Jump to content

Geology of the Pearl River Delta

From Wikipedia, the free encyclopedia
Pearl River Delta
Stratigraphic range: Neoproterozoic to Cenozoic
Fig.1 Map showing the location and relief of Pearl River Delta
TypeGeological formation (delta)
Location
Coordinates21°20’–23°30’N and 112°40’–114°50’E[1]
RegionSub-tropical area
ExtentEast Asia
Type section
CountryChina

The geology of the Pearl River Delta is rock sequences plus superficial sediments, emplaced in an alluvial delta, occupying the Pearl River Estuary. The unconsolidated sediments which dominate the delta are largely derived from continental materials exposed across the Pearl River basin, and range in size from fine particles such as mud to larger fragments like gravel. These deltaic materials have been deposited for 9000 years atop the bedrock at the mouth of the Pearl River in Guangdong Province, situated along the northern margin of the South China Sea.[1]

This landform, replete with an intricate network of river channels, has been evolving since the Early Holocene era, shaping the contemporary delta landscape observed today.[2] During this period, cyclical variations in sea level, known as regression and transgression, have occurred.[3] As a result, space has been created for the deposition of sediments carried by the Pearl River.[3] The Quaternary geological sequence, which overlays the bedrock, exemplifies this cycle. It comprises marine units, primarily constituted by silt and clay, as well as continental units, dominated by sand and gravel.[4] The bedrock underlying the delta exhibits complexity due to varying deformation and intrusion events prompted by significant tectonic activities.[5][6] The ongoing evolution of the delta is principally influenced by neo-tectonic movements, fluvial processes, fluctuations in sea level, and human activities.[1] These elements collectively exert a significant impact on the dynamic development and transformation of the delta.

Geomorphology

[edit]
Fig.2 False colour map of Pearl River Delta, highlighting the morphology and distribution of the river channel

The Pearl River Delta, typically flat and low-lying, has a maximum elevation of 10 meters above sea level, a characteristic feature of deltaic formations.[4] The delta's formation is largely attributed to the deposition of sediment transported by its three main sub-rivers: the East River, the North River, and Xi Jiang, which collectively flow into the Pearl River Estuary.[2] Despite its predominantly low relief, the delta plain, which spans approximately 9750 km², is interspersed with over 160 islands in varied forms such as hills and monadnocks, with elevations ranging from 100 to 300 meters.[7] These rocky islands comprise about one fifth of the delta's total area (~2000 km²).[7] This unique geomorphological feature is the result of a combination of fault block activities and diverse bedrock.

Fig.3 Map of the drainage basin of Pearl River. Showing how the tributaries connect to the main river

The Pearl River Delta represents a complex deltaic system. Unlike the Mississippi River Delta, a textbook example of river delta, it does not neatly fit into William Galloway’s triangular delta classification, which categorizes deltas into three types: river-dominated, wave-dominated, and tide-dominated.[8] The Pearl River Delta is influenced both by tidal and wave processes, with certain parts dominated by fluvial processes.[8] Due to the presence of bedrock islands in the estuary area and the main river being constrained by the steep relief surrounding the deltaic region, the main channel's course has remained relatively stable, preventing the formation of deltaic lobes akin to those in the Mississippi River Delta. Consequently, the deltaic plains are concentrated in the current delta area.[8]

Geological setting

[edit]
Fig.4 Showing the location of Block and pushing direction from the two plates[9]

The Pearl River Delta is situated on the southern edge of the Cathaysia Block, one of the key crustal blocks in southeastern China.[10][11] This region is situated on the Eurasian tectonic plate, abutting the oceanic crust along the margins of the South China Sea.[2] While it is located at the edge of a passive continental margin, the delta experiences a primary tectonic stress field in the north–south direction due to the compressional motion of the Indian Ocean Plate and the Philippine Sea Plate from various directions.[2][12]

The stress field within the Pearl River Delta stimulates the activity of the area's faults, considerably influencing the delta's evolution. The consequent movement and behavior of these faults are key determinants in the continuous development and transformation of this geologically dynamic region. As a result, the behavior of faults and the differential movements of associated fault blocks primarily dictate the neotectonic features in this region, where substantial seismic activity is an occasional phenomenon.[12]

Geological structure

[edit]
Fig.5 Showing the location of fault and fault block. The names of the faults and the fault blocks can be looked up in the table below according to their numbers[2]

The geological structures of the Pearl River Delta are primarily fault-dominated. Fold structures are relatively scarce in this region, with the nearest large-scale fold structure, the Nanling-Wuyi fold belt, situated significantly distant from the delta.[13]

The fault systems in the deltaic region comprise three main sets, including normal, reverse, and strike-slip faults.[2] These faults, which emerged in varying time periods, are categorized based on their trending directions: NE-SW, NW-SE, and W-E.[4] Many of these faults have significantly contributed to the local geomorphological development.[12] Particularly, the first set of faults, which largely shape the morphology of the coastline and the Pearl River Delta.[4] The Shenzhen fault is a key lineament following this trend.[4]

The interaction of these three sets of faults has resulted in the formation of multiple fault blocks that have experienced differential subsidence.[2] These formed fault blocks are crucial in determining the delta's evolution. The rate of sedimentation and the development of river channels in the delta are greatly influenced by the subsidence rate and spatial distribution of these fault blocks.[12] Increased subsidence rates often lead to an enhanced sedimentation rate, resulting in thicker sediment deposition.[12] Additionally, fault zones' susceptibility to weathering and erosion has created weak zones in the basement topography, guiding the development of the main river channels in the delta.[12] The accommodation space for Quaternary deposits was predominantly created by such neotectonic activity.[12]

To illustrate the importance of such fault sets, seven fault blocks created by thirteen faults around the main delta are selected. They include:[2]

Fault[2] Fault type[2] Fault sets History Fault Block[2] Note
1. Sanshui–Luofushan Fault Normal fault W-E The Yanshanian Movement in the Cretaceous period was responsible for the formation of the faults. These structures underwent several periods of reactivation in subsequent geological processes.[12] N/A N/A
2. Guangzhou–Conghua Fault Normal fault NE-SW (I) Dongjiang Delta fault block, (II) Tan Hoi fault block, (III) Wuguishan fault block, (IV) Shiqiao–Guangzhou fault block(I) and (VII) South China Sea fault block
  • Strong activities of the fault block
  • Center of deposition[12]
  • Well preserved in the rock records and can be seen from field evidence.
3. Dongguan–Houjie Fault Strike-slip fault
4. Shiqiao-Xinhui Fault Strike-slip fault
5. Wuguishan Fault Strike-slip falut
6. Shenzhen–Zhuhai Fault Strike-slip falut
7. Pearl River Estuary Fault Strike-slip falut
8. Xijiang Fault Normal fault NW-SE The Himalayan Movement, which took place during the Oligocene-Pliocene epochs, was instrumental in the formation of such fault structures.[12] (V) Xijiang–Beijiang Delta fault block and (VI) Pearl River estuary fault block and
  • Weak activities of the fault block
9. Baini–Shawan Fault Reverse fault
10. Nangang–Humen Fault Strike-slip falut
11. Hualong–Huangge Fault Normal fault
12. Yamen Fault Strike-slip fault

Stratigraphy

[edit]
Fig.6 Stratigraphy of PRD.[4] The units contain different kinds of rock that formed in distinct time period.

The bedrock in the Pearl River Delta consist of some very old rock dated back to Precambrian and are complex in nature.[5][6] This is product of metamorphism and magmatic intrusion experienced by the sedimentary bedrock in the Pearl River Delta caused by several major tectonic events.[1][14] The stratigraphic sequence in Pearl River Delta mainly consisted of a Neo-Proterozoic meta-sedimentary basement unit with a overlying discontinuous rock records from Paleozoic to Mesozoic composed of terrigenous sedimentary rock interbedded with some carbonate unit.[15] The volcanic and intrusive events occurred during the Upper Mesozoic to Tertiary formed granites intruded in these layers of rock and, tuff formed on top of them.[15]At the top, Quaternary deposits consisted of two continental units and two marine units filled the depressed area in the region.[4] This complex stratigraphy is grouped into nine rock units:[4][16]

Rock units in Pearl River Delta
Periods Unit name Dominant rock types Environment Note
Quaternary 1. Quaternary unit Loose deposits with a wide range of clast but with a majority of sand and silty sand Delta Length of the bed is 20-60m
Cretaceous to Tertiary 2. Mesozoic to Tertiary reworked tuff and alluvial unit Reworked tuff breccia and conglomerate, interbedded with sandstone and shale Lake, river and alluvial fan A sharp angular unconformity and red bed sedimentation
Jurassic to Cretaceous 3. Upper Mesozoic volcanic unit Rhyo-porphyry, dacite Porphyry, quartz conglomerate, volcanic breccia, interbedded with layers of tuff, sandstone, shale, and siltstone Volcanic arc Ash tuff in Hong Kong
Jurassic to Cretaceous 4. Upper Mesozoic intrusion unit Granite, diorite and monzonite Volcanic arc Granite and rhyolite of calc-alkaline to high-K calc-alkaline series, the Luofushan pluton
Triassic to Jurassic 5. Mesozoic terrigenous unit Siltstone and shale interbedded with sandstone layer Lake N/A
Carboniferous to Permian 6. Paleozoic terrigenous unit Quartz sandstone with siltstone, marls, fine sandstone and conglomerate Lake, river and alluvial fan N/A
Carboniferous to Permian 7. Paleozoic carbonate unit Limestone, dolostone and carbonate marls Shallow marine N/A
Devonian 8. Paleozoic terrigenous clastic unit Conglomerate, quartz conglomerate, quartz sandstone and quartite Lake, river and alluvial fan N/A
Silurian to Ediacaran 9. Basement unit Slate, siliceous shales, graptolites shales, graptolite shales with layer of sandstone. And metamorphic facies as phyllite, schist and gneiss Deep marine N/A

Geological history

[edit]

The Geological history of Pearl River Delta spans across 600 million years and can be divided into five main periods: the pre-Cretaceous period, the Cretaceous period, the Tertiary period, the Quaternary period, and the recent Holocene epoch.

Paleozoic and Neoproterozoic Era

[edit]

In the Ediacaran period, approximately 600 million years ago, the region of the Pearl River Delta was characterized by a structurally depressed area within a deep marine environment.[4][5] It is theorized that this region constituted an oceanic basin during that period, fostering a depositional environment that facilitated the formation of bioclastic and clastic sedimentary rock.[4][17] In the Paleozoic eon, around 540 million years ago, the depositional environment underwent significant changes. The sedimentary facies formed during this period were markedly different from the Ediacaran bedrock, including notable examples such as shallow marine facies and terrigenous facies.[4]

Mesozoic Era

[edit]
Fig.7 Conceptual block diagram showing how the subduction of the Paleo-Pacific Plate triggered the magmatic intrusion which formed the Mesozoic Magmatic Belt[18]

The Mesozoic era, which began approximately 252 million years ago, was characterized by a primarily lacustrine environment consisting of terrestrial shale interbedded with sandstone.[4] This sedimentation process persisted until substantial tectonic activities ushered in multiple phases of faulting and magmatic intrusion. From the Jurassic to the Cretaceous period, the westward subducting paleo-Pacific Plate triggered the Yanshanian movement which led to the intrusion of granitic magma.[2][13] The regional fault zones guided the intrusive motion of the magma, leading to the formation of the Mesozoic Magmatic Belt in the SE China from the existed large scale NE-SW fault zones.[19] The granites and tuff, which are widely distributed in Hong Kong and the southeastern and eastern areas of the Pearl River Delta, are representative of this magmatic belt.[10] These tectonic and magmatic events induced the deformation of the Ediacaran bedrock through contact and regional metamorphism, transforming it into metasedimentary rock.[20] This period also saw the rapid development of fault block mountains and fault basins.[21] The effects of weathering and erosion led to the formation of hills and mountains from the fault blocks.[2] The weathered material from these mountains was transported and deposited in the fault basins.[2] Consequently, the evolving basin preserved the records of marine transgression and volcanic activity by retaining the land and marine strata from the late Mesozoic to the early Tertiary period.[2] The Himalayan movement, initiated by the collision of India with Asia since the middle Tertiary, uplifted the delta basin through rapid crustal modifications.[22] This uplift facilitated erosion and incision, but the eroded material was not deposited in the Pearl River Delta. Instead, it was transported more than 200 km away from the delta area.[22]

Cenozoic Era

[edit]

Throughout the Tertiary and Quaternary periods, the uplift of the Tibetan Plateau significantly altered the topography, which in turn modified the drainage pattern and led to the formation of the Pearl River drainage basin.[2] This geological event also initiated the rifting of several delta basins due to the movement of fault blocks, resulting in an overall subsidence of the basin adjacent to the estuary in the Late Quaternary.[2] The subsidence of the deltaic region during the Late Quaternary created ample accommodation space, prompting a new phase of deposition and halting the bypassing of sediment to the adjacent continental shelf in the South China Sea.[23][24] The interplay of repeated sea-level changes and subsidence from fault block movements fostered the formation of two deltas at different times. As a result, two stratigraphic sequences were formed, each featuring a combination of terrestrial and marine sedimentary layers.[24] These sequences rest atop sedimentary rocks that date back to the Cenozoic and Mesozoic periods, and are also underlain by Mesozoic igneous rocks.[25]

  • The older sequence of the deltaic deposits traces back to the first cycle of marine regression and transgression during the last interglacial period, which occurred between 130,000 and 115,000 years ago.[24]
  • The more recent sequence of the deltaic deposits pertains to the second cycle of marine regression and transgression. This cycle has been ongoing during the current interglacial period, which spans from 11,500 years ago to the present day.[3]

Evolutionary model in the Holocene

[edit]

The modern configuration of the Pearl River Delta emerged during the second marine transgression, which took place approximately 7500 years ago.[3] To elucidate the factors driving the evolution of the present delta, a three-stage evolutionary model has been proposed.[3]

Fig.8 Showing the sea level change and location of delta plain through time. Figure A-C show the sea level change in stage 1. Figure D-E show the sea level change in stage 2. Figure F show the current shoreline.[26]

Stage 1 (9000–6800 years ago)

[edit]
Fig.9 Schematic cross-section for the Pearl River deltaic sequences showing the sequence is retrograding with a rising sea level during 9000–6800 years ago

The swift environmental changes during the early Holocene were primarily driven by a rapid increase in sea level and, secondarily, by strong monsoon runoff.[3] The interaction of these two factors resulted in the flooding of the deltaic basin by seawater, which led to a shift in sedimentation facies from fine sand to silt and clay.[3] This stage was characterized by a transition from shallow to deep tidal processes in the receiving basin.[3] Subsequently, a transgression phase commenced around 8000 years ago, which after approximately 1200 years (around 6800 years ago) transitioned into a regression phase.[27]

Stage 2 (6800-2000 years ago)

[edit]
Fig.10 Schematic cross-section for the Pearl River deltaic sequences showing the sequence is prograding with a dropping sea level 4000 years ago, while the sequence is aggradating with a more stable sea level 2000 years ago

During the subsequent stage, tides and monsoonal discharge became the dominant mechanisms as the sea level began to stabilize.[3] These factors spurred the delta's growth until approximately 6000 years ago, a process driven by the continuous weakening of the summer monsoon.[3] From this point onwards, the delta front facies transitioned to become the primary sedimentary facies, which allowed for the modification of sediments by tidal action.[28]

Stages 3 (2000 years ago-present)

[edit]
Fig.11 Schematic cross-section for the Pearl River deltaic sequences showing the sequence in the present environment

As the impact of the monsoonal discharge continued to weaken and human activities increased, these human activities became a significant factor during this stage.[3] Despite an increase in sediment supply due to deforestation, most sediments were trapped in reclaimed land or tidal flats.[29] A decrease in the rate of vertical accretion was noted, likely due to a reduction in the amount of sediment reaching the estuary.[3] This could be attributed to a rapid advancement of the shoreline caused by swift land reclamation.[3]

This model reveals a continuous advancement of the Pearl River Delta's shoreline, a trend driven by increased human activities and decreased influences of natural factors such as sea-level changes and monsoonal discharges.

Current geological issues

[edit]

The Pearl River Delta faces two significant geological issues: pollution and subsidence.

Water pollution

[edit]

The primary sources of contamination are chemical spillages, unauthorized factory discharges, and urban water-logging.[4] These human activities significantly impact the dynamics of groundwater, rendering the confined aquifer increasingly susceptible to pollution.[4] As a result, it is advised to abstain from exploiting deep confined aquifers if shallow aquifers are already polluted.[4] To safeguard the crucial groundwater resources around the Pearl River Delta, implementing best practices such as the construction of more efficient water treatment plants and irrigation with clean water are recommended.

Land subsidence

[edit]

Subsidence represents the second significant issue experienced in the Pearl River Delta. Although surface subsidence is a natural part of the geological evolution of the area, human activities within the deltaic region have accelerated this process.[30] The extent of this acceleration can be quantified through InSAR (Interferometric Synthetic Aperture Radar), a remote sensing technology. According to InSAR data, an average subsidence velocity of 5 cm/year was observed in some regions, a rate significantly higher than those reported in earlier studies.[30]

See also

[edit]

References

[edit]
  1. ^ a b c d Ren, Dong-Jie; Shen, Shui-Long; Cheng, Wen-Chieh; Zhang, Ning; Wang, Zhi-Feng (2016-05-26). "Geological formation and geo-hazards during subway construction in Guangzhou". Environmental Earth Sciences. 75 (11): 934. Bibcode:2016EES....75..934R. doi:10.1007/s12665-016-5710-6. ISSN 1866-6280.
  2. ^ a b c d e f g h i j k l m n o p q Zhang, Yuanzhi; Huang, Zhaojun; Li, Yu; Yu, Qing; Jiang, Bing Wang and Tingchen (2016-09-14), "Neo-tectonic Movement in the Pearl River Delta (PRD) Region of China and Its Effects on the Coastal Sedimentary Environment", Applied Studies of Coastal and Marine Environments, IntechOpen, doi:10.5772/61981, ISBN 978-953-51-2549-5, retrieved 2023-10-09
  3. ^ a b c d e f g h i j k l m Zong, Y.; Huang, G.; Switzer, A.D.; Yu, F.; Yim, W.W.-S. (January 2009). "An evolutionary model for the Holocene formation of the Pearl River delta, China". The Holocene. 19 (1): 129–142. Bibcode:2009Holoc..19..129Z. doi:10.1177/0959683608098957. ISSN 0959-6836.
  4. ^ a b c d e f g h i j k l m n o Lancia, Michele; Su, Huang; Tian, Yong; Xu, Jintai; Andrews, Charles; Lerner, David N.; Zheng, Chunmiao (2020-12-09). "Hydrogeology of the Pearl River Delta, southern China". Journal of Maps. 16 (2): 388–395. Bibcode:2020JMaps..16..388L. doi:10.1080/17445647.2020.1761903. ISSN 1744-5647.
  5. ^ a b c Ren, Dong-Jie; Shen, Shui-Long; Cheng, Wen-Chieh; Zhang, Ning; Wang, Zhi-Feng (2016-05-26). "Geological formation and geo-hazards during subway construction in Guangzhou". Environmental Earth Sciences. 75 (11): 934. Bibcode:2016EES....75..934R. doi:10.1007/s12665-016-5710-6. ISSN 1866-6280.
  6. ^ a b Darbyshire, D.P.F.; Sewell, R.J. (November 1997). "Nd and Sr isotope geochemistry of plutonic rocks from Hong Kong: implications for granite petrogenesis, regional structure and crustal evolution". Chemical Geology. 143 (1–2): 81–93. Bibcode:1997ChGeo.143...81D. doi:10.1016/s0009-2541(97)00101-0. ISSN 0009-2541.
  7. ^ a b Huang, Z.; Li, P.; Zhang, Z.; Li, K. (1987). "The geomorphological evolution of the Pearl River Delta. In: Gardiner, V". International Geomorphology 1986 Part I: 989–997.
  8. ^ a b c Li, Chunchu; Lei, Yaping; He, Wei; Dai, Zhijun (August 2001). "Land-ocean interaction in modern delta formation and development: A case study of the Pearl River delta, China". Science in China Series B: Chemistry. 44 (S1): 63–71. doi:10.1007/bf02884810. ISSN 1006-9291.
  9. ^ Xu, Chuang; Wang, Hai-hong; Luo, Zhi-cai; Ning, Jin-sheng; Liu, Hua-liang (March 2015). "Multilayer stress from gravity and its tectonic implications in urban active fault zone: A case study in Shenzhen, South China". Journal of Applied Geophysics. 114: 174–182. Bibcode:2015JAG...114..174X. doi:10.1016/j.jappgeo.2015.01.017. ISSN 0926-9851.
  10. ^ a b Shaw, R.; Tang, D. L.K.; Owen, R. B.; Sewell, R. J. (January 2010). "The Geological History of Hong Kong". Asian Geographer. 27 (1–2): 43–57. doi:10.1080/10225706.2010.9684152. ISSN 1022-5706.
  11. ^ Zhang, GuoWei; Guo, AnLin; Wang, YueJun; Li, SanZhong; Dong, YunPeng; Liu, ShaoFeng; He, DengFa; Cheng, ShunYou; Lu, RuKui; Yao, AnPing (November 2013). "Tectonics of South China continent and its implications". Science China Earth Sciences. 56 (11): 1804–1828. Bibcode:2013ScChD..56.1804Z. doi:10.1007/s11430-013-4679-1. ISSN 1674-7313.
  12. ^ a b c d e f g h i j Y., Yantao; Z., Wenhuan; L., Zaifeng; Z., Zhiqiang; Z., Meizhen; J., Sun (2013). "Neotectonics and its Relations to the Evolution of the Pearl River Delta, Guangdong, China". Journal of Coastal Research. 66 (1).
  13. ^ a b Zhang, Zhe-Kun; Ling, Ming-Xing; Lin, Wei; Sun, Ming; Sun, Weidong (March 2021). "Corrigendum to "Yanshanian movementˮ induced by the westward subduction of the paleo–Pacific plate [Solid Earth Sciences Volume 5 (2) (2020) 103–114]". Solid Earth Sciences. 6 (1): 55. Bibcode:2021SolES...6...55Z. doi:10.1016/j.sesci.2021.01.001. ISSN 2451-912X.
  14. ^ Zhu, Rixiang; Xu, Yigang (2019-05-07). "The subduction of the west Pacific plate and the destruction of the North China Craton". Science China Earth Sciences. 62 (9): 1340–1350. Bibcode:2019ScChD..62.1340Z. doi:10.1007/s11430-018-9356-y. ISSN 1674-7313.
  15. ^ a b Darbyshire, D.P.F.; Sewell, R.J. (November 1997). "Nd and Sr isotope geochemistry of plutonic rocks from Hong Kong: implications for granite petrogenesis, regional structure and crustal evolution". Chemical Geology. 143 (1–2): 81–93. Bibcode:1997ChGeo.143...81D. doi:10.1016/s0009-2541(97)00101-0. ISSN 0009-2541.
  16. ^ Shen, Wenlue. Post-orogenic extension in the Pearl River Delta region (South China) : an integrated morphological, structural, geophysical and thermochronological study (Thesis). The University of Hong Kong Libraries. doi:10.5353/th_b3955858 (inactive 1 November 2024).{{cite thesis}}: CS1 maint: DOI inactive as of November 2024 (link)
  17. ^ Zhang, Feifei; Xiao, Shuhai; Kendall, Brian; Romaniello, Stephen J.; Cui, Huan; Meyer, Mike; Gilleaudeau, Geoffrey J.; Kaufman, Alan J.; Anbar, Ariel D. (June 2018). "Extensive marine anoxia during the terminal Ediacaran Period". Science Advances. 4 (6): eaan8983. Bibcode:2018SciA....4.8983Z. doi:10.1126/sciadv.aan8983. ISSN 2375-2548. PMC 6010336. PMID 29938217.
  18. ^ Huang, Haibo; Xiong, Hou; Qiu, Xuelin; Li, Yuhan (March 2020). "Crustal structure and magmatic evolution in the Pearl River Delta of the Cathaysia Block: New constraints from receiver function modeling". Tectonophysics. 778: 228365. Bibcode:2020Tectp.77828365H. doi:10.1016/j.tecto.2020.228365. ISSN 0040-1951.
  19. ^ Xia, Shaohong; Zhao, Dapeng (December 2014). "Late Mesozoic magmatic plumbing system in the onshore–offshore area of Hong Kong: Insight from 3-D active-source seismic tomography". Journal of Asian Earth Sciences. 96: 46–58. Bibcode:2014JAESc..96...46X. doi:10.1016/j.jseaes.2014.08.038. ISSN 1367-9120.
  20. ^ Ren, Dong-Jie; Shen, Shui-Long; Cheng, Wen-Chieh; Zhang, Ning; Wang, Zhi-Feng (2016-05-26). "Geological formation and geo-hazards during subway construction in Guangzhou". Environmental Earth Sciences. 75 (11): 934. Bibcode:2016EES....75..934R. doi:10.1007/s12665-016-5710-6. ISSN 1866-6280.
  21. ^ Zhang, H. (1980). "Fault-block delta". Journal of Geography (in Chinese). 1: 18–30.
  22. ^ a b Chen, G.N.; Zhang, K.; Li, K.F.; Shao, R.S.; Zhuang, W.M. "Development of the Pearl River Delta in SE china and its relations to reactivation of basement faults". Journal of Geosciences of China. 14 (1): 17–24.
  23. ^ Huang, Y.; Xia, F.; Chen, G. "The fault controlling function in the formation of the Pearl River Delta". Journal of Oceanography (in Chinese). 5 (3): 316–327.
  24. ^ a b c Zong, Y.; Yim, W.W.-S.; Yu, F.; Huang, G. (September 2009). "Late Quaternary environmental changes in the Pearl River mouth region, China". Quaternary International. 206 (1–2): 35–45. Bibcode:2009QuInt.206...35Z. doi:10.1016/j.quaint.2008.10.012. ISSN 1040-6182.
  25. ^ Zhang, K.; Chen, G.; Zhuang, W.; Peng, Z.; Hou, W. "New evidences for late Quaternary tectonic movement in the northern Pearl River Delta". South China Journal of Seismology (in Chinese). 29: 22–26.
  26. ^ Wei, Xing; Wu, Chaoyu; Ni, Peitong; Mo, Wenyuan (May 2016). "Holocene delta evolution and sediment flux of the Pearl River, southern China". Journal of Quaternary Science. 31 (5): 484–494. Bibcode:2016JQS....31..484W. doi:10.1002/jqs.2873. ISSN 0267-8179.
  27. ^ Stanley, Daniel Jean; Warne, Andrew G. (1994-07-08). "Worldwide Initiation of Holocene Marine Deltas by Deceleration of Sea-Level Rise". Science. 265 (5169): 228–231. Bibcode:1994Sci...265..228S. doi:10.1126/science.265.5169.228. ISSN 0036-8075. PMID 17750665.
  28. ^ Wu, C.Y.; Ren, J.; Bao, Y.; Lei, Y.P.; Shi, H.Y. (2007), "A long-term morphological modeling study on the evolution of the Pearl River Delta, network system, and estuarine bays since 6000 yr B.P.", Coastline Changes: Interrelation of Climate and Geological Processes, Geological Society of America, doi:10.1130/2007.2426(14), ISBN 9780813724263, retrieved 2023-10-09
  29. ^ Zhang, Shurong; Lu, Xi Xi; Higgitt, David L.; Chen, Chen-Tung Arthur; Han, Jingtai; Sun, Huiguo (February 2008). "Recent changes of water discharge and sediment load in the Zhujiang (Pearl River) Basin, China". Global and Planetary Change. 60 (3–4): 365–380. Bibcode:2008GPC....60..365Z. doi:10.1016/j.gloplacha.2007.04.003. ISSN 0921-8181.
  30. ^ a b Li, Genger; Feng, Guangcai; Xiong, Zhiqiang; Liu, Qi; Xie, Rongan; Zhu, Xiaoling; Luo, Shuran; Du, Yanan (2020-10-30). "Surface Deformation Evolution in the Pearl River Delta between 2006 and 2011 derived from the ALOS1/PALSAR images". doi:10.21203/rs.3.rs-32256/v2. Retrieved 2023-10-09.