Meteorological Driving Mechanisms and Predictive Modeling of Alpine Grassland Forage Yield Based on Temporal Grouping

doi:10.11924/j.issn.1000-6850.casb2024-0626

Abstract

Abstract:

To explore the stage-specific regulatory mechanisms of meteorological factors on forage yield in alpine steppe and to provide a scientific basis for grassland resource management and yield forecasting, we used fresh forage yield and concurrent meteorological records from the Batan alpine steppe, Tongde County of Qinghai Province during 2005-2023 to conduct study. Thirteen meteorological time-windows were delimited using the stage-grouping approach. Correlation analysis and multiple linear regression were employed to quantify the impacts of precipitation, mean air temperature, relative humidity, sunshine duration, and wind speed on forage yield and to characterize their stage-specific responses. Fresh forage yield exhibited a weak upward trend, with a climate-tendency rate of 1801.4 kg/hm² decade and a coefficient of variation of 59.3%, indicating high sensitivity to climatic fluctuations. Precipitation was the dominant promoting driver, exerting the strongest positive effect during the peak-growing window (May-August), with Pearson’s r=0.294 (P< 0.05). Relative humidity acted compensatory role in the late season by modulating vapor pressure deficit (VPD), as evidenced by r=0.462 (P<0.01) for May-August. Sunshine duration and wind speed exerted persistent suppressive effects across all stages. Temperature effects were stage-dependent: beneficial in spring but statistically non-significant during summer. The developed yield-forecasting model (adjusted R²=0.934, n=19, P<0.001) incorporated three pivotal variables: precipitation from December of the previous year to August of the current year, mean temperature from May to August, and relative humidity from November of the previous year to August of the current year. Forage yield formation in alpine steppe is water-dominated, with significant multi-factor temporal interactions, reflecting an ecological adaptation strategy of ‘water-heat coupling and stage complementarity’. We recommend developing stage-specific management protocols aligned with phenological phases and focusing on key meteorological variables within critical windows to improve forecasting accuracy.

Key words: alpine steppe, forage yield, meteorological factors, relative humidity, stage-grouping approach, yield forecasting, multiple linear regression, water-heat synergy

YANG Fei, LIU Wenbing, ZHANG Haichun, MA Wenyuan. Meteorological Driving Mechanisms and Predictive Modeling of Alpine Grassland Forage Yield Based on Temporal Grouping[J]. Chinese Agricultural Science Bulletin, 2025, 41(30): 131-136.

Figures/Tables 3

References 33

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组别	时段	组别	时段
Z	全年	Z7	3—8月
Z1	上年9月—当年8月	Z8	4—8月
Z2	上年10月—当年8月	Z9	5—8月
Z3	上年11月—当年8月	Z10	6—8月
Z4	上年12月—当年8月	Z11	7—8月
Z5	1—8月	Z12	8月
Z6	2—8月

组别	时段	组别	时段
Z	全年	Z7	3—8月
Z1	上年9月—当年8月	Z8	4—8月
Z2	上年10月—当年8月	Z9	5—8月
Z3	上年11月—当年8月	Z10	6—8月
Z4	上年12月—当年8月	Z11	7—8月
Z5	1—8月	Z12	8月
Z6	2—8月

项目	牧草鲜草产量/(kg/hm²)
项目	平均气温/℃	降水量/mm	日照时数/h	相对湿度/%	平均风速/(m/s)
Z组	0.037	0.285	-0.246	-0.081	-0.304
Z1组	0.265	0.257	-0.212	0.060	-0.128
Z2组	0.222	0.256	-0.252	0.049	-0.144
Z3组	0.209	0.246	-0.151	0.014	-0.136
Z4组	0.221	0.237	-0.166	0.044	-0.130
Z5组	0.190	0.234	-0.188	0.075	-0.184
Z6组	0.221	0.236	-0.185	0.133	-0.184
Z7组	0.245	0.245	-0.212	0.235	-0.208
Z8组	0.216	0.275	-0.244	0.351	-0.228
Z9组	0.151	0.294	-0.286	0.462^**	-0.182
Z10组	0.179	0.255	-0.151	0.415^*	-0.122
Z11组	0.120	0.137	-0.183	0.416^*	-0.099
Z12组	0.047	0.150	-0.096	0.310	-0.066

项目	牧草鲜草产量/(kg/hm²)
项目	平均气温/℃	降水量/mm	日照时数/h	相对湿度/%	平均风速/(m/s)
Z组	0.037	0.285	-0.246	-0.081	-0.304
Z1组	0.265	0.257	-0.212	0.060	-0.128
Z2组	0.222	0.256	-0.252	0.049	-0.144
Z3组	0.209	0.246	-0.151	0.014	-0.136
Z4组	0.221	0.237	-0.166	0.044	-0.130
Z5组	0.190	0.234	-0.188	0.075	-0.184
Z6组	0.221	0.236	-0.185	0.133	-0.184
Z7组	0.245	0.245	-0.212	0.235	-0.208
Z8组	0.216	0.275	-0.244	0.351	-0.228
Z9组	0.151	0.294	-0.286	0.462^**	-0.182
Z10组	0.179	0.255	-0.151	0.415^*	-0.122
Z11组	0.120	0.137	-0.183	0.416^*	-0.099
Z12组	0.047	0.150	-0.096	0.310	-0.066