CN107459657A - 含配体的共轭微孔聚合物及其应用 - Google Patents
含配体的共轭微孔聚合物及其应用 Download PDFInfo
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Abstract
本发明涉及一种含配体的共轭微孔聚合物,由共轭微孔聚合物和铀络合配体通过共价键耦合得到,共轭微孔聚合物包括芳香环和/或杂环,铀络合配体选自含磷基团、含氮基团和含硫基团中的一种或几种。本发明还提供了上述含配体的共轭微孔聚合物作为铀吸附剂中的应用。本发明的含配体的共轭微孔聚合物可在强酸强辐射环境下吸附放射性元素铀。
Description
技术领域
本发明涉及环境保护领域,尤其涉及一种含配体的共轭微孔聚合物及其应用。
背景技术
铀是重要的核电原料,乏燃料中含有高浓度的铀,而从高放射性废液中回收铀并将其再利用,是核能可持续发展的重要保障。然而,乏燃料的高酸度、高辐射性是从中提取铀的主要难点和挑战。
目前乏燃料后处理的方法主要是液液萃取法,包括以CMPO和TBP为混合萃取剂的Purex流程,以HDEHP和TBP为萃取剂的CTH流程等。然而,液液萃取法存在着操作工序多,处理过程中会产生大量有机溶剂废液,萃取剂降解造成二次污染等问题。另外,固相吸附因其操作简单,吸附剂可重复利用等优点受到越来越多的关注。多数固体吸附剂主要是将功能化配体接到骨架材料上,然而很多固体吸附剂在受高剂量的辐照后,会导致一系列性能的下降甚至丧失。虽然一些无机材料虽可以耐受强辐照,但却不能实现在强酸下对铀的有效吸附和分离。
共轭微孔聚合物是一类由全共轭分子链围筑的、具有三维网络结构的、微孔型有机高分子材料。共轭微孔聚合物具有大比表面积,结构的可设计性等优点使其具备作为吸附剂的特点,同时其共轭特性使材料具有高的耐辐照性能。有文章报道过将乙酰半胱氨酸功能化的共轭微孔聚合物用于铀的吸附,其对铀的吸附容量达165mg/g,且对铀表现出优异的选择性,但上述材料只能在弱酸条件下实现对铀的吸附,当pH值小于3后,吸附效率下降显著。因此,发展具有高耐酸耐辐照性能的新型固体吸附剂对乏燃料萃取技术至关重要。
发明内容
为解决上述技术问题,本发明的目的是提供一种含配体的共轭微孔聚合物及其应用,本发明的含配体的共轭微孔聚合物可在强酸强辐射环境下吸附放射性元素铀。
本发明提供了一种配体的共轭微孔聚合物,由共轭微孔聚合物和铀络合配体通过共价键耦合得到,所述共轭微孔聚合物包括芳香环和/或杂环,所述铀络合配体选自含磷基团、含氮基团和含硫基团中的一种或几种。
从结构出发,含有芳香环结构的聚合物由于苯环上的π键能使个别电子接受的辐射能分散给π键上的所有电子,从而减少C-C键因受激发而发生的链断裂,而具有较好的耐辐照性能。共轭微孔聚合物作为骨架,其全共轭的结构能大幅度消耗辐射能量,有效保护配体因辐照引起的分解或变性;且聚合物结构的可设计性为修饰铀配体提供多种途径和方法,有利于在骨架上修饰一种或多种络合铀配体。同时,考虑到强酸条件下的使用,铀络合配体应具有较高化学稳定性,在强酸下能有效地络合铀。本发明的铀络合配体能在强酸下使用,可通过单体连接或后修饰的方法共价连接到聚合物骨架上,用于强酸强辐照环境中对铀的吸附。
进一步地,共轭微孔聚合物由第一单体和第二单体共聚得到,第一单体和第二单体独立地选自苯、苯衍生物、芴、芴衍生物、卟啉、卟啉衍生物、吡啶、吡啶衍生物、噻吩或噻吩衍生物。第一单体和第二单体为含有芳香环和/或杂环的二元、三元或四元化合物,通过耦合反应才能形成共轭微孔聚合物。
进一步地,含磷基团为膦酸基、磷酸酯基和磷氧基中的一种或几种。
进一步地,含氮基团为酰胺基和/或丙二酰胺基。
进一步地,铀络合配体包括以下基团中的一种或几种:
其中,R1、R2、R3、R4独立地选自烷基、氢、苯环或杂环基团。
进一步地,含配体的共轭微孔聚合物的合成方法包括以下步骤:
将第一单体和第二单体进行共聚反应,然后再与铀络合配体化合物进行反应,得到含配体的共轭微孔聚合物,铀络合配体化合物为膦酸、磷酸酯、磷氧化合物、酰胺或丙二酰胺化合物。
进一步地,含配体的共轭微孔聚合物的合成方法包括以下步骤:
将第一单体和铀络合配体化合物进行反应,然后再与第二单体进行共聚反应,得到含配体的共轭微孔聚合物,铀络合配体化合物为膦酸、磷酸酯、磷氧化合物、酰胺或丙二酰胺化合物。
进一步地,当铀络合配体化合物为磷酸酯时,含配体的共轭微孔聚合物的合成方法包括以下步骤:
将1,3,5-三溴苯、乙酸钾和联硼酸频那醇酯在催化剂的作用下,在100℃下搅拌反应,得到第一产物;将2,7-二溴芴和四丁基溴化铵在碱存在下,室温下反应,得到第二产物;将第一产物和第二产物在催化剂作用下,先在90℃下反应24h,再于120℃下反应72h,得到含配体的共轭微孔聚合物,其中催化剂为四(三苯基膦)钯(Pd(PPh3)4)。
进一步地,当铀络合配体化合物为酰胺时,含配体的共轭微孔聚合物的合成方法包括以下步骤:
将2,7-二溴芴、溴代乙酸乙酯在碱存在下,在室温下搅拌反应,得到第三产物;将第一产物和第三产物在碱和催化剂的作用下,先在90℃下反应24h,再于120℃下反应72h,得到含配体的共轭微孔聚合物,其中催化剂为Pd(PPh3)4。
进一步地,当铀络合配体化合物为膦酸时,含配体的共轭微孔聚合物的合成方法包括以下步骤:
将2,2'-联吡啶、双(1,5-环辛二烯)镍、1,5-环辛二烯混匀,向其中加入第一产物和第三产物,室温下反应,得到第四产物;将第四产物、多聚甲醛、盐酸、膦酸、冰醋酸混匀后,在90℃下反应,得到第五产物;将第五产物与亚磷酸三乙酯混匀后,回流反应24小时,得到第六产物;将第六产物在酸中回流反应,得到。反应后冷却至室温,收集沉淀并用THF,甲醇和水次三次后真空干燥,得到含配体的共轭微孔聚合物。
进一步地,当铀络合配体化合物为磷氧化合物时,含配体的共轭微孔聚合物的合成方法包括以下步骤:
将2,7-二溴芴、四丁基溴化铵在碱和烯丙基溴中混合,室温下反应,得到第七产物;将1,3,5-三炔基苯、第七产物在四(三苯基膦)钯、CuI和三乙胺的作用下,90℃下反应,得到第八产物;将第八产物和磷氧化合物在引发剂的作用下,在125℃下反应,得到含配体的共轭微孔聚合物。
本发明还要求保护上述含配体的共轭微孔聚合物作为铀吸附剂的应用。
进一步地,吸附剂用于强酸强辐射环境中。
进一步地,强酸的浓度为4-6mol/L;辐射强度为200-500KGy。
进一步地,强酸为硝酸。辐射由γ射线产生。
进一步地,在25-45℃下使用吸附剂吸附或分离铀。
本发明的化合物,引入具有高化学稳定性的铀配体,利用本发明的化合物,通过液液萃取法,能有效地从高浓度硝酸溶液中将铀萃取至有机层中,而且共轭结构能有效大幅度耗散辐射能量,有效保护配体因辐照引起的分解或变性。
借由上述方案,本发明至少具有以下优点:
本发明以共轭微孔聚合物为骨架,利用其能有效消耗辐射能量的特点,结合功能化配体(铀络合配体)实现在强酸强辐照环境中对铀的吸附和分离。
上述说明仅是本发明技术方案的概述,为了能够更清楚了解本发明的技术手段,并可依照说明书的内容予以实施,以下以本发明的较佳实施例并配合附图详细说明如后。
附图说明
图1是本发明实施例1中,含配体的共轭微孔聚合物的固体核磁测试结果;
图2是本发明实施例1中,含配体的共轭微孔聚合物的红外光谱图和X射线光电子能谱图测试结果;
图3是本发明实施例2中,不同条件对吸附剂吸附效率的影响;
图4是本发明实施例2中,不同盐的浓度对吸附剂吸附容量的影响;
图5是本发明实施例3中,辐照前后吸附剂的固体核磁及吸附容量的测试结果。
具体实施方式
下面结合附图和实施例,对本发明的具体实施方式作进一步详细描述。以下实施例用于说明本发明,但不用来限制本发明的范围。
实施例1 含膦酸酯配体的共轭微孔聚合物的制备
本实施例以膦酸酯配体修饰的共轭微孔聚合物的合成为例,具体方法如下:
(1)向1,3,5-三溴苯(790mg),乙酸钾(1.47g)和联硼酸频那醇酯(2.285g)混合物中加入20ml DMF,N2鼓泡20分钟后,向其中加入催化剂四(三苯基膦)钯(Pd(PPh3)4,89mg,得到混合溶液。将混合溶液在100℃下搅拌反应24小时后冷却至室温。然后用二氯甲烷和水萃取,取有机层用水洗三次后,用再无水硫酸钠干燥,过硅胶柱提纯(洗脱剂:10%EtOAc/石油醚),得到白色固体单体TDB。以上反应的反应路线图如下:
(2)将50g氢氧化钾溶于50ml水中,加入2,7-二溴芴(1.23g)和四丁基溴化铵(370mg),随后加入5ml 1,3-二溴丙烷。将上述混合物在氮气保护下室温搅拌反应25分钟后,用二氯甲烷萃取两次,有机层先水洗,再用1M HCl和饱和食盐水洗,最后用无水硫酸镁干燥。除去溶剂后,过硅胶柱提纯(洗脱剂:5%CH2Cl2/正己烷)得到白色固体F-1。将F-1(250mg)分散于3ml亚磷酸三乙酯中,氮气保护,在170℃下回流4个小时后减压蒸去过量的亚磷酸三乙酯,所得固体过硅胶柱(4%EtOH/CH2Cl2)得到单体F2,其核磁氢谱结果如下:1HNMR(CDCl3,400MHz),δ7.47(6H,m),3.92(8H,m),1.47(4H,m),1.17(12H,t,J=7.0Hz),0.85(4H,m)。以上反应的反应路线图如下:
(3)将TDB(131.8mg)和F2(295mg)溶于50ml DMF,氮气鼓泡30分钟后,加入5ml 1MNa2CO3溶液,再加入催化剂四(三苯基膦)钯(Pd(PPh3)4,25mg)。混合物在氮气保护下先在90℃下搅拌反应24小时,再120℃下搅拌反应72小时,冷却后用DMF、二氯甲烷分别洗三次,再用水透析后冷冻干燥,得到含配体的共轭微孔聚合物,以下简称CMP-EP。以上反应的反应路线图如下:
对合成的CMP-EP进行物化性质的表征,包括固体核磁,红外和X射线光电子能谱分析(XPS),结果如图1-2所示。图1(A)为CMP-EP的固相核磁13C谱,图1(B)为CMP-EP的固相核磁31P谱。从图1可看出,产物CMP-EP的各个碳都可以在13C固体核磁谱上找到对应的锋,同时,磷酸酯中磷对应的锋也可以在CMP-EP的31P谱上找到。图2(A)为CMP-EP的红外光谱图,图2(B)为CMP-EP的X射线光电子能谱图。图2(A)中,在2940cm-1处有C-C的伸缩振动峰;1250cm-1和1030cm-1分别对应磷酸酯上磷氧双键和磷氧单键的伸缩振动峰。图2(B)中,除了O 1s和C 1s的归属锋外,在133.2eV处还可以看到P 2p对应的锋。以上结果表明,采用上述方法可成功获得磷酸酯修饰的共轭微孔聚合物CMP-EP。
实施例2 强酸环境下铀的吸附
(1)称取1mg实施例1制备的CMP-EP分散于不同硝酸浓度的铀酰溶液中,在25℃下吸附平衡后过滤除去吸附剂,利用ICP-MS检测溶液中的铀含量,计算吸附效率。称取不同质量的CMP-EP分散于含6M HNO3的铀酰溶液中,吸附平衡后过滤掉吸附剂,检测溶液中铀浓度。结果如图3所示,图3(A)图示了硝酸浓度对吸附效率的影响,图3(B)图示了吸附剂CMP-EP的用量对吸附效率的影响。图3表明,本发明制备的磷酸酯修饰的共轭微孔聚合物在乏燃料的酸度范围(4-6M HNO3)有优异的吸附性能,吸附效率达90%左右。随着吸附剂用量的增加,其吸附效率随之增加。
(2)将实施例1制备的CMP-EP分散于含有不同硝酸钠浓度的铀酰溶液中,吸附平衡后滤掉吸附剂,检测溶液中的铀浓度。图4(A)图示了不同盐的浓度对吸附剂吸附容量的影响,结果表明,金属盐不会影响吸附剂的吸附性能,且金属盐的浓度对吸附剂的吸附性能的影响不大。
(3)模拟乏燃料的酸度环境及离子种类配置混合离子溶液,溶液中含有U、Zr、Sr、La、Co、Na、Nd、Sm、Cs、Ce、Cr、Zn、Gd、Ba、Ni元素(各离子浓度约为100ppm)。
然后称取一定质量的CMP-EP,将其分散于上述混合离子溶液中(混合后的溶液中,吸附剂浓度为1mg/mL),待吸附平衡(约两小时)后滤去吸附剂,检测溶液中各种离子的浓度。图4(B)给出了CMP-EP对不同离子的分配系数Kd,结果显示CMP-EP对铀的分配系数高达2375mL/g,远远大于其他金属离子的分配系数,说明CMP-EP能在多种离子存在的强酸溶液中选择性的分离吸附铀。
(4)此外,我们还考察了材料的重复性能。称取20mgCMP-EP,将其分散于铀酰的硝酸溶液中(混合后的溶液中,吸附剂浓度为1mg/mL,铀酰浓度为0.04mmol/L,硝酸浓度为6mol/L),待吸附平衡后离心(4000rpm,20分钟)分离得到吸附后CMP-EP,取上层离心液稀释通过ICP-MS检测吸附效率。吸附剂先用水洗3次,再向吸附后材料加入20mL洗脱液(5%NaOH溶液或1mol/L Na2CO3溶液)后搅拌过夜,离心分离出样品,用水洗样品至中性,再加入铀酰溶液进行第二次吸附。重复上述过程4次。结果如图4(C)所示。重复性实验表明,CMP-EP通过碱性洗脱机洗脱后,能有效的保持吸附剂对铀的高吸附效率,证明材料有优异的重复利用性能。
实施例3 强辐照环境下铀的吸附
将实施例1制备的CMP-EP置于空气中进行500KGy的γ射线辐照;另将实施例1制备的CMP-EP分散于6M硝酸溶液中进行500KGy的γ射线辐照。辐照后通过固体核磁及吸附实验考察CMP-EP的耐辐照性能,即将辐照后的CMP-EP加入铀酰溶液中,在25℃下吸附平衡后过滤除去吸附剂,测其吸附容量。结果如图5所示,图5(A)为CMP-EP辐照前后的固相13C谱;图5(B)为CMP-EP辐照前后的固相31P谱。图5(C)为CMP-EP辐照前后的吸附容量。对比辐照前后材料的固体核磁,吸附容量及选择性(图4(B))发现,CMP-EP具备优异的耐辐照性能,在γ射线辐照500KGy后,其吸附性能也没有明显变化。
实施例4 含酰胺配体的共轭微孔聚合物CMP-N的合成
以酰胺为配体,通过Suzuki耦合反应聚合得到共轭微孔聚合物CMP-N。
(1)单体F3的合成
将2,7-二溴芴(3.3g,10mmol)分散于50%NaOH水溶液(8mL)和DMSO(80mL)的混合溶液中,在0℃下逐滴加入溴代乙酸乙酯(5g,30mmol)的DMSO(10mL)溶液。滴加完毕后,混合溶液在室温下搅拌12小时。反应结束后,在冰浴下滴加10N HCl溶液(18ml),并搅拌30分钟。收集沉淀,用水洗三次后真空干燥,通过乙醇和二氯甲烷重结晶得到白色结晶固体F3。反应路线图如下,其中R=CH2CH3,CH2CH2CH3或苯基:
(2)CMP-N的合成
将实施例1制备的TDB(1eq)和F3(1.5eq)溶于50ml DMF,氮气鼓泡30分钟后,加入5ml 1M Na2CO3溶液,再加入催化剂四(三苯基膦)钯(Pd(PPh3)4,3%单体摩尔数)。混合物在氮气保护下先在90℃下搅拌反应24小时,再120℃下搅拌反应72小时,冷却后用DMF、二氯甲烷分别洗三次,再用水透析后冷冻干燥,得到含配体的共轭微孔聚合物CMP-N。反应路线图如下:
实施例5 通过后修饰方法合成含膦酸配体的共轭微孔聚合物CMP-CP
通过后修饰方法合成含膦酸配体的共轭微孔聚合物CMP-CP,具体反应路线见下图。
(1)CMP-C的合成
将2,2'-联吡啶(1eq),双(1,5-环辛二烯)镍[Ni(COD)2,1eq]和1,5-环辛二烯(COD,1eq)溶于无水THF和1,4-二氧六烷的混合溶剂中,随后加入TDB和F3,所得混合溶液氮气保护及在室温下搅拌过夜。反应后,溶液置于冰浴中,滴加6M HCl盐酸溶液,搅拌6小时。过滤收集沉淀,并依次用氯仿,THF,甲醇及水洗,真空干燥得到CMP-C。
(2)CMP-CCl的合成
将200mg CMP-C,0.5g多聚甲醛,10ml盐酸(37%),2ml膦酸(85%)和3ml冰醋酸依次加入安剖瓶中,密封后在90℃下反应三天。反应完成后,过滤收集沉淀,再用水和甲醇次三次后,真空干燥得到CMP-CCl。
(3)CMP-CEP的合成
称取200mg CMP-CCl,将其分散于10ml亚磷酸三乙酯中,所得悬浮液在氮气保护下回流24小时。反应后冷却至室温,收集沉淀并用THF,甲醇和水次三次后真空干燥,得到CMP-CEP。
(4)CMP-CP的合成
称取200mg CMP-CEP并分散于100g水和20ml浓盐酸中,所得悬浮液在氮气下回流两天后,收集沉淀并用水洗至中性,再用甲醇洗三次后真空干燥得到CMP-CP。
实施例6 以磷氧化合物为配体的共轭微孔聚合物CMP-P的合成
以磷氧化合物为配体的共轭微孔聚合物CMP-P的合成,具体路线图见下方。
本实施例也是先合成共轭聚合物骨架,再通过后修饰的方法街上磷氧化合物配体。
(1)F-3的合成
将2,7-二溴芴(1eq)和四丁基溴化铵(2eq)加入用氩气脱气后的DMSO(15ml),50%(w/w)NaOH(15ml)和烯丙基溴(10eq)的混合溶液中,反应溶液在氩气保护下室温搅拌两小时。反应后,加入叔丁基甲基醚(125ml)和去离子水(50ml),再搅拌15分钟。分出有机层,旋蒸除去溶剂后,过硅胶柱提纯(环己烷),所的固体用氯仿重结晶得到单体F-3。
(2)CMP-V的合成
将1,3,5-三炔基苯(1eq),F-3(1.5eq),四(三苯基膦)钯(5%F-3的摩尔量)和CuI(10%F-3的摩尔量)置于两口烧瓶中,加入10mlDMF和10ml三乙胺。溶液在90℃氮气保护下搅拌24小时。反应后冷却至室温,收集沉淀并用氯仿,甲醇和丙酮洗三次,在索氏提取器中用甲醇冲洗三天,真空干燥后得到CMP-V。
(3)CMP-P的合成
称取200mgCMP-V分散于20ml无水甲苯中,加入20mg AIBN和0.05mol R2PH(O)在125℃氩气保护下搅拌12小时。反应后冷却至室温,收集沉淀并用乙醇和水洗三次,真空干燥得到CMP-P。
以上所述仅是本发明的优选实施方式,并不用于限制本发明,应当指出,对于本技术领域的普通技术人员来说,在不脱离本发明技术原理的前提下,还可以做出若干改进和变型,这些改进和变型也应视为本发明的保护范围。
Claims (10)
1.一种含配体的共轭微孔聚合物,其特征在于:由共轭微孔聚合物和铀络合配体通过共价键耦合得到,所述共轭微孔聚合物包括芳香环和/或杂环,所述铀络合配体选自含磷基团、含氮基团和含硫基团中的一种或几种。
2.根据权利要求1所述的含配体的共轭微孔聚合物,其特征在于:所述共轭微孔聚合物由第一单体和第二单体共聚得到,所述第一单体和第二单体独立地选自苯、苯衍生物、芴、芴衍生物、卟啉、卟啉衍生物、吡啶、吡啶衍生物、噻吩或噻吩衍生物。
3.根据权利要求2所述的含配体的共轭微孔聚合物,其特征在于:所述含磷基团为膦酸基、磷酸酯基和磷氧基中的一种或几种。
4.根据权利要求2所述的含配体的共轭微孔聚合物,其特征在于:所述含氮基团为酰胺基和/或丙二酰胺基。
5.根据权利要求2所述的含配体的共轭微孔聚合物,其特征在于:所述铀络合配体包括以下基团中的一种或几种:
其中,R1、R2、R3、R4独立地选自烷基、氢、苯环或杂环基团。
6.根据权利要求2-5中任一项所述的含配体的共轭微孔聚合物,其特征在于,其合成方法包括以下步骤:
将所述第一单体和第二单体进行共聚反应,然后再与铀络合配体化合物进行反应,得到所述含配体的共轭微孔聚合物,所述铀络合配体化合物为膦酸、磷酸酯、磷氧化合物、酰胺或丙二酰胺类化合物。
7.根据权利要求2-5中任一项所述的含配体的共轭微孔聚合物,其特征在于,其合成方法包括以下步骤:
将所述第一单体和铀络合配体化合物进行反应,然后再与所述第二单体进行共聚反应,得到所述含配体的共轭微孔聚合物,所述铀络合配体化合物为膦酸、磷酸酯、磷氧化合物、酰胺或丙二酰胺类化合物。
8.权利要求1-5中任一项所述的含配体的共轭微孔聚合物作为铀吸附剂的应用。
9.根据权利要求8所述的应用,其特征在于:所述吸附剂用于强酸强辐射环境中。
10.根据权利要求9所述的应用,其特征在于:强酸的浓度为4-6mol/L;辐射强度为200-500KGy。
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CN108384530A (zh) * | 2018-01-31 | 2018-08-10 | 宁波激智科技股份有限公司 | 一种包裹量子点的咔唑基共轭微孔聚合物微球及其制备方法、一种量子点薄膜及其应用 |
CN109096456A (zh) * | 2018-08-20 | 2018-12-28 | 吉林师范大学 | 一种含卟啉基共轭微孔聚合物及其制备方法 |
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CN115197464A (zh) * | 2022-07-15 | 2022-10-18 | 东华理工大学 | 一种富含磷氧基聚酰胺酸气凝胶及其制备和应用 |
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CN108384530B (zh) * | 2018-01-31 | 2020-06-16 | 宁波激智科技股份有限公司 | 一种包裹量子点的咔唑基共轭微孔聚合物微球及其制备方法、一种量子点薄膜及其应用 |
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CN114618450A (zh) * | 2022-05-13 | 2022-06-14 | 北京石墨烯技术研究院有限公司 | 共轭微孔聚合物复合材料及其制备方法、吸附剂 |
CN115197464A (zh) * | 2022-07-15 | 2022-10-18 | 东华理工大学 | 一种富含磷氧基聚酰胺酸气凝胶及其制备和应用 |
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