| [1] |
Ahmad M, Rajapaksha AU, Lim JE, Zhang M, Bolan N, et al. 2014. Biochar as a sorbent for contaminant management in soil and water: a review. |
| [2] |
Mohan D, Abhishek K, Sarswat A, Patel M, Singh P, et al. 2018. Biochar production and applications in soil fertility and carbon sequestration – a sustainable solution to crop-residue burning in India. |
| [3] |
Ahmed M, Hayat R, Ahmad M, Ul-Hassan M, Kheir AMS, et al. 2022. Impact of climate change on dryland agricultural systems: a review of current status, potentials, and further work need. |
| [4] |
Lehmann J, Rillig MC, Thies J, Masiello CA, Hockaday WC, et al. 2011. Biochar effects on soil biota – a review. |
| [5] |
Mohan D, Sarswat A, Ok YS, Pittman CU Jr. 2014. Organic and inorganic contaminants removal from water with biochar, a renewable, low cost and sustainable adsorbent – a critical review. |
| [6] |
Naz Z, Jahan S, Rashid A, Kamran A, Abd-Allah EF, et al. 2025. Efficacy of modified biochar for enhancing maize photosynthesis and yield under various irrigation regimes. |
| [7] |
Tan XF, Liu YG, Gu YL, Xu Y, Zeng GM, et al. 2016. Biochar-based nano-composites for the decontamination of wastewater: a review. |
| [8] |
Ramanayaka S, Vithanage M, Alessi DS, Liu WJ, Jayasundera ACA, et al. 2020. Nanobiochar: production, properties, and multifunctional applications. |
| [9] |
Rajput VD, Minkina T, Ahmed B, Singh VK, Mandzhieva S, et al. 2022. Nano-biochar: a novel solution for sustainable agriculture and environmental remediation. |
| [10] |
Chaubey AK, Pratap T, Preetiva B, Patel M, Singsit JS, et al. 2024. Definitive review of nanobiochar. |
| [11] |
Liu G, Zheng H, Jiang Z, Zhao J, Wang Z, et al. 2018. Formation and physicochemical characteristics of nano biochar: insight into chemical and colloidal stability. |
| [12] |
Lyu H, Gao B, He F, Zimmerman AR, Ding C, et al. 2018. Effects of ball milling on the physicochemical and sorptive properties of biochar: experimental observations and governing mechanisms. |
| [13] |
Xiao J, Hu R, Chen G. 2020. Micro-nano-engineered nitrogenous bone biochar developed with a ball-milling technique for high-efficiency removal of aquatic Cd(II), Cu(II) and Pb(II). |
| [14] |
Sani MNH, Amin M, Siddique AB, Nasif SO, Ghaley BB, et al. 2023. Waste-derived nanobiochar: A new avenue towards sustainable agriculture, environment, and circular bioeconomy. |
| [15] |
Lian F, Xing B. 2024. From bulk to nano: formation, features, and functions of nano-black carbon in biogeochemical processes. |
| [16] |
Chen X, Zhou B, Wang Q, Tao W, Lin H. 2020. Nano-biochar reduced soil erosion and nitrate loss in sloping fields on the Loess Plateau of China. |
| [17] |
Yang Y, Zhou B, Hu Z, Lin H. 2020. The effects of nano-biochar on maize growth in northern Shaanxi Province on the Loess Plateau. |
| [18] |
Peng W, Cai W, Pan J, Su X, Dou L. 2025. Molecular mechanisms of alfalfa response to abiotic stresses. |
| [19] |
Shan B, Hao R, Zhang J, Li J, Ye Y, et al. 2022. Microbial remediation mechanisms and applications for lead-contaminated environments. |
| [20] |
Kumar M, Xiong X, Wan Z, Sun Y, Tsang DCW, et al. 2020. Ball milling as a mechanochemical technology for fabrication of novel biochar nanomaterials. |
| [21] |
Naghdi M, Taheran M, Brar SK, Rouissi T, Verma M, et al. 2017. A green method for production of nanobiochar by ball milling- optimization and characterization. |
| [22] |
Yuan Y, Zhang N, Hu X. 2020. Effects of wet and dry ball milling on the physicochemical properties of sawdust derived-biochar. |
| [23] |
Lyu H, Gao B, He F, Zimmerman AR, Ding C, et al. 2018. Experimental and modeling investigations of ball-milled biochar for the removal of aqueous methylene blue. |
| [24] |
Oleszczuk P, Ćwikła-Bundyra W, Bogusz A, Skwarek E, Ok YS. 2016. Characterization of nanoparticles of biochars from different biomass. |
| [25] |
Song B, Chen M, Zhao L, Qiu H, Cao X. 2019. Physicochemical property and colloidal stability of micron- and nano-particle biochar derived from a variety of feedstock sources. |
| [26] |
Behnam H, Firouzi AF. 2023. Effects of synthesis method, feedstock type, and pyrolysis temperature on physicochemical properties of biochar nanoparticles. |
| [27] |
Li H, Cui X, Sun Y, Zheng P, Wang L, et al. 2025. Advances in microbial remediation of heavy metal-contaminated soils: mechanisms, synergistic technologies, field applications and future perspectives. |
| [28] |
Zhang Q, Wang J, Lyu H, Zhao Q, Jiang L, et al. 2019. Ball-milled biochar for galaxolide removal: sorption performance and governing mechanisms. |
| [29] |
Saini AK, Abrol V, Sharma P, Srinivasarao C, Parmar AS, et al. 2025. Nitrogen-fortified nanobiochar impacts soil properties, root growth and basmati rice yield. |
| [30] |
Razzaq S, Zhou B, Ullah Z, Zia-ur-Rehman M, Guo H, et al. 2024. Exploring the impact of organic and inorganic amendments, with foliar application of iron nanoparticles, on cadmium stabilization and growth of maize in wastewater irrigated-soil. |
| [31] |
Liu W, Li Y, Feng Y, Qiao J, Zhao H, et al. 2020. The effectiveness of nanobiochar for reducing phytotoxicity and improving soil remediation in cadmium-contaminated soil. |
| [32] |
Dhal S, Pal H. 2023. Nanotechnology for climate-resilient agriculture. In Climate-Resilient Agriculture, ed. Hasanuzzaman M. Vol 2. Cham: Springer. pp. 863–880 doi: 10.1007/978-3-031-37428-9_38 |
| [33] |
Adeel M, Shakoor N, Mustafa M, Ming X. 2025. Nanotechnology as a new perspective in precision agriculture. In Agri-Nanotechnology: Innovations for Sustainable Agriculture and Environmental Restoration, eds Purewal SS, Gahlaut V, Dash SK. Singapore: Springer. pp. 49–82 doi: 10.1007/978-981-96-9756-4_3 |
| [34] |
Xiang W, Wan Y, Zhang X, Tan Z, Xia T, et al. 2020. Adsorption of tetracycline hydrochloride onto ball-milled biochar: Governing factors and mechanisms. |
| [35] |
Zhou BB, Chen XP, Henry L. 2020. The effect of nano-biochar on soil, water, and nutrient loss of a sloping land with different vegetation covers on Loess Plateau of China. |
| [36] |
Osman KT. 2018. Sandy soils. In Management of Soil Problems. Cham: Springer. pp. 37−65 doi: 10.1007/978-3-319-75527-4_3 |
| [37] |
Arshad MA, Ansari N, Umar M, Arshad F, Adil M, et al. 2021. A review on wheat management, strategies, current problems and future perspectives. |
| [38] |
Hafez EM, Osman HS, Gowayed SM, Okasha SA, Omara AE, et al. 2021. Minimizing the adversely impacts of water deficit and soil salinity on maize growth and productivity in response to the application of plant growth-promoting rhizobacteria and silica nanoparticles. |
| [39] |
Joseph S, Anawar HM, Storer P, Blackwell P, Chia C, et al. 2015. Effects of enriched biochars containing magnetic iron nanoparticles on mycorrhizal colonisation, plant growth, nutrient uptake and soil quality improvement. |
| [40] |
Yue L, Lian F, Han Y, Bao Q, Wang Z, et al. 2019. The effect of biochar nanoparticles on rice plant growth and the uptake of heavy metals: implications for agronomic benefits and potential risk. |
| [41] |
Ramzan M, Zia A, Naz G, Shahid M, Ali Shah A, et al. 2023. Effect of nanobiochar (nBC) on morpho-physio-biochemical responses of black cumin (Nigella sativa L.) in Cr-spiked soil. |
| [42] |
Kamran M, Parveen A, Ahmar S, Malik Z, Hussain S, et al. 2020. An overview of hazardous impacts of soil salinity in crops, tolerance mechanisms, and amelioration through selenium supplementation. |
| [43] |
Razzaq S, Zhou B, Zia-ur-Rehman M, Aamer Maqsood M, Hussain S, et al. 2022. Cadmium stabilization and redox transformation mechanism in maize using nanoscale zerovalent-iron-enriched biochar in cadmium-contaminated soil. |
| [44] |
Poria V, Jhilta P, Rana A, Khokhar J, Singh S. 2022. Pressmud: a sustainable source of value-added products. |
| [45] |
Aftab ZEH, Aslam W, Aftab A, Shah AN, Akhter A, et al. 2022. Incorporation of engineered nanoparticles of biochar and fly ash against bacterial leaf spot of pepper. |
| [46] |
Kong M, Liang J, White JC, Elmer WH, Wang Y, et al. 2022. Biochar nanoparticle-induced plant immunity and its application with the elicitor methoxyindole in Nicotiana benthamiana. |
| [47] |
Harter J, Krause HM, Schuettler S, Ruser R, Fromme M, et al. 2014. Linking N2O emissions from biochar-amended soil to the structure and function of the N-cycling microbial community. |
| [48] |
Liu L, Shen G, Sun M, Cao X, Shang G, et al. 2014. Effect of biochar on nitrous oxide emission and its potential mechanisms. |
| [49] |
Lyu H, Xia S, Tang J, Zhang Y, Gao B, et al. 2020. Thiol-modified biochar synthesized by a facile ball-milling method for enhanced sorption of inorganic Hg2+ and organic CH3Hg+. |
| [50] |
Li R, Zhang Y, Deng H, Zhang Z, Wang JJ, et al. 2020. Removing tetracycline and Hg(II) with ball-milled magnetic nanobiochar and its potential on polluted irrigation water reclamation. |
| [51] |
Dong X, He L, Hu H, Liu N, Gao S, et al. 2018. Removal of 17β-estradiol by using highly adsorptive magnetic biochar nanoparticles from aqueous solution. |
| [52] |
Ramanayaka S, Tsang DCW, Hou D, Ok YS, Vithanage M. 2020. Green synthesis of graphitic nanobiochar for the removal of emerging contaminants in aqueous media. |
| [53] |
Naghdi M, Taheran M, Pulicharla R, Rouissi T, Brar SK, et al. 2019. Pine-wood derived nanobiochar for removal of carbamazepine from aqueous media: adsorption behavior and influential parameters. |
| [54] |
Lian F, Yu W, Zhou Q, Gu S, Wang Z, et al. 2020. Size matters: nano-biochar triggers decomposition and transformation inhibition of antibiotic resistance genes in aqueous environments. |
| [55] |
Rohini P, Jayadev A. 2024. Microplastics on mangrove ecosystem and scope of biodegradation—a review. |
| [56] |
Raut SS, Sharma A, Mishra A. 2025. Nano-bioremediation via biochar, zeolite nanocomposites for water quality enhancement: a review. |
| [57] |
Lateef A, Nazir R, Jamil N, Alam S, Shah R, et al. 2019. Synthesis and characterization of environmental friendly corncob biochar based nano-composite – a potential slow release nano-fertilizer for sustainable agriculture. |
| [58] |
Tan M, Li Y, Chi D, Wu Q. 2023. Efficient removal of ammonium in aqueous solution by ultrasonic magnesium-modified biochar. |
| [59] |
Ma S, Jing F, Sohi SP, Chen J. 2019. New insights into contrasting mechanisms for PAE adsorption on millimeter, micron- and nano-scale biochar. |
| [60] |
Nafi E, Webber H, Danso I, Naab JB, Frei M, et al. 2020. Interactive effects of conservation tillage, residue management, and nitrogen fertilizer application on soil properties under maize-cotton rotation system on highly weathered soils of West Africa. |
| [61] |
Mukherjee D. 2017. Microorganisms: role for crop production and its interface with soil agroecosystem. In Plant-Microbe Interactions in Agro-Ecological Perspectives, eds Singh D, Singh H, Prabha R. Singapore: Springer. pp. 333–359 doi: 10.1007/978-981-10-5813-4_17 |
| [62] |
Woolf D, Amonette JE, Street-Perrott FA, Lehmann J, Joseph S. 2010. Sustainable biochar to mitigate global climate change. |
| [63] |
Wang D, Zhang W, Zhou D. 2013. Antagonistic effects of humic acid and iron oxyhydroxide grain-coating on biochar nanoparticle transport in saturated sand. |
| [64] |
Saxena M, Maity S, Sarkar S. 2014. Carbon nanoparticles in 'biochar' boost wheat (Triticum aestivum) plant growth. |