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Abstract

The morphometry of sedimentary charcoal particles illuminates the source fuel types. This study explores the variation in morphometry (specifically, the length-to-width (L/W) ratio) of charcoal particles of different sizes, using charcoal collected from Miscanthus sinensis (Japanese pampas grass) fields following controlled burning. We also investigated the impact of pretreatment processes on sedimentary microcharcoals. The results indicate a general decrease in the L/W ratio with decreasing particle size, with the microcharcoal exhibiting a substantial decrease. The mean L/W ratios for size categories of 250 µm–1 mm, 125–250 µm, 63–125 µm, and <63 μm in size are 6.42, 5.54, 4.94, and 3.45, respectively. Furthermore, pretreatment processes for microcharcoal decrease the L/W ratio. Consequently, the L/W ratio of grass microcharcoal (<125 μm) likely falls within 50–80% of the ratios observed in grass macrocharcoal (>125 μm), necessitating caution in interpreting microcharcoal data. Our findings emphasize the importance of considering particle size and pretreatment effects when interpreting paleofire records and highlight the need for further research to establish robust cutoff values for fuel type inference based on charcoal morphometry, particularly for microcharcoal.

Keywords

charcoal morphology fire history fuel type grass length-to-width ratio sedimentary charcoal

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References

Clark

(1984) Effects on charcoal of pollen preparation procedures. Pollen et Spores 26(3–4): 559–576.

Crawford

Belcher

(2014) Charcoal morphometry for paleoecological analysis: The effects of fuel type and transportation on morphological parameters. Applications in Plant Sciences 2(8): 1400004.

Daniau

A-L

Loutre

M-F

Swingedouw

, et al. (2023) Precession and obliquity forcing of the South African monsoon revealed by sub-tropical fires. Quaternary Science Reviews 310: 108128.

Daniau

A-L

Sánchez-Goñi

Beaufort

, et al. (2007) Dansgaard–Oeschger climatic variability revealed by fire emissions in southwestern Iberia. Quaternary Science Reviews 26(9–10): 1369–1383.

Daniau

Sánchez Goñi

Martinez

, et al. (2013) Orbital-scale climate forcing of grassland burning in southern Africa. Proceedings of the National Academy of Sciences of the United States of America 110(13): 5069–5073.

Daniau

A-

Bartlein

Harrison

, et al. (2012) Predictability of biomass burning in response to climate changes. Global Biogeochemical Cycles 26(4): GB4007.

Enache

Cumming

(2006) Tracking recorded fires using charcoal morphology from the sedimentary sequence of Prosser Lake, British Columbia (Canada). Quaternary Research 65(02): 282–292.

Feurdean

(2021) Experimental production of charcoal morphologies to discriminate fuel source and fire type: An example from Siberian taiga. Biogeosciences Discussions 18(12): 3805–3821.

Feurdean

Vachula

Hanganu

, et al. (2023) Charcoal morphologies and morphometrics of a Eurasian grass-dominated system for robust interpretation of past fuel and fire type. Biogeosciences 20(24): 5069–5085.

10.

Frank-DePue

Vachula

Balascio

, et al. (2023) Trends in sedimentary charcoal shapes correspond with broad-scale land-use changes: Insights gained from a 300-year lake sediment record from eastern Virginia, USA. Journal of Paleolimnology 69(1): 21–36.

11.

Haliuc

Daniau

A-L

Mouillot

, et al. (2023) Microscopic charcoals in ocean sediments off Africa track past fire intensity from the continent. Communications Earth & Environment 4(1): 133.

12.

Harrison

Villegas-Diaz

Cruz-Silva

, et al. (2022) The reading palaeofire database: An expanded global resource to document changes in fire regimes from sedimentary charcoal records. Earth System Science Data Discussions 14(3): 1109–1124.

13.

Herrmann

Berking

, et al. (2010) Reconstructing Holocene vegetation and climate history of Nam Co area (Tibet), using pollen and other palynomorphs. Quaternary International 218(1-2): 45–57.

14.

Inoue

Okuyama

Hayashi

, et al. (2021) Postglacial anthropogenic fires related to cultural changes in central Japan, inferred from sedimentary charcoal records spanning glacial–interglacial cycles. Journal of Quaternary Science 36(4): 628–637.

15.

Inoue

Okuyama

Takemura

(2018) Long-term fire activity under the East Asian monsoon responding to spring insolation, vegetation type, global climate, and human impact inferred from charcoal records in Lake Biwa sediments in central Japan. Quaternary Science Reviews 179: 59–68.

16.

Inoue

Yoshie

Tanaka

, et al. (2017) Disappearance and alteration process of charcoal fragments in cumulative soils studied using Raman spectroscopy. Geoderma 285: 164–172.

17.

Jensen

Lynch

Calcote

, et al. (2007) Interpretation of charcoal morphotypes in sediments from Ferry Lake, Wisconsin, USA: Do different plant fuel sources produce distinctive charcoal morphotypes? Holocene 17(7): 907–915.

18.

Miao

Song

, et al. (2020) Late Pleistocene fire in the Ili Basin, Central Asia, and its potential links to paleoclimate change and human activities. Palaeogeography Palaeoclimatology Palaeoecology 547: 109700.

19.

Miao

Warny

, et al. (2019) Miocene fire intensification linked to continuous aridification on the Tibetan Plateau. Geology 47(4): 303–307.

20.

Mustaphi

CJC

Pisaric

MFJ

(2014) A classification for macroscopic charcoal morphologies found in Holocene lacustrine sediments. Progress in Physical Geography 38(6): 734–754.

21.

Ogden

III (1986) An alternative to exotic spore or pollen addition in quantitative microfossil studies. Canadian Journal of Earth Sciences 23(1): 102–106.

22.

Ogura

(2007) A study on the identification of original plants of minute charcoal fragments. Japanese Journal of Historical Botany 15(2): 85–95.

23.

Power

Marlon

Ortiz

, et al. (2008) Changes in fire regimes since the last glacial maximum: an assessment based on a global synthesis and analysis of charcoal data. Climate Dynamics 30(7–8): 887–907.

24.

Snitker

(2020) The charcoal quantification tool (CharTool): A suite of open-source tools for quantifying charcoal fragments and sediment properties in archaeological and paleoecological analysis. Ethnobiology Letters 11(1): 103–115.

25.

Thevenon

Williamson

Vincens

, et al. (2003) A late-Holocene charcoal record from Lake Masoko, SW Tanzania: Climatic and anthropologic implications. Holocene 13(5): 785–792.

26.

Umbanhowar

Mcgrath

(1998) Experimental production and analysis of microscopic charcoal from wood, leaves and grasses. Holocene 8(3): 341–346.

27.

Vachula

(2019) A usage-based size classification scheme for sedimentary charcoal. Holocene 29(3): 523–527.

28.

Vachula

Sae-Lim

(2021) A critical appraisal of charcoal morphometry as a paleofire fuel type proxy. Quaternary Science Reviews 262: 106979.

29.

Zhang

Lü

(2006) Preliminary study of charcoal morphology and its environmental significance. Quaternary Sciences 26(5): 857–863.

30.

Zhou

Hui

Vachula

, et al. (2023) Mid-Miocene palaeofire and its complex relationship with vegetation changes in the Wushan Basin, northeastern Tibetan Plateau, China: Evidence from a high-resolution charcoal record. Paleoceanography and Paleoclimatology 38(4): e2022PA004461.

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Effects of particle size and pretreatment methods on the morphometry of grass charcoal particles: Implications for morphometric analysis of microcharcoal particles

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