Assessment of Super Absorbent Polymer (SAP) on Plant Available Water (PAW) in Dry Lands

One of the ways of overcoming the cost of irrigation is through in-situ water harvesting at the plant roots. Super absorbent polymer (SAP) can facilitate water harvesting at the plant roots. This study attempted to assess the effect of SAP on plant available water (PAW) of different soils. In this study, SAP was sequentially added at the rate of 0.2%, 0.3% and 0.5% of the soil weight and its impact assessed in clay, sandy clay and sandy loam soils. The moisture retention characteristics of the original and SAP treated soils were studied using soil water retention curves (SWRC) and results modelled using Gardner model. PAW was estimated from SWRC as the difference between moisture content at 1.5 and 3 bar in all soils. The difference in PAW between original and treated soils was assessed at 5% level of significance. The WRC of all the samples was adequately found to be described by the Gardner model (Coefficient of determination R2 ≥ 98% and residual standard error (RSE) ≤ 0.04). SWRC changed with increase in SAP percentage in clay, sandy clay and sandy loam soils. Clay had a higher change in water retention then sandy clay and lastly sandy loam. Plant available water content (PAW) in all soils increased. In clay soil it increased with increase in SAP from 0.3291 at zero SAP to 0.6223 at 0.5% SAP. Sandy clay soil increased in PAW from 0.2721 at zero SAP to 0.5335 at 0.5% SAP and Sandy loam soils from 0.1691 at zero SAP to 0.3461 at 0.5% SAP. Hence, from the study SAP can be used to conserve irrigation water in the plant roots and therefore reducing the cost since PAW has been increased.

Effects of Super Absorbent Polymers on Yield and Water-saving and Drought-escaping Mechanism in Spring Maize

The effects of super absorbent polymers （SAP） on yield as well as water-saving and drought-escaping mechanism in spring maize in the seasonal drought region were studied. As shown by the results, during the seasonal drought in southern China, SAP treatment promoted the soil moisture, improved the capability of absorption and transportation of roots, promoted physiological and biochemical functions, increased the chlorophyll content, photosynthetic rate and intercellular CO2 concentration, and reduced the stomatal conductance and transplre.tion rate. As a result, the economic characters of spring maize were improved, and the yield was increased.

Promoting effect of super absorbent polymer on hydrate formation

The effect of super absorbent polymer（SAP） on the formation of tetrahydrofuran（THF） hydrate was studied by the successional cooling method.It was found that THF solution samples with 0.004 wt% and 0.03 wt% of SAP formed THF hydrate completely during the same cooling process.The corresponding induction time was 16-29 min,14-31 min,respectively,which was obviously shorter than that of THF solution samples without SAP（25-62 min）.It indicated that SAP accelerated the formation of THF hydrate.At the same time,the pictures of hydrate formation with and without SAP had been compared.It was found that SAP did not change the morphology of the hydrate.Finally,the mechanism of SAP promoting effect on the formation of THF hydrate was suggested.

Factors Influencing Strength of Super Absorbent Polymer(SAP)Concrete

Super absorbent polymers (SAPs) are gradually being applied in concrete production as internal curing agents. SAP can effectively reduce early age autogenous shrinkage of concrete, alleviate the hazards caused by concrete cracking and improve its freeze–thaw resistance. However, the relationships between SAP dosage, SAP particle size and the water–cement ratio of concrete have certain influences on the evolution of the compressive strength of SAP-incorporated concrete. In this study, experiments were conducted to investigate the relationships between the water–cement ratio of concrete, the SAP dosage and SAP particle size. The significant factors influencing concrete strength are determined and equations are proposed for predicting the strength of SAP-incorporated concrete at 3, 7 and 28 days. The findings from this study, such as the SAP dosage should not be larger than 0.2%, are expected to form a theoretical basis for the rational use of SAP as an additive to concrete. © 2017, Tianjin University and Springer-Verlag Berlin Heidelberg.

PREPARATION AND SWELLING PROPERTIES OF SUPER-ABSORBENT POLYMER

A super-absorbent polymer is prepared by graft polymerizing acrylamide (AM) onto potato starch using eerie ammonium nitrate (CAN) and N, N'-methylene-bis-acrylamide (bisAM) as an initiator and cross-linking agent respectively, and then subjecting the potato starch- poly(acrylamide) (PAM) graft copolymer (SPAM) to alkaline saponification. The water absorbency (WA) of the sample is nearly 5000 g H2O/g for dry sample in 24 h at room temperature and is far larger than that of reported in the literature([1]). The variables affecting the WA were investigated and optimiz;ed, they were: concentrations of potato starch, AM, CAN and bisAM were 26.3 g/L, 1.14 mol/L, 10.3 mmol/L and 0.53 mmol/L, respectively. The amount of sodium hydroxide was 15 g and the temperatures of graft copolymerization and saponification reactions were 60 degrees C and 95 degrees C. The time of graft copolymerization and saponification reactions was 2 h, respectively.

土性对工程泥浆固化强度影响规律及微观机理

本文开展了一系列不同液限高分子吸水树脂固化工程泥浆无侧限抗压强度试验,探讨了泥浆土液限对固化效率的影响规律,对比研究了掺入高岭土对泥浆固化强度的改进程度,最后基于XRD和SEM试验揭示了液限和高岭土对固化泥浆强度影响的微观机理。结果表明:随着泥浆土液限的增大,固化泥浆土强度逐渐降低,固化效率随着泥浆土液限增大显著衰减,当液限增加10%,固化泥浆土强度qu平均减少48.2%。然而高岭土的掺入则显著提升了固化泥浆土的强度,并且强度增长率随着龄期逐渐增大,对于龄期为90天时,增加40%高岭土能够提升固化泥浆土强度qu 1.17倍。微观结构试验表明泥浆土液限变化对水化产物产量的影响较小,固化泥浆土强度随泥浆土液限减小主要是由于固化泥浆土孔隙随着泥浆土液限增大而增多,使得微观结构松散从而导致强度降低。高岭土的掺入则显著提升了固化泥浆土的水化产物产量,增强了固化泥浆土胶结强度,从而提升了固化泥浆土强度。因此,在实际工程中,一方面可以通过调配泥浆土液限来提高固化效率;另一方面可以通过掺入高岭土或者一些高岭土基废弃物(如高岭土尾矿)来提高固化强度,实现“以废制废”绿色环保的理念。

江阴靖江长江隧道大体积混凝土抗裂技术研究

江阴靖江长江隧道是国内在建最大直径盾构隧道,其明挖段主体结构混凝土最大厚度达2.2 m,面临着较大的开裂与渗漏风险。在水化与膨胀历程双重调控技术的基础上,进一步研究了高吸水树脂(SAP)的湿度历程调控对混凝土抗裂性能的影响。室内试验结果表明,SAP可显著提高自生体积膨胀变形并优化变形历程,且基本不影响胶凝材料水化放热历程;工程现场试验结果表明,在湿度、水化、膨胀历程多重调控作用下,混凝土温升值降低了4.5℃,温升阶段单位膨胀变形增大206.7%,温降阶段单位收缩变形减小27.5%,为解决裂缝控制难度较大结构的收缩开裂难题提供了材料技术方案。

季冻区纳米SiO_(2)改性SAP路面混凝土的耐磨性

为解决季冻区高吸水性树脂(SAP)路面混凝土耐磨性下降的问题,通过耐磨性试验探索了纳米SiO_(2)(NS)对季冻区SAP路面混凝土磨损量的影响;采用压汞仪(MIP)和扫描电镜(SEM)研究了冻融前后NS改性SAP路面混凝土孔结构和微观形貌的变化,从细微观角度阐述其耐磨性的提升机理;并对其微观结构与耐磨性进行相关性分析。研究结果表明,经150次冻融循环之后,掺有3%NS的改性SAP路面混凝土在200 N磨耗负荷下的磨损量较基准下降30.92%,20~50nm的孔占比上升,50~200nm的孔占比下降,总孔隙量和孔隙率减少,界面区裂缝数量和尺寸大幅降低,内部密实性程度显著提高,耐磨性明显增强。

Super absorbent polymer seed coatings promote seed germinationand seedling growth of Caragana korshinskii in drought

Coating seeds with water absorbent materials can improve their survival, especially for those planted in drought or barren areas. In this study, effects of five kinds of super absorbent polymers(SAPs) on seed germination and seedling growth of Caragana korshinskii under drought conditions were investigated. Our results showed that SAP coatings could significantly improve the percentage and energy of seed germination, as well as reduce the relative electrical conductivity(REC), proline, malondialdehyde(MDA), H_2O_2 content, and peroxidase(POD) activity during germination. These results implied that seeds could uptake moisture from SAP coatings to alleviate drought-induced oxidative stress and membrane damage, thus exhibiting a better vigor and germination performance. After coating C. korshinskii seeds with SAPs, more seedlings emerged and grew better. Under the combined influence of the water absorption capacity of SAP and other factors, the efficiencies of five SAP coatings are in the sequence D>E>B>A>C. The function of the SAP coating on promoting seedling survival was confirmed in Mu Us Sandy Land in Ordos, Inner Mongolia Autonomous Region, China. The average seedling number of SAP D-coated seeds increased twofold on that of naked seeds. Our results are expected to be helpful in understanding and utilizing SAP seed coatings in improving plant survival under drought conditions.

保水增肥措施对黄土丘陵区草地植物群落特征及物种多样性的影响

黄土丘陵区年均降水少,蒸发量大,季节性集中降水易造成水土流失,水分和养分亏缺成为限制该区域草地健康持续发展的重要因素。保水剂(super absorbent polymer, SAP)是一类具有快速吸水,缓慢释水特性的高分子聚合物,起到保水保肥改善土壤理化性质的重要作用。施肥是改良退化草地、提高牧草生产力的重要技术措施之一。为研究保水增肥措施对黄土丘陵区草地植物群落特征及多样性的影响,在甘肃省定西市安定区丘陵草地设置不同保水剂(SAP)和氮磷肥(N:尿素,P:过磷酸钙)添加水平(SAP:45、60 kg/hm^(2)和NP:150 kg/hm^(2)N+300 kg/hm^(2)P、250 kg/hm^(2)N+400 kg/hm^(2)P),揭示不同施量保水剂和氮磷肥单施及交互配施对黄土丘陵区草地土壤含水量、群落特征、物种多样性的影响。研究结果表明:(1)单施45 kg/hm^(2)SAP(T1)显著提高土壤含水量、豆科植物的重要值和地上生物量,有助于提高草地生物量和植物多样性;(2)SAP与NP配施(T7:45 kg/hm^(2)SAP+250 kg/hm^(2)N+400kg/hm^(2)P)或单施NP肥(T3:150 kg/hm^(2)N+300 kg/hm^(2)P)能显著提高植物冠层高度、植被盖度、菊科植物重要值和生物量、群落地上和地下生物量;(3)施用氮磷肥或氮磷肥与保水剂的配施处理除T8(250 kg/hm^(2)N+400kg/hm^(2)P+45 kg/hm^(2)SAP)外其余处理Simpson指数、Shannon-wiener指数及Pielou指数有所降低。综上所述,单施适量保水剂在维持草地多样性的同时有利于生产力缓慢增长,保水剂与氮磷肥配施大幅度提高菊科和禾本科植物生物量,进而提高群落生物量,但会导致植物多样性降低。

高吸水树脂改良煤矸石基质水分特性

【目的】探究不同质量分数的高吸水树脂(SAP)对矿区煤矸石基质容重、孔隙度、毛管水运移规律和保水性等方面的改善状况,阐明SAP最佳使用量下煤矸石基质的水分运移规律,为无土矿区煤矸石基质水分条件改善提供依据,实现矿区煤矸石固废资源化利用,为植被生长提供适宜条件。【方法】通过室内土柱试验模拟质量分数0%、0.1%、0.2%、0.3%和0.4%的SAP对煤矸石基质水分运移规律的影响。【结果】(1)SAP可以改善煤矸石基质物理性质,随SAP使用量的增加,煤矸石基质容重呈下降趋势,总孔隙度与毛管孔隙度呈上升趋势;(2)SAP会极显著抑制煤矸石毛管水上升高度,且质量分数在0%~0.4%范围内,随SAP使用量的增加抑制效果逐渐增强,但当SAP质量分数为0.4%时,对煤矸石毛管水抑制程度较0.3%差异不显著;(3)最小显著差异法拟合分析得到:煤矸石毛管水上升高度随时间变化呈幂函数增加趋势(P<0.01),上升速率与时间变化呈对数函数下降趋势;(4)在室内通风条件下,72 h内不同SAP质量分数的煤矸石基质含水率持续降低,纯煤矸石(SAP质量分数0%)基质含水率下降趋势最大,水分损失率为15.96%,SAP质量分数为0.3%与0.4%下降趋势较小,水分损失率分别为3.90%和3.52%,差异不显著,且作用时间越长,SAP的保水性能表现越突出。【结论】SAP可以改善煤矸石基质水分条件,且在一定范围内,含量越高改善效果越显著。因此从经济和效果两方面考虑,首选质量分数为0.3%的SAP应用于无土矿区煤矸石基质中,为植被生长提供适宜的水气条件。

超吸水聚合物对碱激发泡沫混凝土性能的影响

【目的】研究超吸水聚合物(super‐absorbent polymer,SAP)对提升以矿渣和再生微粉为主要材料的碱激发泡沫混凝土性能的影响。【方法】调节SAP预吸NaOH溶液的质量分数和SAP掺量(质量分数,下同),考察其对碱激发泡沫混凝土的流动性、吸水率、凝结时间、导热系数、孔隙结构及强度的影响;借助扫描电子显微镜和傅里叶红外光谱分析,从微观角度揭示SAP对泡沫混凝土性能影响机制。【结果】随着SAP掺量的增加,碱激发泡沫混凝土的流动度、凝结时间和导热系数呈下降趋势,但吸水率增大。SAP的掺入会导致碱激发泡沫混凝土孔隙率增大和孔隙分布的改变,掺入预吸水和预吸质量分数为0.4%的NaOH溶液的SAP后,增大了碱激发泡沫混凝土中孔隙直径大于550μm的孔隙比例;掺入预吸质量分数为0.9%的NaOH溶液的SAP后,则增大了碱激发泡沫混凝土中孔隙直径小于250μm的孔隙比例。适量的掺入SAP可以显著改善碱激发泡沫混凝土的抗压、抗折强度,当SAP预吸质量分数为0.4%的NaOH溶液且掺量为0.10%时,碱激发泡沫混凝土的抗压、抗折强度最高。【结论】SAP预吸NaOH溶液处理后,可以明显改善碱激发泡沫混凝土的工作性能、孔隙结构和力学性能。

水泥基材料自修复颗粒的制备及修复效果事前快速评价方法

针对多数水泥基材料自修复技术在渗漏水条件下修复物质被冲走、裂缝自修复效果难以达到预期且可修复裂缝宽度较窄的问题,本工作结合物理膨胀修复和化学反应修复的优点,以螯合处理的高吸水性树脂(Chelation super absorbent polymer,C-SAP)为物理修复剂,以反应修复剂(Reactive healing agents,RHA)和高性能混凝土膨胀剂(High performance calcium sulpho aluminate,HCSA)为化学修复剂,设计并制备了一种能在渗漏水条件下快速、高效修复裂缝的自修复颗粒,并改进了自制裂缝水渗透实验装置,开展了自修复颗粒修复效果的事前快速评价,最后采用X射线衍射分析方法分析了修复产物的物相组成。结果表明:自制裂缝水渗透实验装置能在将自修复颗粒应用于水泥基材料前有效且快速地评价颗粒的自修复效果,从而实现自修复颗粒组成的快速优选。当自修复颗粒中m(C-SAP)∶m(RHA)∶m(HCSA)=7.5∶32.5∶60,颗粒掺量为20%和30%时,其能够在672 h时完全封堵0.5 mm的裂缝;颗粒中的m(C-SAP)∶m(RHA)∶m(HCSA)=10∶30∶60且颗粒掺量为30%时,其能够在1008 h时完全封堵0.6 mm的裂缝。在裂缝修复早期,C-SAP解螯合并吸水膨胀,快速封堵裂缝,降低水流量;随后,化学修复物质通过化学反应生成白云石、钙矾石和方解石等结晶产物,从而将裂缝修复。

保水剂在牧草生产和草地沙化治理中的应用现状与前景

保水剂是一类具有快速吸水,缓慢释水特性的高分子聚合物,在传统农业生产中应用较多,但在牧草生产、天然草地恢复及生态建设等方面的研究报道较少。通过对国内外保水剂相关研究的分析,阐明保水剂的作用机制、保水剂在牧草生产及沙化治理中的作用效果和应用前景,旨为保水剂在牧草生产与生态建设中的应用提供参考。

基于材料种类的视角下SAP内养护水泥的基本性能研究

为了研究SAP种类对水泥性能的影响,将3种类型(B、C、D)SAP分别与P·S32.5级水泥和P·O42.5级水泥耦合作用,从宏观和微观两个角度对水泥的基本性能进行分析。结果表明:B类SAP优于C类和D类SAP;B类SAP能够提高水泥的胶砂抗折强度,降低抗压强度;C类和D类SAP均使得水泥胶砂强度降低。掺入SAP能够增加两种水泥的标准稠度用水量并延长初凝和终凝时间。SAP内养护作用能够在水泥浆体内部形成“储水释水库”,从而改善水泥的基本性能,为后续的工程应用提供理论依据。

高吸水性树脂对含再生骨料的水泥基材料自收缩性能影响及收缩预测研究

为研究含再生骨料水泥基材料的收缩性能并减小收缩率,利用非接触式自收缩仪探究了高吸水性树脂SAP掺量(0.1%~0.3%)、SAP粒径(30目、60目)对超早龄期、早龄期和长龄期下含再生骨料掺量(0%、50%、100%)水泥基材料自收缩性能影响。结果表明:1)再生水泥基材料的超早期(3 d内)自收缩率可达总收缩率的53.1%~91.6%,且自收缩率的控制效果与再生骨料掺量、SAP掺量、SAP粒径密切相关;2)100%再生骨料可将超早龄期(3 d)和长期(90 d)自收缩率分别提高53%~118%、36.2%~78.5%;3)50%再生骨料掺量下,0.1%~0.3%的SAP掺量范围内可将90 d自收缩率降低32.6%~53.9%,而100%再生骨料掺量下,仅0.3%的SAP才能起到减缩效果;4)SAP目数对自收缩率的削减效果受再生骨料掺量的敏感性高;5)BP神经网络能准确预测不同龄期自收缩率与再生骨料掺量、SAP掺量、SAP粒径的关系,基于此提出了低收缩再生水泥基材料的优化设计策略。

SAP和聚丙烯纤维双掺对混凝土抗压强度及抗渗性能的影响

隧道等地下工程混凝土主体结构渗漏为常见质量问题,严重影响结构的安全、正常使用功能及耐久性,因此混凝土的抗渗性能成为研究焦点。采用双掺SAP和聚丙烯纤维提高混凝土的抗渗性能,在混凝土中分别掺入质量比为胶凝材料0.1%,0.3%,0.5%的SAP,并同时分别加入1,2,3kg/m3的聚丙烯纤维,进行抗压与抗渗试验。结果表明:单掺0.1%~0.3%SAP时几乎不影响混凝土的抗压强度,但掺量为0.5%时,抗压强度会显著降低;双掺0.1%SAP和0~2kg/m3聚丙烯纤维可略微提升混凝土抗压强度,并且显著改善其抗渗性能;经对比,掺入0.1%~0.3%SAP和0~2kg/m3聚丙烯纤维时,可保证混凝土的抗压强度,提高抗渗性能,有效降低混凝土的渗水风险。

高岭土改性聚丙烯酸钠型高吸水性树脂对砂浆性能的影响

通过反向悬浮聚合法将无机组分高岭土与有机组分聚丙烯酸钠型高吸水性树脂接枝聚合,分析其粒径分布和吸水倍率,确定较为合适的高岭土添加量。试验探究了不同高岭土含量的改性高吸水性树脂以及不同掺量的高岭土改性高吸水性树脂,对砂浆收缩及抗折强度、抗压强度的影响。结果表明,添加含有高岭土的高吸水性树脂有效降低砂浆的干燥收缩,但是高吸水性树脂的添加普遍降低砂浆的抗折、抗压强度,高岭土改性高吸水性树脂在砂浆中的合适掺量为0.2%。

适用植物根系生长观察的半固态凝胶配方筛选

【目的】植物根系是植物吸收土壤水分和养分的重要器官,研究植物根系有助于了解植物根系与地上部相互作用以及植物对环境变化的响应机制。本研究分析高分子吸水树脂(SAP)和卡波姆U20(U20)单配和复配的稳定性和植物生长安全性,尝试建立植物根系生长观察的半固态凝胶开放培养方法。【方法】借助根箱试验,以草本植物黑叶芋(Alocasia longiloba)和灌木鹅掌藤(Schefflera actinopylla)为试验对象,基于营养液和SAP与U20复配半凝胶配方,分析1/4 Hoagland’s营养液(CK)、0.3%SAP凝胶营养液(T1)、0.5%U20凝胶营养液(T2)、0.4%U20+0.3%SAP凝胶营养液(T3)和0.5%U20+0.2%SAP凝胶营养液(T4)的稳定性以及在这些培养介质中植物生长、叶片叶绿素、根系形态变化和养分吸收差异。【结果】放置5周后,各处理培养介质均没有观察霉变和长菌现象,T1、T2和T3出现水化或絮凝分层,T4与CK一样性质稳定且澄清透明。动态观察叶片叶绿素变化发现,同一时间内,鹅掌藤各处理SPAD值和总叶绿素含量均与CK无显著差异,黑叶芋各处理SPAD值也均与CK无显著差异(P>0.05)。与CK相比,T1和T2均对鹅掌藤和黑叶芋根系生长产生抑制作用,T1和T2处理鹅掌藤总根长分别显著降低了51.59%和47.48%(P<0.05),根表面积分别显著降低了30.59%和32.27%(P<0.05);黑叶芋总根长分别显著降低了44.72%和45.86%(P<0.05),根表面积分别显著降低了29.23%和27.75%(P<0.05)。T1和T2处理的鹅掌藤和黑叶芋的生物量累积以及氮磷钾吸收也显著低于CK。T3和T4中两种植物的总根长、根表面积、氮磷钾吸收和生物量累积均与CK无显著差异(P>0.05);与CK中根系多下垂于营养液不同,T4中根系舒展自然,侧根和细根均呈一定角度展开在半固态凝胶中,较好的模拟了根系在土壤介质的生长状态。【结论】0.5%U20+0.2%SAP凝胶营养液可在较长时间内保持稳定的半固态凝胶状态,较好满足了模拟植物根系在土壤中生长的要求,并且短时间内在该营养液中植物生长、叶片叶绿素、根系形态变化和养分吸收与纯营养液无显著差异,可考虑选择该凝胶配方来建立植物根系生长观察的半固态凝胶开放培养方法。

雨养区苹果园土壤理化性质和果实品质对CLP型抗旱塇土剂的响应

【目的】研究CLP型抗旱塇土剂对旱地苹果园土壤理化性质及果实品质的影响。【方法】采用田间试验,使用交联聚丙烯酰胺(丙烯酰胺-丙烯酸钾共聚物(CL-PAM-K,CLP))抗旱塇土剂,共设置4个处理:CK(0 g/株)、T1(150g/株)、T2(250g/株)和T3(350g/株)。通过测定土壤含水率、土壤养分、果实外观品质和营养品质,综合评价各处理对土壤理化性状和果实品质的影响。【结果】萌芽期T1处理0~20、20~40、40~60cm土层土壤电导率分别下降了5.70%、10.82%、19.64%。果实成熟期T1处理20~40、40~60 cm土层土壤含水率分别增加7.26%、39.12%,0~20、20~40、40~60cm土层土壤pH值分别下降了3.43%、1.38%、0.23%,果皮穿刺强度增加了16%。250 g/株抗旱塇土剂施用量提高了萌芽期0~20、20~40、40~60 cm土层土壤含水率和土壤速效氮量和0~20、40~60 cm土层速效钾量,350 g/株抗旱塇土剂施用量提高了萌芽期和成熟期0~20、20~40、40~60 cm土层速效磷量;250 g/株抗旱塇土剂施用量增加了苹果果实可溶性蛋白和总酚量。【结论】350 g/株抗旱塇土剂施用量为改善旱地苹果园土壤理化性质和提高果实品质的最佳保水剂施用量。