Acid weathered soils often require lime and fertilizer application to overcome nutrient deficiencies and metal toxicity to increase soil productivity. Slow-pyrolysis chicken manure biochars, produced at 350 and 700°C with and without subsequent steam activation, were evaluated in an incubation study as soil amendments for a representative acid and highly weathered soil from Appalachia. Biochars were mixed at 5, 10, 20, and 40 g kg into a Gilpin soil (fine-loamy, mixed, active, mesic Typic Hapludult) and incubated in a climate-controlled chamber for 8 wk, along with a nonamended control and soil amended with agronomic dolomitic lime (AgLime). At the end of the incubation, soil pH, nutrient availability (by Mehlich-3 and ammonium bicarbonate diethylene triamine pentaacetic acid [AB-DTPA] extractions), and soil leachate composition were evaluated. Biochar effect on soil pH was process- and rate-dependent. Biochar increased soil pH from 4.8 to 6.6 at the high application rate (40 g kg), but was less effective than AgLime. Biochar produced at 350°C without activation had the least effect on soil pH. Biochar increased soil Mehlich-3 extractable micro- and macronutrients. On the basis of unit element applied, increase in pyrolysis temperature and biochar activation decreased availability of K, P, and S compared to nonactivated biochar produced at 350°C. Activated biochars reduced AB-DTPA extractable Al and Cd more than AgLime. Biochar did not increase NO in leachate, but increased dissolved organic carbon, total N and P, PO, SO, and K at high application rate (40 g kg). Risks of elevated levels of dissolved P may limit chicken manure biochar application rate. Applied at low rates, these biochars provide added nutritional value with low adverse impact on leachate composition.
Short-rotation woody crops are an integral component of regional and national energy portfolios, as well as providing essential ecosystem services such as biomass supplies, carbon sinks, clean water, and healthy soils. We review recent USDA Forest Service Research and Development efforts from the USDA Biomass Research Centers on the provisioning of these ecosystem services from woody crop production systems. For biomass, we highlight productivity and yield potential, pest susceptibility, and bioenergy siting applications. We describe carbon storage in aboveground woody biomass and studies assessing the provision of clean and plentiful water. Soil protection and wildlife habitat are also mentioned, in the context of converting lands from traditional row-crop agriculture to woody production systems.
Under irrigation with secondary effluent, it is often assumed that reduced leaching would delay the transport of effluent organic matter (OM) from within the root zone for long enough for biodegradation to practically eliminate it. This hypothesis was tested in a lysimeter study which compared tap water with low‐quality secondary effluent (total organic C [TOC] = 190 mg C L−1) for Eucalyptus irrigation. Lysimeters (200‐L drums) were packed with dune sand or one of two clayey soils (A horizons of a Calcic Haploxeroll and a Typic Palexeralf) and were either not planted or planted. Leaching treatments were leaching fraction 1 (LF 1) (not planted) and LF 0.2, intermittent leaching and prolonged deficit irrigation. These provided residence times of the water in the soil that ranged from 0.8 to over 200 d. While root organic C (OC) made a negligible net contribution to leachate OC, the effluent‐derived OC was rather recalcitrant as was indicated by: (i) the concentrations of TOC in the leachate increased with decreasing LF to over 250 mg C L−1; (ii) the recovery of the applied TOC in the leachate was significant (10–20%) even at RTs over 20 d (LF ≅ 0.06 in the sand‐packed lysimeters). Most all the dissolved and colloidal organic C (DOC) was smaller than 30 kDa. We expect these concentrations of low‐molecular‐weight mobile OC to govern many aspects of the biological and chemical behavior in solutions of effluent‐irrigated soils, especially under reduced‐leaching regimes.
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