城市绿色空间地表温度的时空演变特征——以北京市六环内区域为例

doi:10.12302/j.issn.1000-2006.202112008

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南京林业大学学报（自然科学版） ›› 2023, Vol. 47 ›› Issue (5): 197-204.doi: 10.12302/j.issn.1000-2006.202112008

城市绿色空间地表温度的时空演变特征——以北京市六环内区域为例

樊柏青¹^,²(), 刘东云¹^,^*(), 王思远², 穆罕默德·阿米尔·西迪基³

1.北京林业大学园林学院,北京 100083
2.东南大学建筑学院,江苏南京 210096
3.天津大学建筑学院,天津 300272

收稿日期:2021-12-06 修回日期:2022-04-26 出版日期:2023-09-30 发布日期:2023-10-10
作者简介:樊柏青(boqing0608@163.com)。
基金资助:
国家重点研发计划(2022YFC3802602)

Spatio-temporal evolution of surface temperature in urban green space: a case study within the Sixth Ring Road in Beijing

FAN Boqing¹^,²(), LIU Dongyun¹^,^*(), WANG Siyuan², Muhammad·Amir·Siddique ³

1. College of Landscape Architecture, Beijing Forestry University, Beijing 100083, China
2. School of Architecture, Southeast University, Nanjing 210096, China
3. School of Architecture, Tianjin University, Tianjin 300272, China

Received:2021-12-06 Revised:2022-04-26 Online:2023-09-30 Published:2023-10-10

摘要/Abstract

摘要：

【目的】随着城市化进程的不断推进,城市热岛效应逐渐加剧,地表温度作为表征城市热环境的常用因子,研究其与城市绿色空间之间的关系对于缓解城市热岛效应有着重要的参考价值。【方法】利用1999、2005、2011、2017年每间隔6 a的北京市4期Landsat5 TM和Landsat8 OLI遥感影像数据,对北京市六环内区域进行遥感解译,并单独提取绿色空间的地表温度,分析其时空演变特征。【结果】北京市六环内区域不同的城市绿色空间降温效益有所差异,但其归一化地表温度多分布于低温至中温之间,耕地、林地、水域、草地的归一化地表温度依次升高;1999—2017年,北京城区绿色空间总共转出(减少)227.09 km²;在绿色空间不变、交换、增加、损失4类用地转换类型中,仅绿色空间增加区域的地表温度有所下降,其余地表温度均表现出不同程度的升高。【结论】在北京市“留白增绿”等政策的引导下,可通过增加绿地面积并合理优化其布局与结构、保护永久基本农田区域、转换草地为其他绿色空间类型等方式缓解城市热岛效应,创造更加适宜的人居环境。

关键词: 城市热岛, 地表温度, 绿色空间, 土地利用, 时空演变, 北京市

Abstract:

【Objective】As urbanization progresses, the urban heat island effect intensifies gradually. Studying the relationship between surface temperature and urban green spaces is important for mitigating the urban heat island effect, as it is a common factor in characterizing the urban thermal environment. However, there are few quantitative studies on the spatial and temporal variations of surface temperature in green spaces alone, and there is a lack of quantitative analyses of the four main types of surface temperature variation (constant, conversion, increase and loss) in different types of urban green spaces at a macroscopic scale. 【Method】 We used four phases of Landsat5 TM and Landsat8 OLI remote sensing image data from Beijing every six years between 1999, 2005, 2011 and 2017. We inverted the surface temperature of the area within the Sixth Ring Road of Beijing and simultaneously performed a remote sensing interpretation at the same time. We then separately extracted the surface temperature of the green space to analyze its spatial and temporal evolution characteristics. 【Result】 Calculating the normalized surface temperature values within the Sixth Ring in 1999, 2005, 2011 and 2017 revealed some differences in surface temperatures in different substrata. For example, the surface temperature of arable land is generally located in the urban fringe area and is less affected by urban construction and anthropogenic heat. Therefore, its surface temperature is lower than that of the green spaces in central urban areas. We observed some cooling characteristics in the green spaces, whereas the remaining substrates showed warming characteristics. The different components of the substratum were one of the main reasons for differences in urban surface temperatures. The spatial distribution of green spaces within the Sixth Ring Road changed to some extent from 1999 to 2017. The overall transfer of green space was 227.09 km². Except for grassland, the other three types of green space tended to be transferred, and the highest proportion was transferred to impermeable surfaces. This continuous urban expansion and construction has led to changes in the composition of the urban substrates, resulting in increased surface temperature and intensification of the urban heat island phenomenon. The spatial and temporal evolution of green space leads to changes in surface temperature. An increase in green space leads to a decrease in surface temperature, whereas the exchanged, lost, and unchanged parts of green space show different degrees of warming. The loss of green space contributed more to the increase in the normalized surface temperature than the exchange of green space. For green space exchange, except for the conversion of grassland to other types of green space, which had a cooling effect, the remaining conversion types showed some warming effects. 【Conclusion】 To mitigate the urban heat island effect and create a more suitable living environment, increasing the area of green space, reasonably optimizing its layout and structure, protecting areas of permanent basic agricultural land, and converting grassland into other types of green space under the guidance of Beijing’s policy of “Leaving white space and increasing green space” is necessary. In the future, monitoring the urban thermal environment at different micro levels can be further combined to form a multi-scale and multi-dimensional surface temperature research mechanism, increase the level of surface temperature research, and provide a more diversified basis for subsequent research alongside macro-scale research on surface temperatures in urban construction areas.

Key words: urban heat island, land surface temperature, green space, land use, spatio-temporal evolution, Beijing City

中图分类号:

X835
TU985

樊柏青,刘东云,王思远,等. 城市绿色空间地表温度的时空演变特征——以北京市六环内区域为例[J]. 南京林业大学学报（自然科学版）, 2023, 47(5): 197-204.

FAN Boqing, LIU Dongyun, WANG Siyuan, Muhammad·Amir·Siddique . Spatio-temporal evolution of surface temperature in urban green space: a case study within the Sixth Ring Road in Beijing[J].Journal of Nanjing Forestry University (Natural Science Edition), 2023, 47(5): 197-204.DOI: 10.12302/j.issn.1000-2006.202112008.

图/表 8

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表1

表2

图2

表3

图3

图4

表4

1999—2017年北京六环内区域绿色空间转换及地表温度变化"

空间变化 space change	用地转换类型 land conversion type	△T_nLS	面积/ km² area	空间变化 space change	用地转换类型 land conversion type	△T_nLS	面积/ km² area
交换 exchange	林地→草地forest land to meadow	0.079	41.73	损失 loss	耕地→裸地arable land to bare ground	0.153	16.79
	林地→耕地 forest land to arable land	0.069	35.07		水域→休耕耕地waters to fallow land	0.172	0.08
	林地→水域forest land to water area	0.038	7.43		水域→不透水面water area to impervious surface	0.149	30.83
	草地→林地grassland to forest land	-0.012	20.35		水域→裸地water area to bare ground	0.148	2.55
	草地→耕地grassland to arable land	-0.016	9.52	增加 increase	休耕耕地→林地fallow land to woodland	-0.191	32.71
	草地→水域grassland to waters	-0.015	0.82		休耕耕地→草地fallow land to grassland	-0.190	17.76
	耕地→林地arable land to forest land	0.084	69.48		休耕耕地→耕地fallow land to arable land	-0.186	21.74
	耕地→草地arable land to grassland	0.094	34.22		休耕耕地→水域fallow land to water area	-0.200	1.21
	耕地→水域arable land to water area	0.083	3.85		不透水面→林地impervious surface to forest land	-0.059	99.18
	水域→林地water area to forest land	0.091	10.70		不透水面→草地impervious surface to grassland	-0.089	39.24
	水域→草地water area to grassland	0.097	4.97		不透水面→耕地impervious surface to arable land	-0.072	23.17
	水域→耕地water area to arable land	0.112	4.67		不透水面→水域impervious surface to water area	-0.113	10.21
	林地→休耕耕地conversion of forest land to fallow land	0.184	1.29		裸地→林地bare ground to forest land	-0.162	7.46
	林地→不透水面forest land to impervious surface	0.160	230.59		裸地→草地bare ground to grassland	-0.124	6.58
	林地→裸地forest land to bare ground	0.143	15.70		裸地→耕地bare ground to arable land	-0.135	2.56
	草地→休耕耕地grassland to fallow land	0.075	0.43		裸地→水域bare ground to water area	-0.247	1.78
损失 loss	草地→不透水面grassland to impervious surface	0.107	39.11	不变 unchanged	林地不变forest land	0.065	203.63
	草地→裸地grassland to bare ground	0.084	3.66		草地不变grassland	0.009	9.49
	耕地→休耕耕地arable land to fallow land	0.147	3.97		耕地不变arable land	0.08	50.61
	耕地→不透水面arable land to impervious surface	0.195	149.52		水域不变water area	0.038	16.31

表4

参考文献 21

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站点编号 No.	日期 data	地表气温/℃ land surface temperature
站点编号 No.	日期 data	平均 mean	最高 max	反演值 inversion value
54511	1999-07-25	39.6	63.2	42.01
54511	2005-07-09	35.3	62.5	40.08
54511	2011-07-26	30.2	41.1	38.42
54511	2017-07-10	30.0	42.8	39.73

年份 year	林地 forest land	草地 grassland	耕地 cultivated land	休耕耕地 fallow land	水域 water area	不透水面 impervious surface	裸地 bare ground
1999	0.287	0.352	0.260	0.520	0.289	0.502	0.528
2005	0.290	0.326	0.259	0.476	0.304	0.486	0.513
2011	0.328	0.339	0.315	0.374	0.302	0.458	0.413
2017	0.350	0.367	0.337	0.461	0.314	0.504	0.434
平均值mean	0.314	0.346	0.292	0.458	0.302	0.487	0.472

年份 year	特低温 extra-low temperature	低温 low temperature	较低温 relatively low temperature	中温 medium temperature	较高温 relatively high temperature	高温 high temperature	特高温 extra-high temperature
1999	16.45	41.29	34.88	6.59	0.66	0.11	0.01
2005	8.16	39.50	37.56	14.27	0.49	0.01	0
2011	1.33	45.55	44.48	8.25	0.38	0.01	0
2017	1.79	39.88	40.49	15.93	1.87	0.04	0

城市绿色空间地表温度的时空演变特征——以北京市六环内区域为例

Spatio-temporal evolution of surface temperature in urban green space: a case study within the Sixth Ring Road in Beijing

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