STUDY ON CENOZOIC PROVENANCE OF THE NORTHERN QAIDAM BASIN: INSIGHTS FROM QUANTITATIVE PRO-VENANCE CONSTRAINTS BASED ON DETRITAL ZIRCON U-Pb DATA

doi:10.3969/j.issn.0253-4967.20240053

Abstract

Abstract:

The Qaidam Basin, as the largest continental sedimentary basin on the northeastern margin of the Qinghai-Xizang Plateau, has formed thick sedimentary strata since the Cenozoic. Its complete and continuous Cenozoic sedimentary strata not only record the sedimentary evolution of the Qaidam Basin but also reflect the uplift and erosion of the adjacent orogenic belts and regional climate-environmental changes. Furthermore, they serve as a crucial resource for understanding the development of the basin-mountain system, tectonic deformation, and the mechanisms and patterns driving the northward expansion of the Qinghai-Xizang Plateau on the northeastern margin. Therefore, it is vital to reconstruct the sedimentary evolution history of the Qaidam Basin during the Cenozoic. Currently, the detrital zircon U-Pb dating method is the most widely used provenance analysis method for reconstructing the basin’s tectonic evolution and the uplift history of the surrounding mountain ranges. However, this method usually relies too heavily on qualitative comparisons of zircon U-Pb age spectra and lacks reliable quantitative analysis. This limitation directly leads to significant differences and disputes in some key understandings, such as the erosion of the source and the transport path of sediments. To address this issue, we selected three representative Cenozoic sedimentary sections on the northern margin of the Qaidam Basin for our study: Dahongou, Hongshan, and Huaitoutala. At the same time, by systematically collecting the latest published U-Pb age data of detrital zircons and basement zircons in modern river sands, we redefined three main provenance areas, including the southern segment of the Qilian Mountains, the East Kunlun Mountains, and the Mesozoic strata in the northern part of the Qaidam Basin. The results show that the Dahongou, Hongshan, and Huaitoutala sections have 6, 2, and 3 distinct shifts in provenance, respectively. Although the sedimentary provenance evolution patterns of these sections are not completely consistent, there is a quasi-synchronous provenance change at ~12-10Ma. Around ~20Ma, the southern Qilian Mountains expanded towards the Qaidam Basin, causing the uplift and erosion of the Mesozoic strata on the northern margin of the Qaidam Basin. All three sections recorded the significant contribution of the Mesozoic provenance from the northern margin of the Qaidam Basin during this period. Although the East Kunlun Mountains experienced a rapid uplift and erosion event in the middle-late Miocene, this tectonic event had a relatively limited impact on the provenance of the Hongshan section, underscoring the limitations of single-section studies for elucidating regional tectonic and sedimentary evolution. Additionally, the simulation of provenance inversion suggests that the northern margin of the Qaidam Basin experienced influences from at least three distinct provenance regions throughout the Cenozoic. The zircon age distribution characteristics of simulated source area Ⅰ closely resemble the detrital zircon age distribution found in modern river sands across the eastern Kunlun Mountains, as per our compilation. Meanwhile, the zircon age distribution in simulated source area Ⅱ closely matches that of modern river sands in the southern Qilian Mountains. Additionally, the provenance area Ⅲ revealed by the inversion simulation exhibits a notable Proterozoic double-peak zircon age signature, although it shows a higher proportion of zircon components exceeding 550Ma, closely aligning with the detrital zircon age composition from the Mesozoic strata(including Jurassic and Cretaceous) of the northern margin of the Qaidam Basin that we compiled. Overall, the inversion simulation results reveal a substantial similarity in the zircon age distribution between the simulated source area III and the Mesozoic strata in the northern margin of the Qaidam Basin. Moreover, in most Mesozoic clastic samples, a significant proportion of the parent material is derived from sources. This suggests that during the Neogene, the relationship between the Mesozoic parent material sources in the northern margin of the Qaidam Basin is more complex than simply a competition between the two end-member source areas, namely the South Qilian Mountains and the East Kunlun Mountains, as has been previously highlighted. Additionally, the Mesozoic strata uncovered by the frontal thrust deformation are likely to be significant contributors to the material supply during the Neogene. Additionally, the provenance inversion simulation in this study is consistent with the above forward simulation results, indicating the rationality and credibility of the provenance interpretation. At the same time, it also shows that, in cases where the number of potential source areas is difficult to determine and the age composition of source-area zircons is difficult to constrain, provenance-inversion simulation will be one of the most effective methods. In conclusion, we believe that the quasi-synchronous provenance change at ~12~10Ma may represent the surface response to the deep-dynamic transformation of the plateau, namely, the delamination of the thickened lithosphere triggers regional tectonic uplift and surface deformation. Besides, the East Kunlun Mountains and the southern Qilian Mountains, the Mesozoic strata distributed in the transition zone between the southern Qilian Mountains and the northern margin of the Qaidam Basin are another important provenance area for the Cenozoic sedimentary process on the northern margin of the Qaidam Basin. The zircon age distribution of these strata is often confused with the provenance of the East Kunlun Mountains in previous studies. These insights provide reliable references for a deeper understanding of the evolution of the Cenozoic Basin-mountain system on the northeastern margin of the Qinghai-Xizang Plateau. We emphasize that, in complex basin-mountain systems, simply comparing the age distributions of detrital zircons in most provenance analyses is no longer sufficient. A thorough qualitative and quantitative analysis and assessment are more conducive to obtaining reliable and comprehensive results.

Key words: Northern Qaidam Basin, Cenozoic strata, detrital zircon, provenance modeling

摘要：

完整连续的柴达木盆地新生代地层是揭示青藏高原东北缘盆-山格局演化、地表构造变形时间及高原向N扩展模式和动力学机制的重要研究载体。其中, 碎屑锆石物源分析又是厘清柴达木盆地构造演化过程、重建周缘造山带隆升历史的关键研究方法之一。然而, 以往的碎屑锆石物源研究多是基于简单定性的特征对比, 缺乏定量的分析手段, 直接导致在一些关键认识上出现重大分歧。文中选取大红沟、红山、怀头他拉3个典型的柴北缘新生代剖面, 汇总收集了具有代表性的碎屑锆石U-Pb数据, 并重新定义了南祁连山、东昆仑山和柴北缘中生界3个潜在物源区。基于碎屑锆石数据的正演和反演物源模拟, 我们发现柴北缘中生代地层也是新生代盆地的重要物源区之一, 其物源贡献量不能被忽视。此外, 大红沟剖面、红山剖面、怀头他拉剖面的物源演化规律具有明显的时空异质性, 仅在距今12~10Ma发生了一期准同步的物源变化, 可能是高原中部岩石圈拆沉的地表响应。因此, 简单的碎屑锆石年龄分布对比无法满足复杂盆-山系统下的物源分析工作, 定性和定量研究手段的联合使用和综合判断有利于得到更加可靠、更加深刻的认识。

关键词: 柴北缘, 新生代地层, 碎屑锆石, 物源模拟

DONG Ling-feng, WANG Wei-tao, QIAO Yu-lai. STUDY ON CENOZOIC PROVENANCE OF THE NORTHERN QAIDAM BASIN: INSIGHTS FROM QUANTITATIVE PRO-VENANCE CONSTRAINTS BASED ON DETRITAL ZIRCON U-Pb DATA[J]. SEISMOLOGY AND GEOLOGY, 2026, 48(1): 81-101.

董凌峰, 王伟涛, 乔宇来. 柴达木盆地北缘新生代物源示踪研究——基于碎屑锆石U-Pb数据的定量约束[J]. 地震地质, 2026, 48(1): 81-101.

Figures/Tables 10

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剖面名称	原始样品编号	地层年龄	锆石颗粒数量	文献来源
大红沟剖面	2DH6126	4.9Ma	95	Bush et al., 2016
大红沟剖面	2DH5484	10Ma	99	Bush et al., 2016
大红沟剖面	2DH4580	13Ma	104	Bush et al., 2016
大红沟剖面	2DH3774	15Ma	97	Bush et al., 2016
大红沟剖面	2DH3040	18Ma	97	Bush et al., 2016
大红沟剖面	2DH1770	20Ma	103	Bush et al., 2016
大红沟剖面	2DH1184	23Ma	95	Bush et al., 2016
大红沟剖面	220611-01	24.5	101	Bush et al., 2016
大红沟剖面	2DH224	25Ma	97	Bush et al., 2016
大红沟剖面	2DH0	25.5Ma	97	Bush et al., 2016
大红沟剖面	1DH0	25.5Ma	106	Bush et al., 2016
大红沟剖面	H860	5.5Ma	86	Wang et al., 2017
大红沟剖面	H792	6.5Ma	94	Wang et al., 2017
大红沟剖面	H753	6.8Ma	93	Wang et al., 2017
大红沟剖面	H706	7.6Ma	93	Wang et al., 2017
大红沟剖面	H545	10Ma	97	Wang et al., 2017
大红沟剖面	H351	12.5Ma	92	Wang et al., 2017
大红沟剖面	D54	23.7Ma	87	Wang et al., 2017
怀头他拉剖面	07HTA046	2.1Ma	109	Zhuang et al., 2018
怀头他拉剖面	07HT490	3.9Ma	103	Zhuang et al., 2018
怀头他拉剖面	07HT364	6.5Ma	105	Zhuang et al., 2018
怀头他拉剖面	07HT308	7.8Ma	102	Zhuang et al., 2018
怀头他拉剖面	07HT209	10.9Ma	103	Zhuang et al., 2018
怀头他拉剖面	07HT023	14.8Ma	111	Zhuang et al., 2018
怀头他拉剖面	07HTB042	15.1Ma	94	Zhuang et al., 2018
怀头他拉剖面	160611-02	12Ma	107	Bush et al., 2016
怀头他拉剖面	CD34	4Ma	96	Li et al., 2021
怀头他拉剖面	CD33	7Ma	83	Li et al., 2021
怀头他拉剖面	CD32	12Ma	83	Li et al., 2021
怀头他拉剖面	CD31	13Ma	96	Li et al., 2021
怀头他拉剖面	CD30	15Ma	97	Li et al., 2021
怀头他拉剖面	CD07-38	20Ma	89	本研究
红山剖面	E624	5.5Ma	101	Wang et al., 2022
红山剖面	E447	9.8Ma	90	Wang et al., 2022
红山剖面	E375	12Ma	91	Wang et al., 2022
红山剖面	W6	16.8Ma	93	Wang et al., 2022
红山剖面	E99	19Ma	94	Wang et al., 2022
红山剖面	W232	21.5Ma	96	Wang et al., 2022
红山剖面	W309	23.7Ma	95	Wang et al., 2022
红山剖面	W401	27.2Ma	88	Wang et al., 2022

剖面名称	原始样品编号	地层年龄	锆石颗粒数量	文献来源
大红沟剖面	2DH6126	4.9Ma	95	Bush et al., 2016
大红沟剖面	2DH5484	10Ma	99	Bush et al., 2016
大红沟剖面	2DH4580	13Ma	104	Bush et al., 2016
大红沟剖面	2DH3774	15Ma	97	Bush et al., 2016
大红沟剖面	2DH3040	18Ma	97	Bush et al., 2016
大红沟剖面	2DH1770	20Ma	103	Bush et al., 2016
大红沟剖面	2DH1184	23Ma	95	Bush et al., 2016
大红沟剖面	220611-01	24.5	101	Bush et al., 2016
大红沟剖面	2DH224	25Ma	97	Bush et al., 2016
大红沟剖面	2DH0	25.5Ma	97	Bush et al., 2016
大红沟剖面	1DH0	25.5Ma	106	Bush et al., 2016
大红沟剖面	H860	5.5Ma	86	Wang et al., 2017
大红沟剖面	H792	6.5Ma	94	Wang et al., 2017
大红沟剖面	H753	6.8Ma	93	Wang et al., 2017
大红沟剖面	H706	7.6Ma	93	Wang et al., 2017
大红沟剖面	H545	10Ma	97	Wang et al., 2017
大红沟剖面	H351	12.5Ma	92	Wang et al., 2017
大红沟剖面	D54	23.7Ma	87	Wang et al., 2017
怀头他拉剖面	07HTA046	2.1Ma	109	Zhuang et al., 2018
怀头他拉剖面	07HT490	3.9Ma	103	Zhuang et al., 2018
怀头他拉剖面	07HT364	6.5Ma	105	Zhuang et al., 2018
怀头他拉剖面	07HT308	7.8Ma	102	Zhuang et al., 2018
怀头他拉剖面	07HT209	10.9Ma	103	Zhuang et al., 2018
怀头他拉剖面	07HT023	14.8Ma	111	Zhuang et al., 2018
怀头他拉剖面	07HTB042	15.1Ma	94	Zhuang et al., 2018
怀头他拉剖面	160611-02	12Ma	107	Bush et al., 2016
怀头他拉剖面	CD34	4Ma	96	Li et al., 2021
怀头他拉剖面	CD33	7Ma	83	Li et al., 2021
怀头他拉剖面	CD32	12Ma	83	Li et al., 2021
怀头他拉剖面	CD31	13Ma	96	Li et al., 2021
怀头他拉剖面	CD30	15Ma	97	Li et al., 2021
怀头他拉剖面	CD07-38	20Ma	89	本研究
红山剖面	E624	5.5Ma	101	Wang et al., 2022
红山剖面	E447	9.8Ma	90	Wang et al., 2022
红山剖面	E375	12Ma	91	Wang et al., 2022
红山剖面	W6	16.8Ma	93	Wang et al., 2022
红山剖面	E99	19Ma	94	Wang et al., 2022
红山剖面	W232	21.5Ma	96	Wang et al., 2022
红山剖面	W309	23.7Ma	95	Wang et al., 2022
红山剖面	W401	27.2Ma	88	Wang et al., 2022

²⁰⁷Pb/²⁰⁶Pb	1s	²⁰⁷Pb/²³⁵Pb	1s	²⁰⁶Pb²³⁸U	1s	²⁰⁸Pb/²³²Th	1s	不协和度
377	135	261	12	249	6	247	5	-4.82
763	44	828	22	875	18	845	17	5.37
441	30	295	7	280	6	280	6	-5.36
460	22	437	8	442	9	445	9	1.13
276	32	260	7	265	6	261	6	1.89
684	28	479	11	437	9	415	9	-9.61
505	23	378	8	365	8	374	7	-3.56
494	24	257	5	235	5	225	4	-9.36
742	43	452	14	410	9	403	10	-10.24
940	26	619	13	553	12	461	9	-11.93
464	24	476	9	479	10	474	9	0.63
546	23	261	5	233	5	237	5	-12.02
555	22	408	8	407	9	452	9	-0.25
476	23	301	6	283	6	295	6	-6.36
370	26	245	6	232	5	228	5	-5.60
298	23	244	5	239	5	240	5	-2.09
436	173	278	17	259	6	257	5	-7.34
474	28	266	7	246	5	257	5	-8.13
485	26	423	9	419	9	418	8	-0.95
554	23	446	8	428	9	413	8	-4.21
493	23	445	8	434	9	418	8	-2.53
558	26	427	9	417	9	411	8	-2.40
702	26	452	10	425	9	398	8	-6.35
486	22	458	8	451	9	442	9	-1.55
374	27	319	7	320	7	322	7	0.31
289	141	264	13	261	6	261	5	-1.15
606	145	422	21	389	9	385	8	-8.48
940	21	895	14	901	18	868	17	0.67
350	29	260	6	253	5	242	5	-2.77
1075	90	953	23	902	19	893	19	-5.65
562	22	487	9	470	10	483	9	-3.62
257	25	246	5	248	5	245	5	0.81
462	144	410	20	401	9	400	8	-2.24
642	23	474	9	443	9	458	9	-7.00
852	22	867	13	848	17	828	16	-2.24
500	73	473	9	467	10	467	12	-1.28
578	26	338	8	306	7	309	6	-10.46
850	22	838	13	831	17	832	16	-0.84
422	27	333	8	320	7	312	6	-4.06
555	137	481	22	465	10	463	9	-3.44
491	23	462	8	462	10	449	9	0.00
507	29	321	8	294	6	281	6	-9.18
533	135	436	20	417	9	415	8	-4.56
943	21	869	13	846	17	822	16	-2.72
569	102	457	15	435	9	432	9	-5.06
974	31	946	19	908	19	926	19	-4.19
815	101	841	24	851	18	852	18	1.18
357	25	379	8	387	8	391	8	2.07
561	25	480	10	469	10	478	10	-2.35
900	21	810	13	782	16	792	15	-3.58
1756	21	1766	22	1772	33	1733	33	0.90
2413	30	2378	31	2558	46	2341	44	5.67
1676	99	1643	38	1617	32	1612	32	-3.65
1952	20	1948	22	1958	36	1965	38	0.31
2427	18	2459	22	2484	44	2510	46	2.29
2435	19	2439	23	2461	44	2382	44	1.06
2456	17	2515	21	2566	46	2575	46	4.29
1783	90	1749	36	1722	34	1716	35	-3.54
1043	20	1039	15	1051	21	1032	22	0.76
2635	17	2521	21	2383	43	2410	44	-10.57
2411	20	2348	24	2364	43	2046	38	-1.99
2337	17	2358	20	2398	43	2361	43	2.54
2443	18	2407	22	2432	44	2465	45	-0.45
2361	25	2394	28	2441	44	2435	45	3.28
1835	20	1834	21	1850	35	1819	34	0.81
1865	18	1817	18	1803	34	1802	34	-3.44
2424	18	2361	22	2312	42	2312	42	-4.84
1168	24	442	10	329	7	294	6	-255.02
2348	19	2352	23	2347	43	2324	43	-0.04
1834	20	1760	20	1713	33	1760	33	-7.06
1649	98	1581	37	1531	32	1522	32	-7.71
2246	18	2166	21	2096	39	2128	39	-7.16
1846	19	1815	20	1775	34	1809	33	-4.00
1619	20	1522	19	1541	30	1535	29	-5.06
2565	18	2536	22	2426	44	2332	43	-5.73
2311	18	2285	22	2306	42	2240	41	-0.22
2446	26	2424	29	2356	43	2432	45	-3.82
1887	19	1881	20	1869	35	1851	34	-0.96
2439	26	2478	29	2461	45	2521	48	0.89
2426	20	2541	24	2673	48	2609	48	9.24
2419	17	2365	21	2326	42	2258	41	-4.00
2438	19	2383	23	2356	43	2605	49	-3.48
1301	92	1287	29	1279	26	1277	27	-1.72
2006	19	2029	21	2060	38	2073	38	2.62
2883	20	2881	25	2863	50	2825	51	-0.70
2218	18	2093	20	1957	37	1900	35	-13.34
2447	19	2480	23	2563	46	2453	45	4.53
2386	73	2242	32	2087	42	2054	44	-14.33
2492	18	2343	22	2201	41	2071	38	-13.22

²⁰⁷Pb/²⁰⁶Pb	1s	²⁰⁷Pb/²³⁵Pb	1s	²⁰⁶Pb²³⁸U	1s	²⁰⁸Pb/²³²Th	1s	不协和度
377	135	261	12	249	6	247	5	-4.82
763	44	828	22	875	18	845	17	5.37
441	30	295	7	280	6	280	6	-5.36
460	22	437	8	442	9	445	9	1.13
276	32	260	7	265	6	261	6	1.89
684	28	479	11	437	9	415	9	-9.61
505	23	378	8	365	8	374	7	-3.56
494	24	257	5	235	5	225	4	-9.36
742	43	452	14	410	9	403	10	-10.24
940	26	619	13	553	12	461	9	-11.93
464	24	476	9	479	10	474	9	0.63
546	23	261	5	233	5	237	5	-12.02
555	22	408	8	407	9	452	9	-0.25
476	23	301	6	283	6	295	6	-6.36
370	26	245	6	232	5	228	5	-5.60
298	23	244	5	239	5	240	5	-2.09
436	173	278	17	259	6	257	5	-7.34
474	28	266	7	246	5	257	5	-8.13
485	26	423	9	419	9	418	8	-0.95
554	23	446	8	428	9	413	8	-4.21
493	23	445	8	434	9	418	8	-2.53
558	26	427	9	417	9	411	8	-2.40
702	26	452	10	425	9	398	8	-6.35
486	22	458	8	451	9	442	9	-1.55
374	27	319	7	320	7	322	7	0.31
289	141	264	13	261	6	261	5	-1.15
606	145	422	21	389	9	385	8	-8.48
940	21	895	14	901	18	868	17	0.67
350	29	260	6	253	5	242	5	-2.77
1075	90	953	23	902	19	893	19	-5.65
562	22	487	9	470	10	483	9	-3.62
257	25	246	5	248	5	245	5	0.81
462	144	410	20	401	9	400	8	-2.24
642	23	474	9	443	9	458	9	-7.00
852	22	867	13	848	17	828	16	-2.24
500	73	473	9	467	10	467	12	-1.28
578	26	338	8	306	7	309	6	-10.46
850	22	838	13	831	17	832	16	-0.84
422	27	333	8	320	7	312	6	-4.06
555	137	481	22	465	10	463	9	-3.44
491	23	462	8	462	10	449	9	0.00
507	29	321	8	294	6	281	6	-9.18
533	135	436	20	417	9	415	8	-4.56
943	21	869	13	846	17	822	16	-2.72
569	102	457	15	435	9	432	9	-5.06
974	31	946	19	908	19	926	19	-4.19
815	101	841	24	851	18	852	18	1.18
357	25	379	8	387	8	391	8	2.07
561	25	480	10	469	10	478	10	-2.35
900	21	810	13	782	16	792	15	-3.58
1756	21	1766	22	1772	33	1733	33	0.90
2413	30	2378	31	2558	46	2341	44	5.67
1676	99	1643	38	1617	32	1612	32	-3.65
1952	20	1948	22	1958	36	1965	38	0.31
2427	18	2459	22	2484	44	2510	46	2.29
2435	19	2439	23	2461	44	2382	44	1.06
2456	17	2515	21	2566	46	2575	46	4.29
1783	90	1749	36	1722	34	1716	35	-3.54
1043	20	1039	15	1051	21	1032	22	0.76
2635	17	2521	21	2383	43	2410	44	-10.57
2411	20	2348	24	2364	43	2046	38	-1.99
2337	17	2358	20	2398	43	2361	43	2.54
2443	18	2407	22	2432	44	2465	45	-0.45
2361	25	2394	28	2441	44	2435	45	3.28
1835	20	1834	21	1850	35	1819	34	0.81
1865	18	1817	18	1803	34	1802	34	-3.44
2424	18	2361	22	2312	42	2312	42	-4.84
1168	24	442	10	329	7	294	6	-255.02
2348	19	2352	23	2347	43	2324	43	-0.04
1834	20	1760	20	1713	33	1760	33	-7.06
1649	98	1581	37	1531	32	1522	32	-7.71
2246	18	2166	21	2096	39	2128	39	-7.16
1846	19	1815	20	1775	34	1809	33	-4.00
1619	20	1522	19	1541	30	1535	29	-5.06
2565	18	2536	22	2426	44	2332	43	-5.73
2311	18	2285	22	2306	42	2240	41	-0.22
2446	26	2424	29	2356	43	2432	45	-3.82
1887	19	1881	20	1869	35	1851	34	-0.96
2439	26	2478	29	2461	45	2521	48	0.89
2426	20	2541	24	2673	48	2609	48	9.24
2419	17	2365	21	2326	42	2258	41	-4.00
2438	19	2383	23	2356	43	2605	49	-3.48
1301	92	1287	29	1279	26	1277	27	-1.72
2006	19	2029	21	2060	38	2073	38	2.62
2883	20	2881	25	2863	50	2825	51	-0.70
2218	18	2093	20	1957	37	1900	35	-13.34
2447	19	2480	23	2563	46	2453	45	4.53
2386	73	2242	32	2087	42	2054	44	-14.33
2492	18	2343	22	2201	41	2071	38	-13.22