Kim H. Ludovici scite author profile

Summary• We examined the relationships between stem CO 2 efflux (E s ), diameter growth, and nonstructural carbohydrate concentration in loblolly pine trees. Carbohydrate supply was altered via stem girdling during rapid stem growth in the spring and after growth had ceased in the autumn. We hypothesized that substrate type and availability control the seasonal variation and temperature sensitivity of E s .• The E s increased and decreased above and below the girdle, respectively, within 24 h of treatment. Seasonal variation in E s response to girdling corresponded to changes in stem soluble sugar and starch concentration. Relative to nongirdled trees, E s increased 94% above the girdle and decreased 50% below in the autumn compared with a 60% and 20% response at similar positions in the spring.• The sensitivity of E s to temperature decreased below the girdle in the autumn and spring and increased above the girdle but only in the autumn. Temperaturecorrected E s was linearly related to soluble sugar (R 2 = 0.57) and starch (R 2 = 0.62) concentration.• We conclude that carbohydrate supply, primarily recently fixed photosynthate, strongly influences E s in Pinus taeda stems. Carbohydrate availability effects on E s obviate the utility of applying short-term temperature response functions across seasons.

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Effects of organic matter removal, soil compaction and vegetation control on 10th year biomass and foliar nutrition: LTSP continent-wide comparisons

Ponder¹,

Fleming²,

Berch³

et al. 2012

Forest Ecology and Management

112

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Effects of organic matter removal, soil compaction, and vegetation control on 5-year seedling performance: a regional comparison of Long-Term Soil Productivity sites

Fleming¹,

Powers²,

Foster³

et al. 2006

Can. J. For. Res.

101

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We examined fifth-year seedling response to soil disturbance and vegetation control at 42 experimental locations representing 25 replicated studies within the North American Long-Term Soil Productivity (LTSP) program. These studies share a common experimental design while encompassing a wide range of climate, site conditions, and forest types. Whole-tree harvest had limited effects on planted seedling performance compared with the effects of stem-only harvest (the control); slight increases in survival were usually offset by decreases in growth. Forest-floor removal improved seedling survival and increased growth in Mediterranean climates, but reduced growth on productive, nutrient-limited, warmhumid sites. Soil compaction with intact forest floors usually benefited conifer survival and growth, regardless of climate or species. Compaction combined with forest-floor removal generally increased survival, had limited effects on individual tree growth, and increased stand growth in Mediterranean climates. Vegetation control benefited seedling growth in all treatments, particularly on more productive sites, but did not affect survival or alter the relative impact of organic matter removal and compaction on growth. Organic matter removal increased aspen coppice densities and, as with compaction, reduced aspen growth.

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Modeling in-situ pine root decomposition using data from a 60-year chronosequence

Ludovici¹,

Zarnoch²,

Richter³

2002

Can. J. For. Res.

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Because the root system of a mature pine tree typically accounts for 2030% of the total tree biomass, decomposition of large lateral roots and taproots following forest harvest and re-establishment potentially impact nutrient supply and carbon sequestration in pine systems over several decades. If the relationship between stump diameter and decomposition of taproot and lateral root material, i.e., wood and bark, can be quantified, a better understanding of rates and patterns of sequestration and nutrient release can also be developed. This study estimated decomposition rates from in-situ root systems using a chronosequence approach. Nine stands of 55- to 70-year-old loblolly pine (Pinus taeda L.) that had been clear-cut 0, 5, 10, 20, 25, 35, 45, 55, and 60 years ago were identified on well-drained Piedmont soils. Taproot and lateral root systems were excavated, measured, and weighed. Although more than 50% of the total root mass decomposed during the first 10 years after harvest, field excavations recovered portions of large lateral roots (>5 cm diameter) and taproots that persisted for more than 35 and 60 years, respectively. Results indicate that decomposition of total root biomass, and its component parts, from mature, clear-cut loblolly pine stands, can be modeled with good precision as a function of groundline stump diameter and years since harvest.

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Kim H. Ludovici

Relationships between stem CO₂ efflux, substrate supply, and growth in young loblolly pine trees

Effects of organic matter removal, soil compaction and vegetation control on 10th year biomass and foliar nutrition: LTSP continent-wide comparisons

Effects of organic matter removal, soil compaction, and vegetation control on 5-year seedling performance: a regional comparison of Long-Term Soil Productivity sites

Modeling in-situ pine root decomposition using data from a 60-year chronosequence

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Kim H. Ludovici

Relationships between stem CO2 efflux, substrate supply, and growth in young loblolly pine trees

Effects of organic matter removal, soil compaction and vegetation control on 10th year biomass and foliar nutrition: LTSP continent-wide comparisons

Effects of organic matter removal, soil compaction, and vegetation control on 5-year seedling performance: a regional comparison of Long-Term Soil Productivity sites

Modeling in-situ pine root decomposition using data from a 60-year chronosequence

Contact Info

Product

Resources

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Relationships between stem CO₂ efflux, substrate supply, and growth in young loblolly pine trees