新疆地热资源分布、成因及开发利用方向:第三次新疆综合科学考察地热科考成果综述

doi:10.13745/j.esf.sf.2025.10.27

地学前缘 ›› 2026, Vol. 33 ›› Issue (1): 283-295.DOI: 10.13745/j.esf.sf.2025.10.27

新疆地热资源分布、成因及开发利用方向:第三次新疆综合科学考察地热科考成果综述

孔彦龙¹(), 董远卓¹, 叶灿滔², 程远志¹, 乃尉华³, 庞忠和¹, 马伟斌², 张健⁴, 龚宇烈², 李义曼¹, 姜光政⁵, 王迎春⁵, 古丽波斯坦·吐逊江⁶, 田小明², 李棱雪², 师德扬³, 张程凯³, 田逸楠³, 李斌³, 陈锋³, 张磊³, 王珂⁷, 任亚倩¹, 张伟尊¹, 罗冠中¹, 段佳斌¹, 陈娅奎¹, 张小雷¹, 汪集暘¹

1.中国科学院地质与地球物理研究所岩石圈演化与环境演变全国重点实验室, 北京 100029
2.中国科学院广州能源研究所, 广东广州 510640
3.新疆维吾尔自治区地质局水文环境地质调查中心, 新疆乌鲁木齐 830000
4.中国科学院大学地球与行星科学学院, 北京 100049
5.成都理工大学能源学院, 四川成都 610059
6.新疆工程学院矿业工程与地质学院, 新疆乌鲁木齐 830023
7.北京市科学技术研究院新材料与先进制造研究所, 北京 100089

收稿日期:2025-08-12 修回日期:2025-10-20 出版日期:2026-11-25 发布日期:2025-11-10
作者简介:孔彦龙(1987—),男,研究员,博士生导师,主要从事地热地质学研究。E-mail: ylkong@mail.iggcas.ac.cn
基金资助:
第三次新疆综合科学考察项目(2022xjkk1304)

The distribution, genesis and utilization directions of geothermal resources in Xinjiang: A summary of the Third Xinjiang Scientific Expedition Program to geothermal science in Xinjiang

KONG Yanlong¹(), DONG Yuanzhuo¹, YE Cantao², CHENG Yuanzhi¹, NAI Weihua³, PANG Zhonghe¹, MA Weibin², ZHANG Jian⁴, GONG Yulie², LI Yiman¹, JIANG Guangzheng⁵, WANG Yingchun⁵, Gulbostan TURSUN⁶, TIAN Xiaoming², LI Lengxue², SHI Deyang³, ZHANG Chengkai³, TIAN Yinan³, LI Bin³, CHEN Feng³, ZHANG Lei³, WANG Ke⁷, REN Yaqian¹, ZHANG Weizun¹, LUO Guanzhong¹, DUAN Jiabin¹, CHEN Yakui¹, ZHANG Xiaolei¹, WANG Jiyang¹

1. Key Laboratory of Lithospheric and Environmental Coevolution, Institute of Geology and Geophysics, Chinese Academy of Sciences, Beijing 100029, China
2. Guangzhou Institute of Energy Conversion, Chinese Academy of Sciences, Guangzhou 510640, China
3. Hydrogeological and Environmental Survey Center of Xinjiang Uygur Autonomous Region Bureau of Geology, Urumqi 830000, China
4. College of Earth and Planetary Sciences, University of Chinese Academy of Sciences, Beijing 100049, China
5. College of Energy, Chengdu University of Technology, Chengdu 610059, China
6. School of Mining Engineering and Geology, Xinjiang Institute of Engineering, Urumqi 830023, China
7. Institute of New Materials and Advanced Manufacturing, Beijing Academy of Science and Technology, Beijing 100089, China

Received:2025-08-12 Revised:2025-10-20 Online:2026-11-25 Published:2025-11-10

摘要/Abstract

摘要：

基于“冷壳冷幔”的理论认识,新疆一直被认为是地热资源相对贫瘠的地区,其总体勘查和开发利用情况远落后于内地。第三次新疆综合科学考察课题“地热等清洁能源资源综合调查与评价”在收集整理全疆地热已有成果的基础上,重点开展野外补充调查,新发现了地热点位11处,补充确定了地热资源赋存形式2种,估算新疆地热资源量折合超过18亿吨标准煤。调查结果显示,新疆地热资源主要分布于盆间隆起山地,与其主要人口分布保持高度一致,而较少的人口基数决定了新疆人均地热资源量较高,反而说明了其具有较大的开发利用潜力。新疆地热资源表现出“北疆禀赋差,南疆禀赋好”的分布格局:北疆天山、阿勒泰山地区广泛发育以断裂深循环成因的中低温水热型地热资源,而在南疆帕米尔高原,受印度-欧亚板块碰撞的影响,形成了目前新疆唯一发现的高温地热资源。然而,新疆地热资源开发利用整体水平相对较低,开发利用方式单一,以洗浴保健和旅游疗养为主,且主要在经济发展较好、交通较方便的北疆,南疆地热开发利用程度较低。通过本次科学考察摸清了新疆地热资源分布与开发利用现状情况,结合新疆国土空间规划,围绕新疆“双碳”发展战略,课题组提出新疆地热能源资源开发利用路线建议:在南疆塔什库尔干塔吉克自治县等地区推动“地热发电+综合利用”发展,在北疆温泉县等地区大力推进“地热+”综合能源开发,在乌-昌-石城市群全面深化浅层、中深层岩土地热能利用。

关键词: 第三次新疆综合科学考察, 能源转型, 资源禀赋, 地热开发, 地热发电, 地热供暖

Abstract:

Based on the theoretical understanding of a “cold crust and cold mantle” geological structure, Xinjiang has long been considered relatively poor in geothermal resources, with its overall exploration and utilization significantly lagging behind eastern China. As part of the Third Xinjiang Scientific Expedition Program, the geothermal study involved supplementary field surveys alongside the collection and systematization of existing geothermal research data from across Xinjiang. The expedition newly identified 11 geothermal sites and established two models of geothermal resource occurrence, estimating the region’s geothermal potential to be equivalent to over 1.8 billion tons of standard coal. Survey results indicate that Xinjiang’s geothermal resources are primarily distributed in intermountain uplifted areas, showing significant overlap with population centers. The region’s relatively small population implies a relatively high per capita geothermal resource endowment, underscoring its considerable development potential. The distribution of geothermal resources in Xinjiang exhibits a distinct pattern: generally poorer endowment in the north versus richer endowment in the south. The North Xinjiang Tianshan and Altay Mountain regions host widespread medium-low temperature hydrothermal resources formed by deep fracture circulation, while the South Xinjiang Pamir Plateau, influenced by the India-Eurasia plate collision, contains the only high-temperature geothermal system so far discovered in Xinjiang. However, the overall development and utilization of these resources remains limited, characterized by singular applications such as bathing, healthcare, and tourism, concentrated mainly in the more accessible and economically developed North Xinjiang; development in the south is comparatively scarce. This scientific expedition has clarified the distribution and status of Xinjiang’s geothermal resources. Based on these findings and aligned with Xinjiang’s territorial spatial planning and ‘Dual Carbon’ goals, the research team proposes the following development pathways: promoting “geothermal power generation + comprehensive utilization” in southern Xinjiang areas such as Tashkurgan County; advancing “Geothermal +” integrated energy development in northern Xinjiang areas like Wenquan County; and enhancing the utilization of shallow to medium-depth geothermal energy from rock and soil layers throughout the Urumqi-Changji-Shihezi urban agglomeration.

Key words: The Third Xinjiang Scientific Expedition Program, energy transition, resource endowment, geothermal development, geothermal power generation, geothermal heating

中图分类号:

P314.1
TE02

孔彦龙, 董远卓, 叶灿滔, 程远志, 乃尉华, 庞忠和, 马伟斌, 张健, 龚宇烈, 李义曼, 姜光政, 王迎春, 古丽波斯坦·吐逊江, 田小明, 李棱雪, 师德扬, 张程凯, 田逸楠, 李斌, 陈锋, 张磊, 王珂, 任亚倩, 张伟尊, 罗冠中, 段佳斌, 陈娅奎, 张小雷, 汪集暘. 新疆地热资源分布、成因及开发利用方向:第三次新疆综合科学考察地热科考成果综述[J]. 地学前缘, 2026, 33(1): 283-295.

KONG Yanlong, DONG Yuanzhuo, YE Cantao, CHENG Yuanzhi, NAI Weihua, PANG Zhonghe, MA Weibin, ZHANG Jian, GONG Yulie, LI Yiman, JIANG Guangzheng, WANG Yingchun, Gulbostan TURSUN, TIAN Xiaoming, LI Lengxue, SHI Deyang, ZHANG Chengkai, TIAN Yinan, LI Bin, CHEN Feng, ZHANG Lei, WANG Ke, REN Yaqian, ZHANG Weizun, LUO Guanzhong, DUAN Jiabin, CHEN Yakui, ZHANG Xiaolei, WANG Jiyang. The distribution, genesis and utilization directions of geothermal resources in Xinjiang: A summary of the Third Xinjiang Scientific Expedition Program to geothermal science in Xinjiang[J]. Earth Science Frontiers, 2026, 33(1): 283-295.

图/表 7

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编号	地热点名称	热储温度/℃	地热资源量/kJ	折合标煤/t
1	乌鲁木齐市水磨沟地热田	51.1	5.57E+14	1.90E+07
2	福海县阿拉善地热异常区	132.8	1.64E+15	5.59E+07
3	福海县库马拉山地热异常区	116.3	1.43E+15	4.88E+07
4	富蕴县库木阿拉善地热异常区	117.9	1.52E+15	5.21E+07
5	富蕴县巴利尔斯地热异常区	120.2	1.55E+15	5.31E+07
6	富蕴县沃萨依地热异常区	120.2	1.55E+15	5.31E+07
7	富蕴县切格尔台地热异常区	121.2	1.57E+15	5.35E+07
8	富蕴县吉浪德地热异常区	123.6	1.60E+15	5.45E+07
9	托里县铁厂沟地热异常区	39.2	4.39E+14	1.50E+07
10	乌苏市南山地热异常区	104.6	1.24E+15	4.23E+07
11	沙湾县金沟河地热异常区	138.7	1.68E+15	5.72E+07
12	呼图壁县达拉拜地热异常区	85.2	1.02E+15	3.48E+07
13	温泉县圣山地热田	119.7	1.48E+15	5.04E+07
14	温泉县阿尔夏提地热异常区	86.5	1.05E+15	3.60E+07
15	温泉县小温泉地热异常区	102.6	1.26E+15	4.30E+07
16	吐鲁番北地热异常区	95.3	1.07E+15	3.65E+07
17	尼勒克县巴尔盖提地热异常区	119.1	1.44E+15	4.92E+07
18	尼勒克县布隆地热异常区	96	1.15E+15	3.92E+07
19	尼勒克县蒙克德萨依地热异常区	117.9	1.43E+15	4.87E+07
20	尼勒克县阿拉善地热异常区	117.1	1.42E+15	4.84E+07
21	察布查尔地热田	61.8	7.13E+14	2.44E+07
22	尼勒克县小阿拉善地热异常区	106.7	1.28E+15	4.39E+07
23	特克斯县阔克苏地热异常区	109.3	1.32E+15	4.52E+07
24	昭苏县夏塔地热异常区	108	1.34E+15	4.56E+07
25	和静县阿热先地热异常区	116.6	1.41E+15	4.82E+07
26	塔中石油基地1、2地热异常区	130	1.52E+15	5.21E+07
27	拜城县铁热克地热异常区	117.7	1.40E+15	4.78E+07
28	柯坪县音干地热异常区	55.8	5.64E+14	1.93E+07
29	乌恰县玉其塔什地热异常区	32	3.18E+14	1.09E+07
30	乌恰县库库尔特地热异常区	69.5	7.94E+14	2.71E+07
31	乌恰县乌恰地热异常区	49.5	5.40E+14	1.85E+07
32	阿图什市哈拉峻乡地热异常区	80.4	9.27E+14	3.17E+07
33	阿克陶县盖孜地热异常区	100.3	1.13E+15	3.87E+07
34	阿克陶县羊布拉克地热异常区	120.7	1.39E+15	4.75E+07
35	阿克陶县唐哥塔地热异常区	102.2	1.16E+15	3.95E+07
36	314国道地热异常区	95.8	1.07E+15	3.67E+07
37	塔县塔合曼地热异常区	122.3	1.52E+15	5.19E+07
38	塔县拜什库尔干地热异常区	96.1	1.20E+15	4.10E+07
39	塔县瓦恰地热异常区	95.8	1.22E+15	4.16E+07
40	塔县达布达尔地热异常区	149.2	1.88E+15	6.41E+07
41	塔县马尔洋地热异常区	149.2	1.88E+15	6.41E+07
42	曲曼地热异常区	202.1	2.55E+15	8.71E+07
43	十三连地地热异常区	95.8	1.98E+14	6.76E+06
44	克孜尔地热异常区	74.4	1.47E+14	5.02E+06
45	千佛洞地热异常区	57.9	1.09E+14	3.72E+06
46	鄯善县迪坎儿村地热异常区	50.9	8.66E+13	2.96E+06
47	五彩湾地热异常区	85.4	1.71E+14	5.84E+06
48	民丰县阿依吐拉罕马扎地热异常区	90.8	1.07E+15	3.64E+07
合计			5.50E+16	1.88E+09

编号	地热点名称	热储温度/℃	地热资源量/kJ	折合标煤/t
1	乌鲁木齐市水磨沟地热田	51.1	5.57E+14	1.90E+07
2	福海县阿拉善地热异常区	132.8	1.64E+15	5.59E+07
3	福海县库马拉山地热异常区	116.3	1.43E+15	4.88E+07
4	富蕴县库木阿拉善地热异常区	117.9	1.52E+15	5.21E+07
5	富蕴县巴利尔斯地热异常区	120.2	1.55E+15	5.31E+07
6	富蕴县沃萨依地热异常区	120.2	1.55E+15	5.31E+07
7	富蕴县切格尔台地热异常区	121.2	1.57E+15	5.35E+07
8	富蕴县吉浪德地热异常区	123.6	1.60E+15	5.45E+07
9	托里县铁厂沟地热异常区	39.2	4.39E+14	1.50E+07
10	乌苏市南山地热异常区	104.6	1.24E+15	4.23E+07
11	沙湾县金沟河地热异常区	138.7	1.68E+15	5.72E+07
12	呼图壁县达拉拜地热异常区	85.2	1.02E+15	3.48E+07
13	温泉县圣山地热田	119.7	1.48E+15	5.04E+07
14	温泉县阿尔夏提地热异常区	86.5	1.05E+15	3.60E+07
15	温泉县小温泉地热异常区	102.6	1.26E+15	4.30E+07
16	吐鲁番北地热异常区	95.3	1.07E+15	3.65E+07
17	尼勒克县巴尔盖提地热异常区	119.1	1.44E+15	4.92E+07
18	尼勒克县布隆地热异常区	96	1.15E+15	3.92E+07
19	尼勒克县蒙克德萨依地热异常区	117.9	1.43E+15	4.87E+07
20	尼勒克县阿拉善地热异常区	117.1	1.42E+15	4.84E+07
21	察布查尔地热田	61.8	7.13E+14	2.44E+07
22	尼勒克县小阿拉善地热异常区	106.7	1.28E+15	4.39E+07
23	特克斯县阔克苏地热异常区	109.3	1.32E+15	4.52E+07
24	昭苏县夏塔地热异常区	108	1.34E+15	4.56E+07
25	和静县阿热先地热异常区	116.6	1.41E+15	4.82E+07
26	塔中石油基地1、2地热异常区	130	1.52E+15	5.21E+07
27	拜城县铁热克地热异常区	117.7	1.40E+15	4.78E+07
28	柯坪县音干地热异常区	55.8	5.64E+14	1.93E+07
29	乌恰县玉其塔什地热异常区	32	3.18E+14	1.09E+07
30	乌恰县库库尔特地热异常区	69.5	7.94E+14	2.71E+07
31	乌恰县乌恰地热异常区	49.5	5.40E+14	1.85E+07
32	阿图什市哈拉峻乡地热异常区	80.4	9.27E+14	3.17E+07
33	阿克陶县盖孜地热异常区	100.3	1.13E+15	3.87E+07
34	阿克陶县羊布拉克地热异常区	120.7	1.39E+15	4.75E+07
35	阿克陶县唐哥塔地热异常区	102.2	1.16E+15	3.95E+07
36	314国道地热异常区	95.8	1.07E+15	3.67E+07
37	塔县塔合曼地热异常区	122.3	1.52E+15	5.19E+07
38	塔县拜什库尔干地热异常区	96.1	1.20E+15	4.10E+07
39	塔县瓦恰地热异常区	95.8	1.22E+15	4.16E+07
40	塔县达布达尔地热异常区	149.2	1.88E+15	6.41E+07
41	塔县马尔洋地热异常区	149.2	1.88E+15	6.41E+07
42	曲曼地热异常区	202.1	2.55E+15	8.71E+07
43	十三连地地热异常区	95.8	1.98E+14	6.76E+06
44	克孜尔地热异常区	74.4	1.47E+14	5.02E+06
45	千佛洞地热异常区	57.9	1.09E+14	3.72E+06
46	鄯善县迪坎儿村地热异常区	50.9	8.66E+13	2.96E+06
47	五彩湾地热异常区	85.4	1.71E+14	5.84E+06
48	民丰县阿依吐拉罕马扎地热异常区	90.8	1.07E+15	3.64E+07
合计			5.50E+16	1.88E+09

新疆地热资源分布、成因及开发利用方向:第三次新疆综合科学考察地热科考成果综述

The distribution, genesis and utilization directions of geothermal resources in Xinjiang: A summary of the Third Xinjiang Scientific Expedition Program to geothermal science in Xinjiang

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