A PDO-like record documented by microfossils from the northern region of the California Current System since the Early Pleistocene

doi:10.13745/j.esf.sf.2020.6.23

Abstract

Abstract:

The California Current System (CCS) is a very important boundary current in the Northeast Pacific Ocean and it plays an important role in the global air-ocean interactions. On the interannual and decadal timescales, the ocean-climate change and activity of upwelling in the CCS are principally affected by the Pacific Decadal Oscillation (PDO, with variable periods ranging from 20 to 30 a). To understand the variation of upwelling activity in the northern region of the CCS since the Early Pleistocene and its main control mechanism, we analyzed the data of calcareous nannofossils (fossils of coccolithophores) and diatom fossils from the International Ocean Drilling Program Holes 1020B (southern site, at 41° N) and 1245B (northern site, at 44° N). Our results suggested that abundance variations in these two fossil groups were correlated with most glacial-interglacial cycles, by which high abundances of diatom fossils and nannofosills were associated with glacial and interglacial stages, respectively. Three ca.0.5 Ma long-term stages of fossil abundance variations were recognized: the Early Pleistocene Stage (1.5-1.1 Ma) featured by abundant nannofossils in both holes, the Middle Pleistocene Stage (1.1-0.65 Ma) by relatively abundant diatoms and nannofossils with opposite variation trends in the two holes, and the Late Pleistocene Stage (since 0.65 Ma) by relatively abundant diatoms with very low and sporadic nannofossils in Hole 1245B and contrarily, abundant nannofossils with less abundant diatoms in Hole 1020B. We proposed a mode of long-term dominance of “Pacific Decadal Oscillation (PDO-like)” in combination with “North Pacific Gyre Oscillation (NPGO-like)” mode to explain the possible mechanisms for these records. The northern region of the CCS had been affected by a long-term dominance of +PDO-like phase that led to decreased upwelling during the Early Pleistocene, and by an altering of -PDO (intensified upwelling ) and +PDO phases over the Middle Pleistocene Transition period (MPT). And for the last 0.65 Ma, the region was affected by an altering of strong -NPGO and weak -PDO phases for Hole 1020B, but only by -PDO phase for Hole 1245B. An abrupt increase in diatom abundance (by three times in Hole 1020B and five times in Hole 1245B) marked the setup of MPT at 1.1 Ma, and a significant change in abundances of calcareous nannofossils (3-fold increase and reduction at the southern and northern sites, respectively) indicated the end of MPT at 0.65 Ma. This altering of microfossil abundances was seen as the results of abrupt palaeoceanographic changes. It further implied that the shift from a positive to a negative phase of long-term PDO-like dominance period may be abrupt too. The opposite changing trends of these two fossil groups at the northern and southern sites during and after MPT indicated possible geographical differentiation of ocean-climate conditions in the northern region of the CCS. It provided the Pleistocene records for the study of modern air-ocean processes and biological distribution with the regional boundary at 40° N.

Key words: calcareous nannofossils, diatom fossils, upwelling, California Current System, PDO-like, Middle Pleistocene Transition

CLC Number:

SU Xin, CHEN Fang, YU Chonghan, GUO Ce. A PDO-like record documented by microfossils from the northern region of the California Current System since the Early Pleistocene[J]. Earth Science Frontiers, 2020, 27(6): 128-143.

Figures/Tables 7

References 88

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ODP钻孔	位置 (水深/m)	岩心深度/m		岩性单元	主要岩性
ODP钻孔	位置 (水深/m)	顶部	底部	岩性单元	主要岩性
1020B	41°0.051'N	0	121.8	IA	灰色至浅橄榄色黏土和超微化石黏土互层
	126°26.064'W	121.8	228.5	IB	浅灰橄榄色至深灰色黏土和硅藻黏土
	(3 038.4)	228.5	278.8	II	浅黄灰至橄榄灰色超微化石软泥与浅灰橄榄色超微化石黏土厚层互层
1245B	44°35.1587'N	0	31.5	I	深绿灰色含钙质超微化石黏土和粉砂质黏土
	125°8.9455'W	31.5	76.0	II	深绿灰色含硅藻黏土和粉砂质黏土,与细砂互层
	(869.7)	76.0	183.0	IIIA	深绿灰色富含超微化石、富含硅藻黏土以及粉砂质黏土,与粉砂互层
		183.0	212.7	IIIB	深绿灰色粉砂质黏土和富含超微化石粉砂质黏土,与粉砂互层
		212.7	320.0	IVA	深绿灰色至深灰色富含生物组分的粉砂质泥岩
		320.0	419.3	IVB	深绿灰色至深灰色泥岩和粉砂质泥岩
		419.3	472.9	V	深绿灰色泥岩和粉砂质泥岩

ODP钻孔	位置 (水深/m)	岩心深度/m		岩性单元	主要岩性
ODP钻孔	位置 (水深/m)	顶部	底部	岩性单元	主要岩性
1020B	41°0.051'N	0	121.8	IA	灰色至浅橄榄色黏土和超微化石黏土互层
	126°26.064'W	121.8	228.5	IB	浅灰橄榄色至深灰色黏土和硅藻黏土
	(3 038.4)	228.5	278.8	II	浅黄灰至橄榄灰色超微化石软泥与浅灰橄榄色超微化石黏土厚层互层
1245B	44°35.1587'N	0	31.5	I	深绿灰色含钙质超微化石黏土和粉砂质黏土
	125°8.9455'W	31.5	76.0	II	深绿灰色含硅藻黏土和粉砂质黏土,与细砂互层
	(869.7)	76.0	183.0	IIIA	深绿灰色富含超微化石、富含硅藻黏土以及粉砂质黏土,与粉砂互层
		183.0	212.7	IIIB	深绿灰色粉砂质黏土和富含超微化石粉砂质黏土,与粉砂互层
		212.7	320.0	IVA	深绿灰色至深灰色富含生物组分的粉砂质泥岩
		320.0	419.3	IVB	深绿灰色至深灰色泥岩和粉砂质泥岩
		419.3	472.9	V	深绿灰色泥岩和粉砂质泥岩

年龄/Ma	生物或古地磁事件	平均深度/mcd	备注
0.44	T Pseudoemiliania lacunosa	51.30	钙质超微化石
0.773	B Brunhes	84.83	古地磁
1.008	T Jaramillo	100.68	古地磁
1.076	B Jaramillo	108.81	古地磁
1.24	T large Gephyrocapsa spp.	125.01	钙质超微化石
1.62	B large Gephyrocapsa spp.	144.69	钙质超微化石

年龄/Ma	生物或古地磁事件	平均深度/mcd	备注
0.44	T Pseudoemiliania lacunosa	51.30	钙质超微化石
0.773	B Brunhes	84.83	古地磁
1.008	T Jaramillo	100.68	古地磁
1.076	B Jaramillo	108.81	古地磁
1.24	T large Gephyrocapsa spp.	125.01	钙质超微化石
1.62	B large Gephyrocapsa spp.	144.69	钙质超微化石

年龄/Ma	生物事件	平均深度/mbsf	备注
0.29	FO Emiliania huxleyi	60.96	钙质超微化石
0.44	LO Pseudoemiliania lacunosa	80.47	钙质超微化石
1.02	LO small Gephyrocapsa spp.Acme	150.77	钙质超微化石
1.24	FO small Gephyrocapsa spp.Acme	276.13	钙质超微化石
1.60	FO Calcidiscus macintyrei	517.52	钙质超微化石