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The Effect of Chemical Amendments Used for Phosphorus Abatement on Greenhouse Gas and Ammonia Emissions from Dairy Cattle Slurry: Synergies and Pollution Swapping.Carbon Abatement and Emissions Associated with the Gasification of Walnut Shells for Bioenergy and Biochar ProductionA systematic review of biochar research, with a focus on its stability in situ and its promise as a climate mitigation strategyA dual-isotope approach to allow conclusive partitioning between three sources.Biochar and microbial signaling: production conditions determine effects on microbial communication.The impact of biochars on sorption and biodegradation of polycyclic aromatic hydrocarbons in soils--a review.Towards a global assessment of pyrogenic carbon from vegetation fires.A synthetic analysis of greenhouse gas emissions from manure amended agricultural soils in China.Role of biochar on composting of organic wastes and remediation of contaminated soils-a review.Emissions intensity and carbon stocks of a tropical Ultisol after amendment with Tithonia green manure, urea and biochar.Immobilization of metals in contaminated soil from E-waste recycling site by dairy-manure-derived biochar.Cost-effective enhanced iron bioavailability in rice grain grown on calcareous soil by sulfur mediation and its effect on heavy metals mineralization.Long-term influence of biochar on native organic carbon mineralisation in a low-carbon clayey soil.Fire as a soil-forming factor.Effects of biochar and maize straw on the short-term carbon and nitrogen dynamics in a cultivated silty loam in China.Enhanced rice production but greatly reduced carbon emission following biochar amendment in a metal-polluted rice paddy.Nitrogen nutrition in cotton and control strategies for greenhouse gas emissions: a review.Comment on "Fire-derived charcoal causes loss of forest humus".Biochar composites with nano zerovalent iron and eggshell powder for nitrate removal from aqueous solution with coexisting chloride ions.Extractable pool of biochar controls on crop productivity rather than greenhouse gas emission from a rice paddy under rice-wheat rotation.Soil-borne fungi challenge the concept of long-term biochemical recalcitrance of pyrochar.Characterization of modified biochars prepared at low pyrolysis temperature as an efficient adsorbent for atrazine removal.Charcoal Disrupts Soil Microbial Communication through a Combination of Signal Sorption and Hydrolysis.Investigating the biochar effects on C-mineralization and sequestration of carbon in soil compared with conventional amendments using the stable isotope (δ 13 C) approachSoil organic matter turnover is governed by accessibility not recalcitranceBiochar in bioenergy cropping systems: impacts on soil faunal communities and linked ecosystem processesSelf-assembly of needle-like layered double hydroxide (LDH) nanocrystals on hydrochar: characterization and phosphate removal abilityThe effect of biochar management on soil and plant community properties in a boreal forestInfluence of species identity and charring conditions on fire-derived charcoal traitsStimulation of boreal tree seedling growth by wood-derived charcoal: effects of charcoal properties, seedling species and soil fertilityResponse to Comment on "Fire-Derived Charcoal Causes Loss of Forest Humus"Measurement of soil carbon oxidation state and oxidative ratio by13C nuclear magnetic resonanceObservations and assessment of forest carbon dynamics following disturbance in North AmericaSoil carbon sequestration to mitigate climate change: a critical re-examination to identify the true and the falseA meta-analysis on pyrogenic organic matter induced priming effectCharcoal does not change the decomposition rate of mixed litters in a mineral cambisol: a controlled conditions studyImpact of biochar properties on soil conditions and agricultural sustainability: A reviewEffect of barley straw biochar application on greenhouse gas emissions from upland soil for Chinese cabbage cultivation in short-term laboratory experimentsBiochar: Pros must outweigh consBiochar Preparation, Characterization, and Adsorptive Capacity and Its Effect on Bioavailability of Contaminants: An Overview
P2860
Q28548000-E1550D1A-845A-4AD5-8A26-672E8B468030Q28602927-52C43F02-0792-4424-8F7A-BCC436D48D5AQ28678214-DC2DBD11-3A3B-498A-B002-9DBD336B5571Q36341394-42DD8177-C52D-4B6E-A4B2-77415155063CQ37498501-F457C32A-474F-4E51-94E6-30F64ABE2AC8Q38262834-2BC6CDBA-50AD-4213-981D-81E747C9D86AQ38502639-EB443445-67C5-4BB6-867E-31E01A1A75B8Q38624952-19B35E8F-7FB5-4B3F-B860-7F007FA0DD1DQ38678078-F24F2E98-00EC-42E2-A95D-E770246BD5F1Q38849407-F347F90F-662C-473D-9046-C63A6F800BC3Q39190504-C2C8A314-379B-4847-BAC1-024DDF2BB1E6Q39382348-068D4910-AE9C-43A9-9084-11744284D3BEQ41881284-1CC0E28A-04F3-4F9E-AA51-A50545625B26Q41899448-9B3137EC-E9C3-4616-A1AC-A7A1388CD20CQ46474216-CDD8AF95-6F35-4BD4-BE34-2FA08FD78301Q46694839-0646B16C-FCD1-4CBA-BED0-CF5B05879645Q47757510-68B3BDBA-FF3B-4A50-8E1B-2A13A567AD11Q47825201-14C2657C-39D7-427B-8FB3-5191FD376C0AQ47881461-CBE602F1-7ABC-45DF-87F7-DFCD1C5B376AQ49397595-BDE70EC8-4563-435F-BC22-AA6FE5237B85Q50025637-24945A38-9D17-4B71-AEAC-E860624E3B3EQ52843835-79145FF6-B094-4E46-B395-70518CAD1F56Q55451373-903AAE5C-628C-4437-946E-995152E99CFEQ55878535-7635451C-831A-45EA-AF9B-7F2CA1A5DEF8Q56049179-2EF1D8FF-BD95-423E-B985-24CBAB02BEA0Q57001703-14FEE824-1AE3-40A5-B5E9-06ABE3BD0ADAQ57047260-6AA94FCF-2719-412A-AD3B-F82732423016Q57055770-024C9838-6562-4FF1-8393-D3E330B743F7Q57055804-194B07BD-314A-44DA-888A-BED7E65D05BBQ57055865-B0DD6B27-279F-4229-A265-E2FDAF64FD05Q57056041-01D34DB7-6B8A-4FD1-B2F3-DDBB99422519Q57204927-EC4F0219-9484-4EEF-9CE2-AB03B8E52B9BQ57452381-1C002970-4FC4-4510-8B7A-DC386F1481D2Q57579078-12B9BC99-C368-4CC6-B3F1-5EBCE38CFEC7Q57780326-3D0048DF-7C20-492D-A565-24C108BAB5C0Q57780391-FB637EC6-7AE9-414C-AD46-39A9673774FFQ58334548-91FB96F0-9036-49FC-98A7-E1CAC97986D8Q58335242-6A15EA37-271D-44DD-838F-097D9454F35FQ58926834-24B6D2DD-B2AD-48ED-9CEE-66A2A50CCCF5Q59047205-AC378251-C97D-4A31-8F05-6D0EE7FCD8B4
P2860
description
2008 nî lūn-bûn
@nan
2008年の論文
@ja
2008年学术文章
@wuu
2008年学术文章
@zh
2008年学术文章
@zh-cn
2008年学术文章
@zh-hans
2008年学术文章
@zh-my
2008年学术文章
@zh-sg
2008年學術文章
@yue
2008年學術文章
@zh-hant
name
Fire-derived charcoal causes loss of forest humus.
@en
Fire-derived charcoal causes loss of forest humus.
@nl
type
label
Fire-derived charcoal causes loss of forest humus.
@en
Fire-derived charcoal causes loss of forest humus.
@nl
prefLabel
Fire-derived charcoal causes loss of forest humus.
@en
Fire-derived charcoal causes loss of forest humus.
@nl
P356
P1433
P1476
Fire-derived charcoal causes loss of forest humus.
@en
P2093
Olle Zackrisson
P356
10.1126/SCIENCE.1154960
P407
P577
2008-05-01T00:00:00Z