气候变化背景下我国天麻种植适宜性和适宜区的评估

doi:10.3724/SP.J.1006.2024.34098

摘要/Abstract

摘要：

气候变化通过改变物种栖息地的适宜性来影响物种的生长区域。天麻作为中国珍稀濒危药用植物, 评估其种植适宜区分布以及气候变化对天麻种植适宜性的影响可以为天麻生产布局提供重要依据。本研究采用MaxEnt模型, 基于我国天麻地理分布数据和环境数据, 模拟天麻种植适宜性和适宜区的空间分布和变化。结果表明, 影响天麻分布的主要环境因子是5月至7月太阳辐射量、10月至11月降水量、最冷月最低温和植被类型。我国天麻种植高适宜区主要分布在四川盆地周围的西南地区。1961—2020年, 天麻种植适宜性呈波动增加趋势, 种植适宜性提高的面积占全国陆地面积的9.10%, 主要分布在西南地区、华中、华东的部分地区以及陕西省。过去60年间5月至7月太阳辐射量总体上的下降是天麻种植适宜性提高的主要原因。本研究通过对天麻种植适宜性准确评估和种植适宜区变化因子解析, 为我国天麻生产与人工栽培选址提供科学依据, 对制定应对未来气候变化的对策具有借鉴意义。

关键词: 天麻, 种植适宜性, 环境因子, MaxEnt, ArcGIS

Abstract:

Climate change affects species growth areas by altering the suitability of their habitats. As a rare and endangered medical plant in China, the evaluation of the suitable distribution area and the impact of climate change on the suitability of Gastrodia elata can provide important information for the production layout of Gastrodia elata. In this study, the MaxEnt model was used to simulate the spatial distribution and changes of the suitability and suitable area for Gastrodia elata cultivation from 1961 to 2020, based on geographic distribution and environmental data. Results showed that the main environmental factors affecting the distribution of Gastrodia elata were solar radiation from May to July, precipitation in October and November, the minimum temperature in the coldest month, and vegetation type. The high suitable areas for Gastrodia elata cultivation in China were mainly distributed in the southwestern region around the Sichuan Basin. 1961 to 2020, the suitability for Gastrodia elata cultivation had shown a fluctuating increasing trend, with the area of improved suitability accounting for 9.10% of the total land area of China, mainly concentrated in Southwest China, the parts of central and eastern China, and Shaanxi province. The overall decrease in solar radiation from May to July over the past 60 years was the main reason for the increased suitability of asparagus cultivation. This study provided a scientific basis for the production and artificial cultivation site selection of Gastrodia elata in China, which provided reference significance for formulating strategies to respond to future climate change.

Key words: Gastrodia elata, planting suitability, environmental factors, MaxEnt model, ArcGIS

郝佳乐, 赵炯超, 赵明宇, 王艺璇, 逯杰, 石晓宇, 高真真, 褚庆全. 气候变化背景下我国天麻种植适宜性和适宜区的评估[J]. 作物学报, 2024, 50(4): 1004-1014.

HAO Jia-Le, ZHAO Jiong-Chao, ZHAO Ming-Yu, WANG Yi-Xuan, LU Jie, SHI Xiao-Yu, GAO Zhen-Zhen, CHU Qing-Quan. Assessment of the cultivation suitability and suitable regions of Gastrodia elata under climate change in China[J]. Acta Agronomica Sinica, 2024, 50(4): 1004-1014.

图/表 8

图1

表1

影响天麻种植分布的潜在环境因子"

潜在环境因子 Potential environmental factor	意义 Meaning	文献 References
5月至7月太阳辐射量(Solar_5to7) Solar radiation from May to July	反映天麻地面生长阶段光照吸收状况 Reflecting the light absorption status of the ground growth stage of Gastrodia elata	[15]
10月至11月降水量(Pre_10to11) Precipitation in October and November	反映天麻关键生育时期水分供应情况 Reflecting water availability during the critical reproductive period of Gastrodia elata	[23,16]
植被类型(VEG) Vegetation	天麻自然分布多需要一定的落叶阔叶林 Natural distribution of Gastrodia elata mostly requires a certain amount of deciduous broadleaf forest	[24]
最冷月最低温(MINtem_CM) Min temperature of coldest month	天麻生长期内承受的最低温度 The minimum temperature to be tolerated during the growth period of Gastrodia elata	[23]
等温性(ISO) Isothermality	天麻生长期内热量平均水平 Average heat level during the growth period of Gastrodia elata	[23]
含粘量(SCS) Soil sediment concentration	反映天麻种植地土壤保水保肥能力 Reflects the soil water and fertility retention capacity of the Gastrodia elata cultivation sites	[25]
降水变异系数(CVpre) Precipitation variability	天麻生长期降水量的季节性差异 Seasonal differences in precipitation during the growing season of Gastrodia elata	[26]
坡度Slope	影响天麻空间分布 Influence on the spatial distribution of Gastrodia elata	[24]
土壤有机碳(SOC) Soil organic carbon	反映天麻种植地土壤质量状况 Reflecting the soil quality of the Gastrodia elata cultivation sites	[27]
坡向(ASPECT) Slope	影响天麻营养吸收状况和产量 Influence nutrient uptake status and yield of absorption conditions of Gastrodia elata	[28]
土壤含水量(SWC) Soil water content	反映天麻种植地土壤水分状况 Reflecting the soil moisture status of the Gastrodia elata cultivation sites	[27]

表1

图2

图3

表2

图4

图5

表3

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分类 Classification	5月至7月太阳辐射量 Solar radiation from May to July (MJ m^-2)	10月至11月降水量 Precipitation in October and November (mm)	最冷月最低温 Minimum temperature of coldest month (℃)	植被类型 Vegetation
高适宜区 High suitable area	1230.14-1598.53	79.58-159.81	-11.17 to -0.68	针叶林, 针阔叶混交林, 阔叶林 Coniferous forests, mixed coniferous, and broad-leaved forests, broad- leaved forests
中适宜区 Moderate suitable area	1598.53-1713.89	72.66-78.20 161.19-209.60	-13.83 to -11.46 -0.53 to -0.09	灌丛, 栽培植被 Scrub and cultivated vegetation
低适宜区 Less suitable area	1713.89-1810.64	67.13-72.66 209.60-238.65	-14.72 to -13.98 0.21 to 1.98	其他 Others
不适宜区 Unsuitable area	<1230.14 or >1810.64	<67.13 or >238.65	< -14.72 or >1.98	荒漠, 草原, 草甸, 沼泽, 高山植被 Deserts, grasslands, meadows, swamps, and alpine vegetation

适宜性划分 Suitability regionalization	年份Years
适宜性划分 Suitability regionalization	1961-1970	1971-1980	1981-1990	1991-2000	2001-2010	2011-2020
低适宜区Less suitable area	61.79	76.84	72.97	87.72	76.15	81.03
中适宜区Moderate suitable area	25.71	33.68	35.81	47.46	41.93	40.51
高适宜区High suitable area	15.09	21.83	24.60	40.63	32.49	26.66
总适宜区Total suitable area	102.59	132.35	133.38	175.81	150.57	148.20
不适宜区Unsuitable area	857.41	827.65	826.62	784.19	809.43	811.80