The morphological evidence for the regional continuity and diversity of Middle Pleistocene human evolution in China

doi:10.16359/j.cnki.cn11-1963/q.2019.0048

Abstract

Abstract:

For decades, the Middle Pleistocene human fossils found in China have been attributed into Homo erectus and archaic Homo sapiens; respectively. This classification was mainly based on morphology and chronology of these fossils. Some cranial, mandibular and dental features identified and described on the human fossils of Zhoukoudian locality 1 by Weidenreich have been used as the standard for Homo erectus. According to the chronology of the Chinese Middle Pleistocene human fossils, later period of Middle Pleistocene around 300 ka are usually regarded as approximate border between Homo erectus and archaic Homo sapiens. For the past two decades, more Middle Pleistocene human fossils have been found in Africa, Europe and East Asia. Currently, the understanding for the fossil morphology and evolution of Middle Pleistocene humans has changed a lot. Recent studies of human fossils from Dali, Xujiayao, Panxian Dadong, Xuchang, Hualongdong indicate that in the past 300 ka, the human evolution in East Asia exhibited complicated diversities. Classifying all the hominins of this time period into archaic Homo sapiens cannot accurately reflect the human evolution patterns in East Asian continent. In the present study, with considering the research progress of Middle Pleistocene human evolution in China, the expressions of some morphological features with evolutionary and taxonomic values were analyzed for the Middle Pleistocene human fossils. Based on these analysis, the evolution pattern of Middle Pleistocene humans in China were tentatively explored. Our study indicates that the human fossils of early period of Middle Pleistocene in China including Zhoukoudian, Hexian, Yiyuan, Nanjing exhibit more features characterizing the region pattern and the expression of these feature are relatively stable. In contrast, the morphology expressions of human fossils from later period of Middle Pleistocene like Dali, Jinniushan, Maba, Panxian Dadong, Xujiayao, Xuchang, Hualongdong are more complicated with wide variation ranges. Besides, a number of evidence showing the living activity, healthy status and adaptation to environment have been found in the human fossils of this period. With these findings, the authors propose that the human evolution of early period of Middle Pleistocene in China mainly follows the pattern of morphological continuity. Entering the later part of Middle Pleistocene, the regional pattern of human evolution in China decreased with diversity taking the main place. A series of new human fossil findings and research progresses indicate that several hominins may co-exist in Middle Pleistocene’s East Asia. With available evidence of human fossil morphology and chronology, approximately 300 ka is the key time point for the evolution changes in Middle Pleistocene in China.

Key words: Middle Pleistocene, Homo erectus, Archaic Homo sapiens, Regional continuity, Diversity, China

CLC Number:

Q983

LIU Wu, WU Xiujie, XING Song. The morphological evidence for the regional continuity and diversity of Middle Pleistocene human evolution in China[J]. Acta Anthropologica Sinica, 2019, 38(04): 473-490.

Figures/Tables 9

References 61

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化石地点(Site)	人类化石(Human fossil)	时代/年代(Age)	主要数据来源(Source)
周口店第一地点(ZKD Loc.1)	头骨、下颌骨、牙齿	Q21/≈500 kaBP[23]	化石、模型、文献[3-5,24-25]
蓝田陈家窝子(Chenjiawozi)	下颌骨及附带牙齿	Q21/650 kaBP[26]	化石
沂源( Yiyuan)	头骨、牙齿	Q21/630 kaBP[27]	化石、文献[28]
和县(Hexian )	头骨、下颌骨、牙齿	Q21/412 kaBP[29]	化石、文献[30,31]
南京汤山( Nangjing Tangshan)	头骨	Q21/620~580 kaBP[32]	模型、文献[33]
大荔(Dali )	头骨	Q22/300-260 kaBP[34]	模型、文献[14]
金牛山(Jinniushan )	头骨	Q22/260 kaBP[35]	模型、文献[36]
马坝(Maba )	头骨	Q22/130-300 kaBP[37]	化石、文献[16,38-39]
长阳( Changyang)	上颌骨	Q22/195 kaBP[40]	化石、文献[41]
桐梓( Tongzi)	牙齿	Q22/113-206 kaBP[42]	化石、文献[20]
巢县( Chaoxian)	头骨、牙齿	Q22/200-300 kaBP[43]	化石、文献[15,41]
丁村(Dingcun )	牙齿	Q22/160-200 kaBP[44]	化石
许家窑(Xujiayao )	头骨、牙齿	Q22/120-200 kaBP[44-46]	化石、文献[17,41,47-48]
盘县大洞(Panxian Dadong )	牙齿	Q22/280-130 kaBP[49]	化石、文献[18]
许昌( Xuchang)	头骨	Q22/125-160 kaBP[19]	化石、文献[19]
华龙洞(Hualongdong )	头骨、下颌骨、牙齿	Q22/270-300 kaBP[21]	化石、文献[21]

化石地点(Site)	人类化石(Human fossil)	时代/年代(Age)	主要数据来源(Source)
周口店第一地点(ZKD Loc.1)	头骨、下颌骨、牙齿	Q21/≈500 kaBP[23]	化石、模型、文献[3-5,24-25]
蓝田陈家窝子(Chenjiawozi)	下颌骨及附带牙齿	Q21/650 kaBP[26]	化石
沂源( Yiyuan)	头骨、牙齿	Q21/630 kaBP[27]	化石、文献[28]
和县(Hexian )	头骨、下颌骨、牙齿	Q21/412 kaBP[29]	化石、文献[30,31]
南京汤山( Nangjing Tangshan)	头骨	Q21/620~580 kaBP[32]	模型、文献[33]
大荔(Dali )	头骨	Q22/300-260 kaBP[34]	模型、文献[14]
金牛山(Jinniushan )	头骨	Q22/260 kaBP[35]	模型、文献[36]
马坝(Maba )	头骨	Q22/130-300 kaBP[37]	化石、文献[16,38-39]
长阳( Changyang)	上颌骨	Q22/195 kaBP[40]	化石、文献[41]
桐梓( Tongzi)	牙齿	Q22/113-206 kaBP[42]	化石、文献[20]
巢县( Chaoxian)	头骨、牙齿	Q22/200-300 kaBP[43]	化石、文献[15,41]
丁村(Dingcun )	牙齿	Q22/160-200 kaBP[44]	化石
许家窑(Xujiayao )	头骨、牙齿	Q22/120-200 kaBP[44-46]	化石、文献[17,41,47-48]
盘县大洞(Panxian Dadong )	牙齿	Q22/280-130 kaBP[49]	化石、文献[18]
许昌( Xuchang)	头骨	Q22/125-160 kaBP[19]	化石、文献[19]
华龙洞(Hualongdong )	头骨、下颌骨、牙齿	Q22/270-300 kaBP[21]	化石、文献[21]

遗址Site	整体曲度指数 (纵向) ABH/GLO	整体曲度指数 (横向) ABH/XCB	额骨曲度 FRC/FRA	顶骨曲度 PAC/PAA	顶骨横向曲度指数 BRAC/BRAA	枕骨曲度指数 L-O chord/arc 枕骨曲角
ZKD 2 (Q21)			91.9	94.3
ZKD 3 (Q21)	51.3	60.9	88.7	94.9	87.6	77.8 / 106°
ZKD 5 (Q21)		60.7	89.2		91.6	71.6
ZKD 10(Q21)	53.3	64.0	89.1	93.8	85.2	/104°
ZKD 11(Q21)	49.0	63.3	87.3	93.5	87.1	73.5/ /105°
ZKD 12(Q21)	51.9	65.7	90.8	95.8	86.8	72.9 / 98°
南京 1 号/Nanjing 1(Q21)	51.4	60.8	90.8	95.1	88.8	75.8 / 106°
和县/Hexian(Q21)	50.0	59.4	82.5	93.6	81.7	75.2
早期组平均/Average	51.2	62.1	88.8	94.4	86.8	74.4
大荔/Dali(Q22)	49.6	68.6	84.4	93.0	79.8	68.3 / 105°
金牛山/Jinniushan(Q22)	47.8	66.5	83.3	92.4	83.6	72.6/ 93.7°
马坝/Maba(Q22)			86.3	93.9
许昌/Xuchang(Q22)		55.9		96.1	81.6
许家窑/Xujiayao(Q22)				94.5	81.1
华龙洞/Hualongdong(Q22)	58.3	69.4	87.3	91.0
晚期组平均/Average	51.9	65.1	85.3	93.5	81.5	73.6/99.4°

遗址Site	整体曲度指数 (纵向) ABH/GLO	整体曲度指数 (横向) ABH/XCB	额骨曲度 FRC/FRA	顶骨曲度 PAC/PAA	顶骨横向曲度指数 BRAC/BRAA	枕骨曲度指数 L-O chord/arc 枕骨曲角
ZKD 2 (Q21)			91.9	94.3
ZKD 3 (Q21)	51.3	60.9	88.7	94.9	87.6	77.8 / 106°
ZKD 5 (Q21)		60.7	89.2		91.6	71.6
ZKD 10(Q21)	53.3	64.0	89.1	93.8	85.2	/104°
ZKD 11(Q21)	49.0	63.3	87.3	93.5	87.1	73.5/ /105°
ZKD 12(Q21)	51.9	65.7	90.8	95.8	86.8	72.9 / 98°
南京 1 号/Nanjing 1(Q21)	51.4	60.8	90.8	95.1	88.8	75.8 / 106°
和县/Hexian(Q21)	50.0	59.4	82.5	93.6	81.7	75.2
早期组平均/Average	51.2	62.1	88.8	94.4	86.8	74.4
大荔/Dali(Q22)	49.6	68.6	84.4	93.0	79.8	68.3 / 105°
金牛山/Jinniushan(Q22)	47.8	66.5	83.3	92.4	83.6	72.6/ 93.7°
马坝/Maba(Q22)			86.3	93.9
许昌/Xuchang(Q22)		55.9		96.1	81.6
许家窑/Xujiayao(Q22)				94.5	81.1
华龙洞/Hualongdong(Q22)	58.3	69.4	87.3	91.0
晚期组平均/Average	51.9	65.1	85.3	93.5	81.5	73.6/99.4°

遗址(Site)	绝对颅容量(mL)	相对颅容量(EQ)	顶骨横向曲度指数 (BRAC/BRAA)
ZKD 2 (Q21)	1130
ZKD 3 (Q21)	915		87.6 (121.8/139.0)
ZKD 5 (Q21)	1140		91.6 (128.2/140.0)
ZKD 10(Q21)	1225		85.2 (132.5/155.5)
ZKD 11(Q21)	1015	4.6	87.1 (126.3/145.0)
ZKD 12(Q21)	1030		86.8 (133.2/153.5)
南京 1 号(Q21)	860		88.8 (119.0/134.0)
和县(Q21)	1025		81.7(124.8/152.7)
早期组平均	1042.5		86.8 (126.5/145.7)
大荔(Q22)	1120	5.3	79.8 (130.9/164.1)
金牛山(Q22)	1390		83.6 (128.5/153.7)
马坝(Q22)	1300
许昌(Q22)	1800	5.45	81.6 (146.6/179.6)
许家窑(XJY6 PA1486/1490)(Q22)			81.1 (142.0/175.0)
华龙洞(Q22)	1150
晚期组平均	1352		81.5 (137.0/168.1)