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  High-Temperature Biochar Exceeding 700°C Maximizes Carbon Stability for 1,000 Years While Low-Temperature Variants Between 350°C and 500°C Optimize Soil Co-Benefits

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  Aging Increases Conductivity of 350°C Pyrogenic Carbon by Over Three Orders of Magnitude While Reducing High-Temperature Carbon Performance

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  Pyrolyzing Plastic-Contaminated Melon Vines at 500°C Increases Cabbage Yields by 119 Percent While Immobilizing 95 Percent of Soil Lead

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  Hybridizing Dragon Tree Fibers with Three Percent Biochar Boosts Epoxy Tensile Strength by Over One Hundred and Thirty-Five Percent

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  Combining Biochar and Biofertilizers Boosts Crop Yields by Over Fifty Percent and Enhances Soil Health

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  Biochar-Immobilized Enzymes Achieve over Ninety-Nine Percent Pollutant Removal to Advance Sustainable Environmental Remediation

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  Iron Modified Orange Peel Biochar Achieves Over Ninety Percent Removal of Emerging Antibiotic Contaminants from Wastewater

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  Optimal Biochar Application Strategies Could Avoid up to Fifty Percent of Annual Nitrous Oxide Emissions from Chinese Croplands

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  Green-Synthesized Iron Nanoparticles Enhance Biochar Fertilizer Efficiency by Over Forty Percent to Reduce Global Greenhouse Gas Emissions

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  Highly Conductive Graphitized Biochar Increases Active Iron Generation by Nearly Nineteen Percent to Accelerate Antibiotic Degradation in Paddy Soils