Application of Rice Husk Biochar for Achieving Sustainable Agriculture and Environment

This paper critically reviewed the current knowledge and challenges of rice husk biochar(RHB)production and its effects on soil properties,plant growth,immobilization of heavy metals,reduction of nutrient leaching and mitigation of greenhouse gas emissions.The characteristics of RHBs produced at various pyrolysis temperatures were discussed and compared to biochars derived from other agro-industrial wastes.RHBs produced at higher pyrolysis temperatures show lower hydrogen/carbon ratio,which suggests the presence of higher aromatic carbon compounds.The increase of pyrolysis temperature also results in production of RHBs with higher ash content,lower yield and higher surface area.RHB usually has higher silicon and ash contents and lower carbon content compared to biochars derived from other feedstocks at the same pyrolysis conditions.Although it depends on soil type,RHB application can improve soil organic carbon content,cation exchange capacity,available K concentration,bulk density and microbial activity.The effect of RHB on soil aggregation mainly depends on soil texture.The growth of different crops is also enhanced by application of RHB.RHB addition to soil can immobilize heavy metals and herbicides and reduce their bioavailability.RHB application shows a significant capacity in reduction of nitrate leaching,although its magnitude depends on the biochar application rate and soil biogeochemical characteristics.Use of RHB,especially in paddy fields,shows a promising mitigation effect on greenhouse gas(CH4,CO2 and N2O)emissions.Although RHB characteristics are also related to other factors such as pyrolysis heating rate and residence time,its performance for specific applications(e.g.carbon sequestration,pH amendment)can be manipulated by adjusting the pyrolysis temperature.More research is needed on long-term field applications of RHB to fully understand the advantages and disadvantages of RHB as a soil amendment.

Rice Husk at a Glance:From Agro-Industrial to Modern Applications

Excessive waste production has led to the concept of a circular bioeconomy to deliver valuable by-products and improve environmental sustainability.The annual worldwide rice production accounts for more than 750 million tons of grain and 150 million tons of husk.Rice husk(RH)contains valuable biomaterials with extensive applications in various fields.The proportions of each component depend primarily on rice genotype,soil chemistry,and climatic conditions.RH and its derivatives,including ash,biochar,hydrochar,and activated carbon have been placed foreground of applications in agriculture and other industries.While the investigation on RH’s compositions,microstructures,and by-products has been done copiously,owing to its unique features,it is still an open-ended area with enormous scope for innovation,research,and technology.Here,we reviewed the latest applications of RH and its derivatives,including fuel and other energy resources,construction materials,pharmacy,medicine,and nanobiotechnology to keep this versatile biomaterial in the spotlight.

Pryloysis of Coffee Husks for Biochar Production

Effective utilization of coffee wastes has been a great challenge in Uganda despite their wider use to replenish soil organic matter. This study explored the possibility of producing biochar from coffee husks that could be used as a soil amendment for replenishing soil nutrients and also for enhancement of soil water holding capacity. Pyrolysis of coffee husks was done in a batch bio-reactor under slow pyrolysis conditions of temperatures 350°C - 550°C and residence times 30 - 60 min. For easy characterization, biochar was grinded, sieved through a 1 mm sieve and then analyzed using a computerized Thermo Graphic Analyzer with an inbuilt and integrated ELTRA 84 GmbH Precision Digital weighing scale. Proximate analysis (wet basis) of biochar gave a moisture content of 5.2%, ash content of 14.7%, volatile matter of 13.2% and fixed carbon of 66.9%. Biochar was applied to soil at different rates (0%, 5%, 10% and 20% w/w) and its effect on water holding capacity was investigated. Results show that bio-char amended soils had higher water holding capacity (p ≤ 0.05) compared to biochar free soils. The water holding capacity also increased with increase in biochar amendment with a 1.5% increase in soil water holding capacity for each 1% increase in biochar application rate. Biochar was also rich in soil nutrient elements with 0.96% N, 0.39% P and 1.97% K;this increased the availability of soil nutrients for crop growth. The results suggest that biochar could be a better tool to improve soil conditions thus enhancing the sustainability of agriculture.

稻壳生物炭/过硫酸盐降解水中四环素的研究

以稻壳为原料,制备了稻壳生物炭,并运用FTIR、XRD等进行表征,详细研究了稻壳生物炭/过硫酸盐体系对水中四环素的去除效果和机制,并对四环素降解过程进行了动力学分析。结果表明,制备的稻壳生物炭对过硫酸盐具有良好的活化性能,能协同过硫酸盐实现四环素的高效去除。稻壳生物炭/过硫酸盐体系对四环素的去除率显著高于单一生物炭、过硫酸盐体系和活性炭/过硫酸盐体系。稻壳生物炭/过硫酸盐体系降解100 mL浓度10 mg/L四环素的最佳工艺条件为:生物炭投加量3 g/L,过硫酸盐投加量12 mmol/L,反应温度60℃,初始溶液pH为5.5,反应时间为120 min。该条件下,四环素的去除率达93.9%。FTIR证实,制备的稻壳生物炭表面富含羟基、羧基等含氧官能团,可活化过硫酸盐产生更多硫酸根自由基。此外,水中共存阴离子对降解过程存在不同程度的抑制作用。动力学分析表明,四环素降解过程符合一级反应动力学模型;自由基猝灭实验证实,反应体系主导自由基为硫酸根自由基。

定量分析稻壳生物炭不同组分对水体中铅和镉的吸附贡献

为了定量描述生物炭中有机与无机组分对Pb^(2+)和Cd^(2+)吸附贡献率,采用慢速热解法在不同温度下制备稻壳生物炭(Biochar,BC),并分别经水洗、酸洗处理去除水溶性组分(Water-soluble Matter,WM)和酸溶性组分(Acidsoluble Matter,AM),通过批量试验,定量计算不同组分对Pb^(2+)和Cd^(2+)吸附的贡献率。吸附动力学和等温吸附结果表明稻壳生物炭主要依靠化学吸附去除Pb^(2+)和Cd^(2+)。生物炭不同组分对Pb^(2+)的吸附贡献率大小依次为WM(44.0%~54.5%)>AM(28.5%~31.0%)>OM(14.5%~27.6%),对于Cd^(2+)则是WM(49.0%~61.0%)>AM(25.9%~29.0%)>OM(13.1%~22.0%),说明无机组分控制了Pb^(2+)和Cd^(2+)吸附过程,其中离子交换和表面沉淀是稻壳生物炭吸附Pb^(2+)和Cd^(2+)的主要机制。

稻壳生物炭中不同组分对水稻富集汞的影响

采用盆栽试验,通过设置对照(CK)组、稻壳生物炭(BC)组、水洗BC组和BC水洗液组4个处理,来探究BC中不同组分对水稻富集汞的影响。结果表明:(1)与CK组相比,BC组、水洗BC组和BC水洗液组水稻植株生物量分别增加了49.14%、24.69%、9.62%;(2)CK组水稻精米中总汞质量浓度为22.90μg/kg,BC组、水洗BC组和BC水洗液组精米中总汞含量分别降低了66.29%、67.99%、57.34%;(3)与CK组相比,施用BC、水洗BC和BC水洗液可使土壤中溶解与可交换态汞含量分别降低91.20%、85.60%和34.40%;(4)BC、水洗BC、BC水洗液通过增加水稻植株生物量、降低土壤中生物有效态汞含量及孔隙水中总汞含量缓解水稻对汞的富集,BC及水洗BC的效果优于BC水洗液。

稻壳生物炭灌浆材料性能试验研究

研究开发新型绿色低碳、固碳的路面材料对支撑国家“双碳”战略目标的实现具有重要意义。为了探究稻壳生物炭细度和掺量对灌浆材料性能的影响,确定稻壳生物炭的最佳细度和替代水泥的最佳掺量,以不同细度稻壳生物炭替代不同质量分数水泥的方式,将稻壳生物炭加入到灌浆材料中,并且对不同龄期的试件进行性能测试,包括流动度试验、抗折试验、抗压试验及干缩试验。试验结果表明:在各组稻壳生物炭灌浆材料抗压强度均高于规范的前提下,以稻壳生物炭灌浆材料的抗收缩性能为参考指标,结合流动性能对掺量的影响,最终确定将稻壳生物炭细度定为粗粒径,替代水泥的比例定为8%。

谷壳源生物炭用量对水稻田控酸和钝化土壤镉活性的短期效应

为了探究谷壳源生物炭不同施用量对水稻田控酸和钝化土壤重金属镉活性的短期效应,本研究设置了谷壳源生物炭6个不同用量处理,分析测定土壤pH、水稻产量、土壤有效态镉含量、水稻植株茎和穗中的镉含量和土壤肥力的变化。结果表明,与CK相比,施用生物炭能有效提高土壤pH,提高了0.15~1.04个单位;当生物炭施用量为80 t·hm^(-2)时,对提高土壤pH效果更显著。施用生物炭能有效提高土壤的综合肥力,土壤全氮、全磷和全钾含量在生物炭施用量超过40 t·hm^(-2)后显著增加,增幅分别达8.62%~14.2%、19.6%~28.3%和11.9%~21.5%;有效磷、速效钾和有机质含量在生物炭施用量≥20 t·hm^(-2)时显著增加,增幅分别达34.6%~115%、70.9%~394%和29.3%~118%;当生物炭施用量超过20 t·hm^(-2)时,水解性氮含量显著降低,降幅为11.4%~22.1%。施用生物炭能有效降低土壤中的有效态镉及水稻植株茎、穗中的镉含量,当生物炭施用量≥20 t·hm^(-2)时,降幅分别为24.0%~37.1%、24.1%~82.9%和28.0%~78.3%;水稻叶中镉含量则在生物炭施用量超过40 t·hm^(-2)后显著降低了22.1%~35.7%。施用生物炭能提高水稻产量,当施用量为20~40 t·hm^(-2)时有显著的增产效果,增幅分别为12.4%和9.42%。从短期来看,谷壳生物炭具有调节土壤酸度、钝化重金属镉活性和提高水稻产量的潜力,且施用量以20 t·hm^(-2)为宜。

稻壳生物炭老化对烤烟生长发育的影响

生物炭因特殊的结构和性质,被广泛用于土壤改良。本文采用室外盆栽法,研究了稻壳生物炭老化对烤烟生长发育的影响。结果表明:施用新鲜稻壳生物炭或老化稻壳生物炭均可提高烤烟根体积和根系活力,对株高、茎围和最大叶长也有一定的促进作用,从而在一定程度上提高了烤烟的产量和质量。总体来看,以施用新鲜稻壳生物炭或15%H_(2)O_(2)氧化老化稻壳生物炭的效果较好。

不同龄期生物炭混凝土力学性能试验研究

将生物炭用于混凝土材料可改善其力学性能,实现固碳的同时丰富了生物质材料固废利用的途径。为研究不同龄期下椰壳、玉米秸秆、稻壳3种生物炭混凝土的工作性能与力学性能,将它以不同质量百分比替代水泥制备生物炭混凝土,对生物碳混凝土的塌落度、基本力学性能展开试验研究。采用SEM和XRD观察生物炭混凝土微观结构与水化产物。结果表明微观结构上生物炭促进了混凝土中水化硅酸钙的生成,水化产物间搭接密实,填充内部孔隙,增加密实程度,进而提升混凝土的宏观力学性能;生物炭可使混凝土7、14 d早期强度显著提升,早期抗压强度最高可提升19.7%,劈裂抗拉强度最高可提升21.7%,抗折强度最高可提升17.3%。

不同吸附材料对废水中Cd(Ⅱ)的吸附动力学及机理

选择稻壳生物炭、钠基膨润土和天然硅藻土3种常见吸附材料,进行了系列吸附试验,并采用扫描电镜(SEM)和傅里叶红外光谱(FTIR)分析对吸附材料进行了表征,研究3种吸附材料对污水中Cd(Ⅱ)的吸附动力学及吸附机理,结果表明:3种吸附材料对Cd(Ⅱ)的吸附都符合准二级动力学模型,对溶液中Cd(Ⅱ)的吸附均为物理-化学复合过程。生物炭对溶液中Cd(Ⅱ)的吸附机制主要是其孔道内的钙氧化物以及表面的含氧官能团,膨润土和硅藻土则主要依赖于比表面积、表面微孔和双键官能团作用。

耐火材料用生物质炭的制备及其对原位合成SiC晶须的影响

为开发用于含碳浇注料中能替代石墨的可再生碳材料,分别以秸秆和稻壳粉为原料制备生物质炭,研究了生物质种类和处理工艺(直接热解+900℃碳化、180℃水热+900℃碳化、180和200℃水热催化+900℃碳化)对碳化产物的物相组成、显微结构及对原位合成SiC晶须的影响。结果表明:稻壳与秸秆的原始结构经水热处理后部分坍缩并发生水解聚合生成碳微球。秸秆经200℃水热催化+900℃碳化后产物中存在明显的非晶态二氧化硅与碳,且碳含量最高,大量碳微球晶核在碳骨架表面形成。相较于以石墨为碳源,添加秸秆基生物质炭的粉体中生成大量交错的SiC晶须。

改性稻壳生物炭对水中反硝化过程和N_(2)O排放的影响

为探究H_(2)O_(2)改性和NaBH_(4)改性稻壳生物炭(BC-H_(2)O_(2)和BC-NaBH_(4))对反硝化过程和N_(2)O排放的影响及机理,在制备并测定BC-H_(2)O_(2)和BC-NaBH_(4)理化性质及其表面含氧官能团含量基础上,将未改性生物炭(BC)、BC-H_(2)O_(2)和BC-NaBH_(4)以1%(w/V)的比例分别加入含有厌氧反硝化细菌(DB)的培养体系,开展DB去除模拟废水中低浓度硝酸盐(约10mg/L,以N计)的室内培养实验.结果表明,H_(2)O_(2)改性增加了生物炭表面的羧基含量,而NaBH_(4)改性增加了生物炭表面的内酯基和酚羟基含量.另外,傅立叶变换红外光谱分析表明,与BC相比,BC-H_(2)O_(2)的C=O含量明显增加.DB+BC-H_(2)O_(2)和DB+BC-NaBH_(4)处理的反硝化速率峰值较DB+BC处理提前12h出现,且分别高17.50%和6.32%.与DB+BC处理相比,DB+BC-NaBH_(4)处理的N_(2)O累积排放量增加10.43%,但差异不显著;DB+BC-H_(2)O_(2)处理的N_(2)O累积排放量显著增加165.54%,N_(2)O/(N_(2)O+N_(2))比值显著增加170.00%,但N_(2)O+N_(2)累积排放量之间无显著差异(P<0.05),表明BC-H_(2)O_(2)抑制反硝化过程中N_(2)O向N_(2)还原,进而促进N_(2)O排放,这可能与添加BC-H_(2)O_(2)使培养体系的pH值、碳生物有效性降低以及C=O含量增加有关.

稻壳及稻壳生物炭对土壤团聚体稳定性及有机碳分布的影响

【目的】长期种植雷竹(Phyllostachys praecox)会导致土壤酸化加剧,土壤结构破坏。我们比较了施用不同量稻壳和稻壳生物炭对土壤理化性状和团聚体组成的影响,以寻求实现雷竹的可持续生产的有效措施。【方法】采用盆栽方法进行雷竹幼苗试验,供试土壤长期种植雷竹,pH为5.3。设置分别施用稻壳、稻壳生物炭10 t/hm^(2)(10H、10B)和30 t/hm^(2)(30H、30B)处理,以不施稻壳和稻壳生物炭的处理为对照(CK)。雷竹幼苗生长262天后,采集土样测定土壤基本理化性质,采用湿筛法筛分不同粒级土壤团聚体,测定各粒级团聚体中有机碳和全氮含量。【结果】30H和30B处理均显著降低了<0.053 mm粒级团聚体含量,显著提高了水稳性团聚体的平均重量直径(MWD)、几何平均直径(GMD)以及>0.25 mm粒级团聚体(R0.25)含量;10H和10B处理对水稳性团聚体的MWD、GMD以及R0.25含量均无显著影响。30B处理显著增加了>2 mm、0.25~2 mm、0.053~0.25 mm粒级团聚体中有机碳含量,其中增加幅度最大的是>2 mm粒级团聚体;10H和30H处理均显著增加了<0.053 mm粒级团聚体中有机碳含量,而对其它粒级团聚体中有机碳含量无显著影响。【结论】施用30 t/hm^(2)的稻壳和稻壳生物炭均能显著提高土壤结构的稳定性,且与施用稻壳相比,施用稻壳生物炭可通过增加大团聚体中有机碳含量,显著提高土壤有机碳含量。因此,用30 t/hm^(2)的稻壳生物炭替代稻壳施用于雷竹林土壤能在一定程度上改善土壤结构,提高土壤固碳潜力。

Designing and Performance Evaluation of Biochar Production in a Top-Lit Updraft Up-scaled Gasifier

The Original Belonio Rice Husk Gasifier (OBRHG), initially of height of 0.6 m, diameter of 0.15 m and thickness of 0.025 m was tested for biochar production through air gasification of rice husk (RH) and the design was upscaled to height of 1.65 m, diameter of 0.85 m and thickness of 0.16 m. A total of 27 experiments were conducted to monitor the gasifier performance and the system can operate with the centrifugal blower operating at a power input of 155 W and a maximum flow rate of 1450 m3/hr regulated according to the air requirement. Building the UBRHG is simple and inexpensive to fabricate and with the fairly satisfactory performance and ease of construction along with the convenience of operation, the UBRHG with RH as feed would find abundant avenues of applications in a rural setting for biochar production alongside thermal, mechanical and electrical energy delivery.

乙酸锌改性稻壳生物炭电容及电吸附Cu^(2+)性能

以稻壳为原料制备生物炭(稻壳炭),利用不同浓度的乙酸锌对稻壳炭改性,制得产物分别命名为稻壳生物炭(RHC)和改性稻壳生物炭(MRHC)。通过SEM、BET、XRD对制备的生物炭理化特性进行表征。将RHC和MRHC制成电极,测试其电化学性能。结果表明,MRHC孔隙结构丰富,比表面积较大,且锌以颗粒状氧化物形式存在于生物炭表面。与RHC相比,MRHC电极比电容大大提高,电阻显著减小,循环性能和倍率性能均有提升。MRHC-0.3(乙酸锌浓度为0.3 mol/L时的MRHC)比表面积为495 m^(2)/g,孔容为0.214 cm^(3)/g,该电极在2 A/g下充放电2000次后,其比电容保持率为92.16%。电极在0.9 V、p H为5、Cu^(2+)初始质量浓度为100 mg/L条件下,MRHC-0.3对Cu^(2+)的电吸附效果最好,吸附量为9.57 mg/g。在0.9 V、pH为5、200 mL Cu^(2+)初始质量浓度为50 mg/L的条件下,去除率可达63.82%。

Positive effects of biochar application and Rhizophagus irregularis inoculation on mycorrhizal colonization,rice seedlings and phosphorus cycling in paddy soils

Phosphorus(P)is an essential element for plant growth but is often limiting in ecosystems;therefore,improving the P fertilizer use efficiency is important.Biochar and arbuscular mycorrhizal fungi(AMF)may enhance P cycling in paddy soils that contain high content of total P but low content of available P(AP).In this study,the effects of biochar addition and Rhizophagus irregularis inoculation on the organic and inorganic P contents and phosphatase activities in paddy soils,rice seedling growth,and AMF colonization were investigated.Compared with no biochar addition,biochar addition enhanced the percentage of spore germination at day 7,hyphal length,most probable number,and mycorrhizal colonization rate of R.irregularis by 32%,662%,70%,and 28%on average,respectively.Biochar and R.irregularis altered soil P cycling and availability.Biochar and R.irregularis,either individually or in combination,increased soil AP content by 2%–48%.Rice seedlings treated with biochar and R.irregularis produced greater biomass,improved root morphology,and increased nutrient uptake compared with those of the control without biochar and R.irregularis.The results suggest that combined application of biochar and R.irregularis is beneficial to rice cultivation in paddy soils with high content of total P but low content of AP.

稻壳生物炭施用方式对土壤理化特性及烤烟产质量的影响

以稻壳制备的生物炭为试验材料,以云烟87为供试烤烟品种,探究了在常规施肥基础上采用不同方式(垄面撒施、移栽穴撒施、条施、全田翻耕撒施)增施稻壳生物炭对植烟土壤改良、烟草生长发育及产质量的影响,以不施生物炭作对照,以期为生物炭在烟草种植及烟田土壤改良方面的应用提供依据。结果表明:采用不同方式施用生物炭对植烟土壤肥力和烤烟产质量均有显著影响,其中,全田翻耕撒施的效果最优,显著增加了烟田土壤的碱解氮、速效钾含量和最大田间持水量,与CK相比分别增加了23.78%、51.31%和11.54个百分点,土壤容重降低了0.16 g/cm^(3);烤后烟叶的总碱、总氮、总糖、还原糖、氯离子、糖碱比和上等烟比例显著上升。

白酒酒糟稻壳基生物炭的制备及吸附应用

为促进酒糟的资源化开发和利用,以酱香型白酒酒糟稻壳为原料热解制备生物炭。以粗炭产率和不同乙醇体积分数溶液中的邻苯二甲酸二丁酯(DBP)吸附容量为评价指标,通过正交试验优化制备工艺,采用比表面及孔隙度分析仪、傅里叶变换红外光谱仪(FTIR)、扫描电镜-X射线能谱仪(SEM-EDS)对生物炭进行了表征。结果表明,酒糟稻壳基生物炭的最优制备工艺为炭化温度400℃,活化时间12 h,炭化时间2.5 h,碱料比2∶1,升温速率5℃/min。此优化条件下,粗炭产率为46.14%,DBP吸附容量最高为20.725 mg/g(水体系)。乙醇体积分数对生物炭的吸附性能有重要影响,随着乙醇体积分数在0~50%范围内升高,生物炭对DBP的吸附容量明显下降,但与商业活性炭相比,酒糟稻壳基生物炭对乙醇水溶液中DBP具有更优的吸附性能。

稻壳合成纳米多孔生物炭用于吸附亚甲基蓝

采用KOH和KOH-NaOH作为活化剂,稻壳为原料,制备出活性生物炭,对亚甲基蓝的吸附表现出优异的性能。研究了单独用KOH活化和KOH-NaOH联合活化时,碱炭比、活化温度和活化时间的影响。结果表明,当KOH和生物炭的质量比为1∶1,活化温度为900℃,活化时间为1h时,活化后的生物炭的吸附能力为314.571mg·g^(-1)。但采用KOH-NaOH联合活化(稻壳∶KOH∶NaOH的质量比为1∶0.3∶0.7),活化温度为800℃,活化时间为1h,在相同的吸附条件下,活化生物炭的吸附容量为350.287mg·g^(-1)。采用扫描电子显微镜、比表面积分析仪和红外光谱仪来表征两种类型的活性生物炭。结果表明,它们的化学成分相似,都具有丰富的孔隙结构,但通过KOH-NaOH联合活化制备的稻壳炭主要是微孔,孔径分布更均匀,这被认为是高吸附能力的主要原因。