Leaching of dissolved organic carbon, dissolved organic nitrogen, and other solutes from coarse woody debris and litter in a mixed forest in New York State

Hafner, Sasha D.; Groffman, Peter M.; Mitchell, Myron J.

doi:10.1007/s10533-004-4722-6

Cited by 86 publications

(44 citation statements)

References 81 publications

(108 reference statements)

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“…Part of the carbon and other nutrients can be released as dissolved organic forms (Vestgarden 2001, Hafner et al 2005. In boreal forests, the decomposition process is mainly carried out by fungi and bacteria (Persson et al 1980), which produce degrading enzymes (Killham 1994).…”

Section: Factors Affecting the Decomposition Ratementioning

confidence: 99%

Logging residues and ground vegetation in nutrient dynamics of a clear-cut boreal forest

Palviainen¹

2005

Diss. For.

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In this thesis are studied the role of decomposing logging residues and developing ground vegetation in nutrient dynamics of a clear-cut area. The main aims were to study how much nutrients are released from logging residues during the first three years after clear-cutting and what is the role of ground vegetation in the retention of nutrients on site after clear-cutting. The study was conducted in eastern Finland in a Norway spruce dominated mixed forest, part of which was clear-cut and part left uncut. The decomposition of Norway spruce (Picea abies (L.) H. Karst.), Scots pine (Pinus sylvestris L.) and silver birch (Betula pendula Roth) logging residues i.e. foliage, fine roots (diameter 2 mm) and branches (diameter 1 cm), were studied using the litterbag method. Above-and below-ground biomass of the ground vegetation was sampled on one uncut plot and two clear-cut plots one year before and five years after clear-cutting.In total, 33 % of the dry mass and C, 49 % of P, 90 % of K and 8 % of Ca were released from logging residues in three years, but there was no net release of N because more N accumulated in the roots and branches than was released from the foliage. The loss of mass, C, P and K was greatest during the first year, whereas there was no net release of Ca until the third year. Most of the released nutrients originated from the foliage. Total ground vegetation biomass and nutrient pools decreased after clear-cutting to one half or even lower, but returned to precutting levels within 4-5 years, and the pools of P and K became even larger. In the first year after clear-cutting more N and Ca accumulated in the logging residues than were stored in the ground vegetation.The results indicate that logging residues are a potential source of the elevated dissolved C and P, K and Ca observed in surface waters soon after clear-cutting, but are not a net source of N during the first three years. The ground vegetation is capable of taking up only a small fraction of the nutrients that are released from logging residues during the first two years after clear-cutting and the decomposing dead ground vegetation is a potential source of leached nutrients. The results suggest that nutrients released from logging residues are initially retained on site primarily through soil processes and microbial immobilization. Solely microbial immobilization in logging residues can initially play a more important role in the retention of N and Ca than the ground vegetation. Ground vegetation, however, recovers rapidly from clear-cutting and it becomes thereafter a significant nutrient sink.

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Section: Factors Affecting the Decomposition Ratementioning

confidence: 99%

Logging residues and ground vegetation in nutrient dynamics of a clear-cut boreal forest

Palviainen¹

2005

Diss. For.

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“…Standard error of mean is reported (n=6). cal, chemical and biochemical properties of the underlying soil was reported by several studies (Busse 1994, Kayahara et al 1996, Krzyszowska-Waitkus & Vance 1999, Spears et al 2003, Hafner et al 2005, Zalamea et al 2007, Kappes et al 2007) however, to our knowledge, no specific investigations have been done on wooden-work deterioration ef fects on soil biological features. Thus, our results represent a new field of research ai med to assess the environmental impact of soil bioengineering works.…”

Section: Discussionmentioning

confidence: 79%

“…Several studies report increase of microbial biomass C:N ratio and denitrification activity (Hafner et al 2005), increase of microbial biomass C and of microbial quotient (qmic -Busse 1994), increase of non symbiotic N-fixing bacteria (Hendrickson 1994). Conversely, Zalamea-Bustillo 2005 did not find any dif ference in soil microbial biomass size in soils under decomposing logs when compa red to control soils.…”

Section: Parametersmentioning

confidence: 94%

“…A lack of effect on soil moisture can be related to the early decay stage of the logs; in fact, Harmon & Sexton 1995 reported that a high degree of decay, particularly with degradation of sapwood and heartwood, allows higher infiltration ra tes of water thus modifying soil humidity. Kayahara et al (1996) and Hafner et al (2005) reported higher C:N ratios in the soil under decomposing wood, due to increases in total C coupled with decreases of total N and indicating that decaying wood can re present a source of recalcitrant organic mat ter. We did not observe significant variations of soil C and N content and of the C:N ratio.…”

Section: Parametersmentioning

confidence: 96%

“…Some studies found higher C (carbon) and N (nitrogen) percentages in soil under decaying wood, but did not observe changes in the C:N ratios (Kayahara et al 1996), while Hafner et al (2005) reported hi gher C:N ratio beneath decaying logs.…”

Section: Introductionmentioning

confidence: 95%

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Wood-soil interactions in soil bioengineering slope stabilization works

Moscatelli¹,

Romagnoli²,

Cenfi³

et al. 2009

iForest

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© iForest -Biogeosciences and Forestry IntroductionSoil bioengineering uses sound engineering practices in conjunction with integrated eco logical principles, using living vegetation and other materials to construct slopes (hill slopes, riverbanks, and lake/shorelines), sta bilize slopes, control erosion, protect wildlife habitats and enhance the functioning of eco systems (Donald & Robbin 1996, Gray & Sotir 1996. Successes of ecological engi neering make it an increasingly attractive al ternative to traditional engineering approa ches, which are often much more expensive to construct and sustain (Li & Eddleman 2002). Vegetation can affect the stability of slopes by modifying the hydrological regime in the soil. Species often used in bioenginee ring applications include willow, poplar, grasses and native shrub species anyway usually fast-growth species.In the last years wood has been widely used as a suitable natural material to be used in soil bioengineering works (Sauli et al. 2002). In particular, among wood characte ristics, its mechanical resistance and its dura tion over time is not always necessary, being its role that of allowing plants colonization in its early stages and so these characteristics are important only in specific situations. Among the various environmental factors in fluencing the performance of the woodenwork, soil plays an extremely important role. Its properties in fact not only determine wood decay rate, but are in turn influenced by wood decomposition which can deeply affect soil physico-chemical and biochemical features. Another important aspect of soil bioengineering is thus emphasized: soil is an element either active in wood decay or pas sive, being itself influenced by wood decay. Soil nutrients cycling and availability are in deed deeply affected by wood decay so that decomposing logs have been referred as "slow-release fertilizers" (Carey 1980). Dead wood is no longer considered as me rely debris, and wood decomposition is wi dely recognized as a key ecological process (Franklin et al. 1987). Decaying wood also plays an important role in soil development because the residues from the degradation of wood components (especially lignin) are one of the substrates for humus formation (Ste venson 1982). Additionally, leaching of dis solved organic matter from decaying wood contributes to the soil organic matter pools and, providing easily available organic sub strates, may fuel soil microbial biomass, thus enhancing its size and/or activity (Yavitt & Fahey 1985, Spears et al. 2003.However, regarding the effect of decaying wood on the physical, chemical and bioche mical properties of the underlying soil, con trasting results were reported and, to our knowledge, not specifically on soil bioengi neering works. Some studies found higher C (carbon) and N (nitrogen) percentages in soil under decaying wood, but did not observe changes in the C:N ratios (Kayahara et al. 1996), while Hafner et al. (2005) reported hi gher C:N ratio beneath decaying logs.Further approaches, aimed to infer effe...

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Gap formation and dynamics after long‐term steady state in an old‐growth Picea abies stand in Norway: Above‐ and belowground interactions

Nygaard

Strand

Stuanes

2017

Ecology and Evolution

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Stand dynamics and the gap initiation prior to gap formation are not well‐understood because of its long‐term nature and the scarcity of late‐successional stands. Reconstruction of such disturbance is normally based on historical records and dendroecological methods. We investigated gap initiation and formation at the fine‐scale stand level in the old‐growth reserve of Karlshaugen in Norway. Given its long‐term conservation history, and thorough mapping in permanent marked plots with spatially referenced trees, it provides an opportunity to present stand development before, during, and after gap formation. Late‐successional decline in biomass was recorded after more than 50 years of close to steady state. Gaps in the canopy were mainly created by large old trees that had been killed by spruce bark beetles. Snapping by wind was the main reason for treefall. Long‐term dominance of Norway spruce excluded downy birch and Scots pine from the stand. Comparisons of the forest floor soil properties between the gap and nongap area showed significantly higher concentrations of plant available Ca within the gap area. Plant root simulator (PRS™) probes showed significantly higher supply rates for Ca and Mg, but significantly lower K for the gap compared to the nongap area. Soil water from the gap area had significantly higher C:N ratios compared to the nongap area. Fine‐scale variation with increasing distance to logs indicated that CWD is important for leaking of DOC and Ca. Our long‐term study from Karlshaugen documents gap dynamics after more than 50 years of steady state and a multiscale disturbance regime in an old‐growth forest. The observed disturbance dynamic caused higher aboveground and belowground heterogeneity in plots, coarse woody debris, and nutrients. Our study of the nutrient levels of the forest floor suggest that natural gaps of old‐growth forest provide a long‐lasting biogeochemical feedback system particularly with respect to Ca and probably also N. Norway spruce trees near the gap edge responded with high plasticity to reduced competition, showing the importance of the edge zone as hot spots for establishing heterogeneity, but also the potential for carbon sequestration in old‐growth forest.

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Leaching of dissolved organic carbon, dissolved organic nitrogen, and other solutes from coarse woody debris and litter in a mixed forest in New York State

Cited by 86 publications

References 81 publications

Logging residues and ground vegetation in nutrient dynamics of a clear-cut boreal forest

Logging residues and ground vegetation in nutrient dynamics of a clear-cut boreal forest

Wood-soil interactions in soil bioengineering slope stabilization works

Gap formation and dynamics after long‐term steady state in an old‐growth Picea abies stand in Norway: Above‐ and belowground interactions

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