农业工程学报
農業工程學報
농업공정학보
2013年
21期
188-193
,共6页
覃莉莉%万涛%熊磊%武大庆%孙萌萌%胡俊燕%谭雪梅
覃莉莉%萬濤%熊磊%武大慶%孫萌萌%鬍俊燕%譚雪梅
담리리%만도%웅뢰%무대경%손맹맹%호준연%담설매
秸秆%肥料%尿素%高吸水树脂%缓释%植酸
秸稈%肥料%尿素%高吸水樹脂%緩釋%植痠
갈간%비료%뇨소%고흡수수지%완석%식산
straw%fertilizers%urea%superabsorbent%slow release%phytic acid
为了提高化肥的利用率、降低环境污染和提高玉米秸秆的高附加值综合利用水平,以过硫酸铵和亚硫酸氢钠为氧化还原引发剂,将植酸改性玉米秸秆与衣康酸、乙烯基吡咯烷酮和丙烯酰胺接枝共聚制备植酸改性玉米秸秆复合高吸水性树脂(PCS-SA,phytic acid-modified corn stalk-composite superabsorbent),该文重点研究了衣康酸与乙烯基吡咯烷酮质量比对PCS-SA尿素溶液吸肥速率、保肥率以及缓释速率的影响,采用扫描电镜(SEM, scanning electronic microscope)和傅里叶红外光谱(FTIR,fourier transform infrared spectroscopy)对PCS-SA的结构和形貌进行了表征。结果表明衣康酸与乙烯基吡咯烷酮质量比为70:30制备的PCS-SA对尿素吸附量为3.81 g/g,40 min尿素溶液吸肥率达到最大值(360 g/g),PCS-SA吸肥凝胶去离子水中3 d尿素释放率为66.14%,在土壤中5 d尿素释放率为47.6%,明显降低了尿素的释放速率、提高了土壤的保肥能力。FTIR谱图初步证实PCS-SA的结构,SEM表明PCS-SA具有不规则的凹凸波状表面,并伴有许多大微孔和小毛细孔。该研究为PCS-SA在农林等领域的应用提供试验依据和参考。
為瞭提高化肥的利用率、降低環境汙染和提高玉米秸稈的高附加值綜閤利用水平,以過硫痠銨和亞硫痠氫鈉為氧化還原引髮劑,將植痠改性玉米秸稈與衣康痠、乙烯基吡咯烷酮和丙烯酰胺接枝共聚製備植痠改性玉米秸稈複閤高吸水性樹脂(PCS-SA,phytic acid-modified corn stalk-composite superabsorbent),該文重點研究瞭衣康痠與乙烯基吡咯烷酮質量比對PCS-SA尿素溶液吸肥速率、保肥率以及緩釋速率的影響,採用掃描電鏡(SEM, scanning electronic microscope)和傅裏葉紅外光譜(FTIR,fourier transform infrared spectroscopy)對PCS-SA的結構和形貌進行瞭錶徵。結果錶明衣康痠與乙烯基吡咯烷酮質量比為70:30製備的PCS-SA對尿素吸附量為3.81 g/g,40 min尿素溶液吸肥率達到最大值(360 g/g),PCS-SA吸肥凝膠去離子水中3 d尿素釋放率為66.14%,在土壤中5 d尿素釋放率為47.6%,明顯降低瞭尿素的釋放速率、提高瞭土壤的保肥能力。FTIR譜圖初步證實PCS-SA的結構,SEM錶明PCS-SA具有不規則的凹凸波狀錶麵,併伴有許多大微孔和小毛細孔。該研究為PCS-SA在農林等領域的應用提供試驗依據和參攷。
위료제고화비적이용솔、강저배경오염화제고옥미갈간적고부가치종합이용수평,이과류산안화아류산경납위양화환원인발제,장식산개성옥미갈간여의강산、을희기필각완동화병희선알접지공취제비식산개성옥미갈간복합고흡수성수지(PCS-SA,phytic acid-modified corn stalk-composite superabsorbent),해문중점연구료의강산여을희기필각완동질량비대PCS-SA뇨소용액흡비속솔、보비솔이급완석속솔적영향,채용소묘전경(SEM, scanning electronic microscope)화부리협홍외광보(FTIR,fourier transform infrared spectroscopy)대PCS-SA적결구화형모진행료표정。결과표명의강산여을희기필각완동질량비위70:30제비적PCS-SA대뇨소흡부량위3.81 g/g,40 min뇨소용액흡비솔체도최대치(360 g/g),PCS-SA흡비응효거리자수중3 d뇨소석방솔위66.14%,재토양중5 d뇨소석방솔위47.6%,명현강저료뇨소적석방속솔、제고료토양적보비능력。FTIR보도초보증실PCS-SA적결구,SEM표명PCS-SA구유불규칙적요철파상표면,병반유허다대미공화소모세공。해연구위PCS-SA재농림등영역적응용제공시험의거화삼고。
The growth of plants and vegetables is mainly a function of the quantity of fertilizer and water. It is very important to improve the utilization of water resources and fertilizer nutrients. However, about 40-70%of the nitrogen of the applied normal fertilizers is lost to the environment, and cannot be absorbed by plants and vegetables, causing not only large economic and resource losses, but also very serious environmental pollution. It has been reported that about 1/3 of nitrogen fertilizers enter into the atmosphere, where N2O destroys the ozone layer, and about 1/3 of nitrogen fertilizers leach into the water, leading to eutrophication of water resources. As a by-product of corn crops, corn stalk is an abundant biodegradable resource whose main components are cellulose, hemicellulose, and lignin. Up to now, most of the crop residues have been focused on burying them back to improve the fertility of the soil, using them as the materials for the paper industry and producing protein feed, alcohol, and methane by microbial fermentation. Corn stalk can be used as a bioabsorbent, due to its large surface area and a number of hydrophilic hydroxyl groups on the macromolecular chains. However, its fertilizer adsorption capacity is still very low. Therefore, modification of corn stalk is needed to enhance its fertilizer adsorption capacity. Up to now, straw was either gelatinized, or modified by acid or/and base treatment and then grafted with some monomers to prepare straw composite superabsorbents. But there are no reports on the phytic acid-modified corn stalk composite superabsorbents. The present work aims to investigate the urea absorbency, urea retention, and urea release properties of phytic acid-modified corn stalk composite superabsorbents (PCS-SA) prepared by graft copolymerization of acrylamide (AM), vinyl pyrrolidone (VP), and itaconic acid (IA) with phytic acid-modified corn stalk (PCS) in an aqueous solution, using ammonium persulfate and sodium bisulfite as a redox initiator. The effect of the mass ratio of IA to VP on the urea absorbency, urea retention, and urea release rate of PCS-SA was investigated. The structure and morphology of PCS-SA were characterized by FTIR and SEM, respectively. The results showed that with an increasing IA and NVP mass ratio, the urea solution absorption rate, urea solution retention, and urea release rate of PCS-SA are improved. However, when the IA and NVP mass ratio was greater than 70:30, the urea solution absorption rate, urea solution retention, and urea release rate of PCS-SA decreased. PCS-SA, synthesized with an IA and VP mass ratio of 70:30, had a urea absorption capacity of 3.81g/g, urea absorbency of 360g/g within 40min, urea release ratio of 66.14%in distilled water after 3d, and urea release ratio of 47.6% in soil after 5 d, resulting in a significantly decreased urea release rate and an increasing urea retention of soil. FTIR spectrum of PCS-SA appeared as characteristics of absorption peaks which might be ascribed to a PCS structural unit, VP unit, IA unit and AM unit, respectively, as indicative of the target structure for the prepared PCS-SA. SEM showed that PCS-SA had an irregular and rugged surface, accompanied by many small and large pores, which can facilitate the permeation of urea solution into the polymeric network.
