Natural forests exhibit higher organic carbon concentrations and recalcitrant carbon proportions in soil than plantations: a global data synthesis

doi:10.1007/s11676-024-01739-1

Abstract

Abstract:

Different chemical compositions of soil organic carbon (SOC) affect its persistence and whether it significantly differs between natural forests and plantations remains unclear. By synthesizing 234 observations of SOC chemical compositions, we evaluated global patterns of concentration, individual chemical composition (alkyl C, O-alkyl C, aromatic C, and carbonyl C), and their distribution evenness. Our results indicate a notably higher SOC, a markedly larger proportion of recalcitrant alkyl C, and lower easily decomposed carbonyl C proportion in natural forests. However, SOC chemical compositions were appreciably more evenly distributed in plantations. Based on the assumed conceptual index of SOC chemical composition evenness, we deduced that, compared to natural forests, plantations may have higher possible resistance to SOC decomposition under disturbances. In tropical regions, SOC levels, recalcitrant SOC chemical composition, and their distributed evenness were significantly higher in natural forests, indicating that SOC has higher chemical stability and possible resistance to decomposition. Climate factors had minor effects on alkyl C in forests globally, while they notably affected SOC chemical composition in tropical forests. This could contribute to the differences in chemical compositions and their distributed evenness between plantations and natural stands.

Key words: Global data synthesis, Natural forest, Plantations, Soil organic carbon, Soil organic carbon chemical composition

Xiuqing Nie, Hui Wang, Jian Wang, Shirong Liu. Natural forests exhibit higher organic carbon concentrations and recalcitrant carbon proportions in soil than plantations: a global data synthesis[J]. JOURNAL OF FORESTRY RESEARCH, 2024, 35(1): 90-.

Xiuqing Nie, Hui Wang, Jian Wang, Shirong Liu. [J]. 林业研究(英文版), 2024, 35(1): 90-.

References 64

1	Angst G, Kögel-Knabner I, Kirfel K, Hertel D, Mueller CW. Spatial distribution and chemical composition of soil organic matter fractions in rhizosphere and non-rhizosphere soil under European beech (Fagus sylvatica L.). Geoderma, 2016, 264: 179-187, DOI
2	Baldock J, Oades J, Waters A, Peng X, Vassallo A, Wilson M. Aspects of the chemical structure of soil organic materials as revealed by solid-state ¹³C NMR spectroscopy. Biogeochemistry, 1992, 16: 1-42, DOI
3	Berg B, Meentemeyer V. Litter quality in a north European transect versus carbon storage potential. Plant Soil, 2002, 242: 83-92, DOI
4	Chen CR, Xu ZH, Mathers NJ. Soil carbon pools in adjacent natural and plantation forests of subtropical Australia. Soil Sci Soc Am J, 2004, 68: 282-291, DOI
5	Cheng L, Booker FL, Tu C, Burkey KO, Zhou LS, Shew HD, Rufty TW, Hu SJ. Arbuscular mycorrhizal fungi increase organic carbon decomposition under elevated CO₂. Science, 2012, 337: 1084-1087, DOI
6	Chiti T, Certini G, Marzaioli F, D'Acqui LP, Forte C, Castaldi S, Valentini R. Composition and turnover time of organic matter in soil fractions with different magnetic susceptibility. Geoderma, 2019, 349: 88-96, DOI
7	Condron LM, Newman RH. Chemical nature of soil organic matter under grassland and recently established forest. Eur J Soil Sci, 1998, 49: 597-603, DOI
8	Crow SE, Lajtha K, Filley TR, Swanston CW, Bowden RD, Caldwell BA. Sources of plant-derived carbon and stability of organic matter in soil: implications for global change. Glob Change Biol, 2009, 15: 2003-2019, DOI
9	Cusack DF, Halterman SM, Tanner EVJ, Wright SJ, Hockaday W, Dietterich LH, Turner BL. Decadal-scale litter manipulation alters the biochemical and physical character of tropical forest soil carbon. Soil Biol Biochem, 2018, 124: 199-209, DOI
10	Davidson EA, Janssens IA. Temperature sensitivity of soil carbon decomposition and feedbacks to climate change. Nature, 2006, 440: 165-173, DOI
11	De Marco A, Panico SC, Memoli V, Santorufo L, Zarrelli A, Barile R, Maisto G. Differences in soil carbon and nitrogen pools between afforested pine forests and natural shrublands in a Mediterranean area. Appl Soil Ecol, 2022, 170, DOI
12	Dymov AA, Zhangurov EV, Hagedorn F. Soil organic matter composition along altitudinal gradients in permafrost affected soils of the Subpolar Ural Mountains. CATENA, 2015, 131: 140-148, DOI
13	Fang XH, Zhang JC, Meng MJ, Guo XP, Wu YW, Liu X, Zhao KL, Ding LZ, Shao YF, Fu WJ. Forest-type shift and subsequent intensive management affected soil organic carbon and microbial community in southeastern China. Eur J for Res, 2017, 136: 689-697, DOI
14	Feng X, Simpson AJ, Wilson KP, Dudley Williams D, Simpson MJ. Increased cuticular carbon sequestration and lignin oxidation in response to soil warming. Nat Geosci, 2008, 1: 836-839, DOI
15	Georgiou K, Jackson RB, Vindušková O, Abramoff RZ, Ahlström A, Feng W, Harden JW, Pellegrini AFA, Polley HW, Soong JL, Riley WJ, Torn MS. Global stocks and capacity of mineral-associated soil organic carbon. Nat Commun, 2022, 13: 3797, DOI
16	Guan S, An N, Zong N, He YT, Shi PL, Zhang JJ, He NP. Climate warming impacts on soil organic carbon fractions and aggregate stability in a Tibetan alpine meadow. Soil Biol Biochem, 2018, 116: 224-236, DOI
17	Hall SJ, Ye C, Weintraub SR, Hockaday WC. Molecular trade-offs in soil organic carbon composition at continental scale. Nat Geosci, 2020, 13: 687-692, DOI
18	Hasegawa S, Marshall J, Sparrman T, Nasholm T. Decadal nitrogen addition alters chemical composition of soil organic matter in a boreal forest. Geoderma, 2021, 386, DOI
19	Hong SB, Piao SL, Chen AP, Liu YW, Liu LL, Peng SS, Sardans J, Sun Y, Peñuelas J, Zeng H. Afforestation neutralizes soil pH. Nat Commun, 2018, 9: 520, DOI
20	Hong SB, Yin GD, Piao SL, Dybzinski R, Cong N, Li XY, Wang K, Peñuelas J, Zeng H, Chen AP. Divergent responses of soil organic carbon to afforestation. Nat Sustain, 2020, 3: 694-700, DOI
21	Hua FY, Bruijnzeel LA, Meli P, Martin PA, Zhang J, Nakagawa S, Miao XR, Wang WY, McEvoy C, Peña-Arancibia JL, Brancalion PHS, Smith P, Edwards DP, Balmford A. The biodiversity and ecosystem service contributions and trade-offs of forest restoration approaches. Science, 2022, 375: 839-844, DOI
22	Huang ZQ, Xu ZH, Chen CR, Boyd S. Changes in soil carbon during the establishment of a hardwood plantation in subtropical Australia. For Ecol Manag, 2008, 254: 46-55, DOI
23	Jiménez-González MA, De la Rosa JM, Jiménez-Morillo NT, Almendros G, González-Pérez JA, Knicker H. Post-fire recovery of soil organic matter in a Cambisol from typical Mediterranean forest in Southwestern Spain. Sci Total Environ, 2016, 572: 1414-1421, DOI
24	Kallenbach C, Frey S, Grandy A. Direct evidence for microbial-derived soil organic matter formation and it ecophsiological controls. Nat Commun, 2016, 7: 13630, DOI
25	Kang HZ, Yu WJ, Dutta S, Gao HH. Soil microbial community composition and function are closely associated with soil organic matter chemistry along a latitudinal gradient. Geoderma, 2021, 383, DOI
26	Kögel-Knabner I. The macromolecular organic composition of plant and microbial residues as inputs to soil organic matter: fourteen years on. Soil Biol Biochem, 2017, 34: 139-162, DOI
27	Kögel-Knabner I, Hatcher PG, Tegelaar EW, de Leeuw JW. Aliphatic components of forest soil organic matter as determined by solid-state ¹³C NMR and analytical pyrolysis. Sci Total Environ, 1992, 113: 89-106, DOI
28	Lane N, Martin W. The energetics of genome complexity. Nature, 2010, 467: 929-934, DOI
29	Lehmann J, Kleber M. The contentious nature of soil organic matter. Nature, 2015, 528: 60-68, DOI
30	Lehmann J, Hansel CM, Kaiser C, Kleber M, Maher K, Manzoni S, Nunan N, Reichstein M, Schimel JP, Torn MS, Wieder WR, Kögel-Knabner I. Persistence of soil organic carbon caused by functional complexity. Nat Geosci, 2020, 13: 529-534, DOI
31	Lemma B, Kleja DB, Nilsson I, Olsson M. Soil carbon sequestration under different exotic tree species in the southwestern highlands of Ethiopia. Geoderma, 2006, 136: 886-898, DOI
32	Li YF, Zhang JJ, Chang SX, Jiang PK, Zhou GM, Shen ZM, Wu JS, Lin L, Wang ZS, Shen MC. Converting native shrub forests to Chinese chestnut plantations and subsequent intensive management affected soil C and N pools. For Ecol Manag, 2014, 312: 161-169, DOI
33	Liao CZ, Luo YQ, Fang CM, Chen JK, Li B. The effects of plantation practice on soil properties based on the comparison between natural and planted forests: a meta-analysis. Glob Ecol Biogeogr, 2012, 21: 318-327, DOI
34	Liu CH, Luo YQ, Chen ZL, Lian ZM. The relationship between soil animal community ecology and soil micro-ecological-environment. Ecol Environ, 2007, 16: 1564-1569, DOI
35	Lorenz K, Lal R, Preston CM, Nierop KGJ. Strengthening the soil organic carbon pool by increasing contributions from recalcitrant aliphatic bio(macro)molecules. Geoderma, 2007, 142: 1-10, DOI
37	Mathers NJ, Xu ZH. Solid-state ¹³C NMR spectroscopy: characterization of soil organic matter under two contrasting residue management regimes in a 2-year-old pine plantation of subtropical Australia. Geoderma, 2003, 114: 19-31, DOI
38	Mikutta R, Kleber M, Torn MS, Jahn R. Stabilization of soil organic matter: Association with minerals or chemical recalcitrance?. Biogeochemistry, 2006, 77: 25-56, DOI
39	Nie XQ, Wang D, Yang LC, Zhou GY. Controls on variation of soil organic carbon concentration in the shrublands of the north-eastern Tibetan Plateau. Eur J Soil Sci, 2021, 72: 1817-1830, DOI
40	Özkan U, Gökbulak F. Effect of vegetation change from forest to herbaceous vegetation cover on soil moisture and temperature regimes and soil water chemistry. CATENA, 2017, 149: 158-166, DOI
41	Pibumrung P, Gajaseni N, Popan A. Profiles of carbon stocks in forest, reforestation and agricultural land, Northern Thailand. J For Res, 2008, 19: 11-18, DOI
42	Pisani O, Frey SD, Simpson AJ, Simpson MJ. Soil warming and nitrogen deposition alter soil organic matter composition at the molecular-level. Biogeochemistry, 2015, 123: 391-409, DOI
43	Quideau SA, Chadwick OA, Benesi A, Graham RC, Anderson MA. A direct link between forest vegetation type and soil organic matter composition. Geoderma, 2001, 104: 41-60, DOI
44	R Development Core Team. R: a language and environment for statistical computing, 2016 Vienna R Foundation for Statistial Computing
45	Ramesh T, Bolan NS, Kirkham MB, Wijesekara H, Kanchikerimath M, Rao CS, Sandeep S, Rinklebe J, Ok YS, Choudhury BU. Soil organic carbon dynamics: impact of land use changes and management practices: a review. Adv Agron, 2019, 156: 1-107, DOI
46	Rasmussen C, Heckman K, Wieder WR, Keiluweit M, Lawrence CR, Berhe AA, Blankinship JC, Crow SE, Druhan JL, Hicks Pries CE, Marin-Spiotta E, Plante AF, Schäde C, Schimel JP, Sierra CA, Thompson A, Wagai R. Beyond clay: towards an improved set of variables for predicting soil organic matter content. Biogeochemistry, 2018, 137: 297-306, DOI
47	Rowley MC, Grand S, Verrecchia ÉP. Calcium-mediated stabilisation of soil organic carbon. Biogeochemistry, 2018, 137: 27-49, DOI
48	Schmidt M, Torn W, Abiven S, Dittmar T, Guggenberger G, Janssens IA, Kleber M, Kogel-Knabner I, Lehmann J, Manning DA, Nannipieri P, Rasse DP, Weiner S, Trumbore SE. Persistence of soil organic matter as an ecosystem property. Nature, 2011, 478: 49-56, DOI
49	Schuur EA, McGuire AD, Schädel C, Grosse G, Harden J, Hayes DJ, Hugelius G, Koven CD, Kuhry P, Lawrence DM. Climate change and the permafrost carbon feedback. Nature, 2015, 520: 171-179, DOI
50	Shannon C, Weaver W. The mathematical theory of communication, 1949 Urbana University of Illinois Press 3-94
51	Shen CC, Xiong JB, Zhang HY, Feng YZ, Lin XG, Li XY, Liang WJ, Chu HY. Soil pH drives the spatial distribution of bacterial communities along elevation on Changbai Mountain. Soil Biol Biochem, 2013, 57: 204-211, DOI
52	Shrestha BM, Certini G, Forte C, Singh BR. Soil organic matter quality under different land uses in a mountain watershed of Nepal. Soil Sci Soc Am J, 2008, 72: 1563-1569, DOI
53	Slessarev E, Lin Y, Bingham N, Johnson J, Dai Y, Schimel J, Chadwick O. Water balance creates a threshold in soil pH at the global scale. Nature, 2016, 540: 567-569, DOI
54	Tashi S, Singh B, Keitel C, Adams M. Soil carbon and nitrogen stocks in forests along an altitudinal gradient in the eastern Himalayas and a meta-analysis of global data. Glob Change Biol, 2016, 22: 2255-2268, DOI
59	Wang H, Ding Y, Zhang YG, Wang JX, Freedman Z, Liu PC, Cong W, Wang J, Zang RG, Liu SR. Evenness of soil organic carbon chemical components changes with tree species richness, composition and functional diversity across forests in China. Glob Change Biol, 2023, 29: 2852-2864, DOI
55	Wang H, Liu SR, Schindler A, Wang JX, Yang YJ, Song ZC, You YM, Shi ZM, Li ZY, Chen L, Ming AG, Lu LH, Cai DX. Experimental warming reduced topsoil carbon content and increased soil bacterial diversity in a subtropical planted forest. Soil Biol Biochem, 2019, 133: 155-164, DOI
56	Wang H, Liu SR, Song ZC, Yang YJ, Wang JX, You YM, Zhang X, Shi ZM, Nong Y, Ming AG, Lu LH, Cai DX. Introducing nitrogen-fixing tree species and mixing with Pinus massoniana alters and evenly distributes various chemical compositions of soil organic carbon in a planted forest in southern China. For Ecol Manag, 2019, 449, DOI
57	Wang H, Song ZC, Wang JJ, Yang YJ, Wang J, Liu SR. The quadratic relationship between tree species richness and topsoil organic carbon stock in a subtropical mixed-species planted forest. Eur J for Res, 2022, 141(6): 1151-1161, DOI
60	Wang J, Wang H, Ding Y, Zhang YG, Cong W, Zang RG, Liu SR. Shifting cultivation and logging change soil organic carbon functional groups in tropical lowland rainforests on Hainan Island in China. For Ecol Manag, 2023, 549, DOI
58	Wang J, Wang H, Li X, Nie XQ, Liu SR. Effects of environmental factors and tree species mixtures on the functional groups of soil organic carbon across subtropical plantations in southern China. Plant Soil, 2022, 480: 265-281, DOI
61	Wu JS, Lin HP, Meng CF, Jiang PK, Fu WJ. Effects of intercropping grasses on soil organic carbon and microbial community functional diversity under Chinese hickory (Carya cathayensis Sarg.) stands. Soil Res, 2014, 52: 575-583, DOI
62	Wynn JG, Bird MI, Vellen L, Grand-Clement E, Carter J, Berry SL. Continental-scale measurement of the soil organic carbon pool with climatic, edaphic, and biotic controls. Glob Biogeochem Cycles, 2006, 20: 1-12, DOI
63	Yang YH, Li P, He HL, Zhao X, Datta A, Ma WH, Zhang Y, Liu XJ, Han WX, Wilson MC, Fang JY. Long-term changes in soil pH across major forest ecosystems in China. Geophys Res Lett, 2015, 42: 933-940, DOI
64	Zarafshar M, Bazot S, Matinizadeh M, Bordbar SK, Rousta MJ, Kooch Y, Enayati K, Abbasi A, Negahdarsaber M. Do tree plantations or cultivated fields have the same ability to maintain soil quality as natural forests?. Appl Soil Ecol, 2020, 151, DOI

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