Emperor in each dynasty in the adaptive cycle; the eight loops represent eight long dynasties: the Western Han(W. Han, 206 BC-AD 25), Eastern Han(E. Han, AD 25-220); Tang(AD 618-907); Northern Song(N. Song, AD 960-1127); Southern Song(S. Song, AD 1127-1279); Yuan(AD 1234-1368); Ming(AD 1368-1644); and Qing(AD 1644-1911)

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