在煤油介质中TODGA的γ辐射分解及萃取性能研究

N,N,N’,N’-四辛基-3-氧戊二酰胺(N,N,N’,N’-tetraoctyl-diglycolamide,TODGA)是一种具有广泛发展前景的针对锕系核素萃取分离的酰胺荚醚类萃取剂。为研究TODGA在煤油介质中的γ辐照性能,研究采用超高效液相色谱手段,以煤油作稀释剂,研究了水相中不同硝酸浓度下γ吸收剂量对TODGA辐解的影响;评价了辐照后TODGA-煤油-3 mol·L^(-1)硝酸混合体系对碱土金属、镧系元素的萃取性能变化。研究表明:TODGA的辐解率随着体系中硝酸浓度的升高而逐渐下降,当水相添加4 mol·L^(-1)硝酸水溶液,相较于不含硝酸水溶液时可抑制18%程度的辐解。而吸收剂量的增加导致了TODGA辐解增加,当吸收剂量低于100 kGy时,TODGA的辐解程度为10%~40%;当吸收剂量为1000 kGy时,TODGA的辐解增加明显,辐解率高达70%。TODGA辐解主要由醚键断裂导致,在硝酸水溶液的作用下改变辐解路径,还会发生辛基侧链的断裂。TODGA对碱土金属元素Sr的初始萃取率为25%,吸收剂量为100 kGy时几乎不萃取Sr,而其对镧系元素(Ce、Eu、Dy)的萃取率接近100%。

Me-TODGA与TODGA萃取锶性能对比

以N,N,N′,N′-四辛基-2-甲基-3-氧戊二酰胺(Me-TODGA)或N,N,N′,N′-四辛基-3-氧戊二酰胺(TODGA)为萃取剂、磷酸三丁酯(TBP)为相改良剂、煤油为稀释剂,对比研究了水相酸度、萃取剂浓度、锶浓度、温度对Me-TODGA-TBP体系和TODGA-TBP体系萃取Sr^2+的影响,并采用斜率法确定了萃合物的组成。结果表明,2种酰胺荚醚萃取Sr^2+的分配比(DSr)随HNO3浓度(c(HNO3)=0.1~2.7mol/L)、萃取剂浓度(c(萃取剂)=0.05~0.3mol/L)的增加而增大,随Sr^2+浓度的升高略有下降,随温度的升高而下降。2种萃取剂的萃合物组成分别为Sr(NO3)2·3Me-TODGA和Sr(NO3)2·2TODGA。萃取反应的ΔH分别为-69.46kJ/mol和-51.39kJ/mol,ΔS分别为-190.5J/(mol·K)和-128.4J/(mol·K),ΔG分别为-12.68kJ/mol和-13.12kJ/mol。相比之下,Me-TODGA萃取Sr2+的分配比不到TODGA的1/5。

TODGA-DHOA体系从硝酸介质中萃取碱土金属

合成了新型酰胺类萃取剂N,N,N′,N′-四辛基-3-氧戊二酰胺(TODGA)和N,N-二己基辛酰胺(DHOA),研究了以正十二烷为溶剂时,该萃取体系在硝酸介质中对碱土金属的萃取行为,考察了萃取体系变化、酸度、金属离子强度、盐析剂离子强度及温度对萃取分配比的影响。同时对萃合物的化学组成及萃取机理进行了分析和讨论。研究结果表明:TODGA与M(Ⅱ)形成的萃合物分子为M(NO3)2.2TODGA(org);在293K时,TODGA萃取Sr(Ⅱ)的ΔG=(-2.08±0.06)kJ/mol,ΔH=(-24.30±1.45)kJ/mol,ΔS=(-75.80±4.74)J/(mol.K)。在萃取过程中没有形成三相,提出了从高放废液(HLLW)中分离回收Sr的初步方案。

TODGA-DHOA体系萃取金属离子 Ⅲ.对Am(Ⅲ)和三价镧系离子的萃取

研究了以N,N,N’,N’-四辛基-3-氧戊二酰胺(TODGA)和N,N-二己基辛酰胺(DHOA)为萃取剂、正十二烷为稀释剂对Am(Ⅲ)和三价镧系元素的萃取行为,主要考察了萃取剂浓度、HNO3浓度、NaNO3浓度、金属离子浓度和温度的影响。结果表明:随着TODGA浓度的增加,TODGA/正十二烷和TODGA-DHOA/正十二烷两种萃取体系对Am(Ⅲ)和三价镧系元素的萃取分配比显著增加,DHOA对三价锕系和镧系萃取能力很弱,而DHOA的加入,对TODGA/正十二烷萃取Am(Ⅲ)和三价镧系元素具有一定抑制作用。TODGA萃取三价镧系元素的分配比随着镧系原子序数的增加而增加,Am的分配比与Eu相近。TODGA萃取稀土元素是放热反应,萃取过程中焓变起主导作用,吉布斯自由能变(-ΔG)变化的规律也表明随着镧系原子序数的增加,TODGA对其萃取能力增强。通过对TODGA萃取Am(Ⅲ)和三价镧系元素机理探讨,得到萃取反应方程式均为:M3+aq+3NO-3,aq+3TODGAorg→M(NO3)

TODGA-DHOA体系萃取金属离子 Ⅰ.对Np(Ⅳ,Ⅴ,Ⅵ)的萃取

次锕系核素(主要为Am、Cm和Np)是放射性废物中长期放射性毒性的最大贡献体,将这些次锕系核素从废物中去除后可以将必要的储存时间由原来的大于106年减少到不到103年。近年来,二甘醇二酰胺(两个酰胺基团之间通过醚基连接)作为三齿试剂与金属离子配位得到了广泛的研究。在这类试剂中,N,N,N′,N′-四辛基-3-氧戊二酰胺(TODGA)被认为从高放废液(HLLW)中分离三价锕系和镧系具有较大的应用前景。本工作以TODGA和N,N-二己基辛酰胺(DHOA)为萃取剂,研究了以正十二烷为稀释剂,二者对Np(Ⅳ)、Np(Ⅴ)和Np(Ⅵ)的萃取行为,主要考察了萃取剂浓度、HNO3浓度和NaNO3浓度的影响。结果表明:TODGA和DHOA对Np(Ⅳ)、Np(Ⅴ)和Np(Ⅵ)的萃取分配比大小顺序均为:D(Np(Ⅳ))>D(Np(Ⅵ))>D(Np(Ⅴ)),并且均对Np(Ⅴ)的萃取能力较小;TODGA/正十二烷体系中加入DHOA时,对Np(Ⅳ,Ⅴ,Ⅵ)萃取具有一定的反协同效应;TODGA萃取Np(Ⅳ,Ⅴ,Ⅵ)的方程式分别为:Np4+(aq)+4NO-3(aq)+3TODGA(org→)Np(NO3)4.3TODGA(org)NpO+2(aq)+NO-3(aq)+TODGA(org→)NpO2(NO3).TODGA(org)NpO2+2(aq)+2NO-3(aq)+2TODGA(org→)NpO2(NO3)2.2TODGA(org)

TODGA/正十二烷萃取Sr(Ⅱ)的动力学

以N,N,N′,N′-四辛基-3-氧戊二酰胺(TODGA)为萃取剂、正十二烷为稀释剂,研究了该萃取体系在恒界面池中萃取Sr(Ⅱ)的动力学,考察了搅拌转速、界面面积、萃取剂浓度、金属离子浓度、酸度和温度等因素对萃取行为的影响,并推导了相应的萃取机理。结果表明:(1)搅拌转速在130r/min以下时,0.1mol/LTODGA/正十二烷萃取Sr(Ⅱ)的过程为扩散控制类型,在搅拌转速为150r/min以上时,则可能属于化学反应控制的动力学控制模式;(2)求得了在(170±2)r/min、温度为(25±0.1)℃时0.1mol/L TODGA/正十二烷萃取Sr(Ⅱ)的初始速率方程:r0=dcorg(M)dt|t=0=k.SVc0.91aq,0(Sr)c0.73aq,0(HNO3)c0.87org,0(TODGA)在25℃下,求得表观萃取速率常数k=(22.5±2.5)×10-3mol-1.51.L1.51.min-1.cm;(3)0.1mol/L TODGA/正十二烷萃取Sr(Ⅱ)的初始速率随着温度的升高而增大,求得表观萃取活化能Ea(Sr(Ⅱ))=(24.3±0.7)kJ/mol。

TODGA-DHOA体系萃取金属离子 Ⅱ.对Pu(Ⅲ,Ⅳ,Ⅵ)的萃取

研究了以N,N,N′,N′-四辛基-3-氧戊二酰胺(TODGA)和N,N-二己基辛酰胺(DHOA)为萃取剂,正十二烷为稀释剂体系对Pu(Ⅲ)、Pu(Ⅳ)和Pu(Ⅵ)的萃取行为,主要考察了萃取剂浓度、HNO3浓度和NaNO3浓度的影响。结果表明:TODGA和DHOA对Pu(Ⅲ)、Pu(Ⅳ)和Pu(Ⅵ)的萃取分配比大小顺序均为:D(Pu(Ⅲ))>D(Pu(Ⅳ))>D(Pu(Ⅵ)),TODGA/正十二烷体系中加入DHOA时,对Pu(Ⅲ,Ⅳ,Ⅵ)萃取具有一定抑制作用,但在较高酸度范围内(≥3.0mol/L HNO3),不论体系中Pu的价态为何种形式,TODGA均能对其进行有效的回收。TODGA萃取Pu(Ⅲ,Ⅳ,Ⅵ)的方程式分别为:Pu3++3NO-3a+4TODGA。→Pu(NO3)3.4TODGA。Pu4+a+4NO-3a+3TODGA。→Pu(NO3)4.3TODGA。PuO2+2a+2NO-3a+2TODGA。→PuO2(NO3)2.2TODGA。

TODGA/正十二烷萃取Am(Ⅲ)的动力学

以N,N,N′,N′-四辛基-3-氧戊二酰胺(TODGA)为萃取剂,正十二烷为稀释剂,研究了该萃取体系在恒界面池中萃取Am(Ⅲ)的动力学,考察了搅拌转速、两相界面面积、萃取剂浓度、金属离子浓度、酸度和温度等因素对Am(Ⅲ)萃取行为的影响,并推导了相应的萃取机理。结果表明:(1)搅拌转速在130r/min以下时,0.1mol/L TODGA/正十二烷萃取Am(Ⅲ)的过程为扩散控制类型,在搅拌转速为150r/min以上时,则属于化学反应控制的动力学控制模式;(2)求得了在(170±2)r/min、温度为(25±0.1)℃时0.1mol/L TODGA/正十二烷萃取Am(Ⅲ)的初始速率方程:r0=dcorg(M)dtt=0=k·SVc0.94aq,0(Am)c1.05aq,0(HNO3)c1.19org,0(TODGA)在25℃下,求得表观速率常数k=(24.2±3.4)×10-3mol-2.18.L2.18.min-1.cm;(3)0.1mol/L TODGA/正十二烷萃取Am(Ⅲ)的初始速率随着温度的升高而增大,求得表观活化能Ea=(25.94±0.98)kJ/mol。

TODGA和DHOA的γ辐照稳定性研究

N,N,N’,N’-四辛基-3-氧戊二酰胺(TODGA)/N,N-二己基辛酰胺(DHOA)/正十二烷被认为是一种具有前景的高放废液萃取分离体系,为了解该体系的辐照稳定性,采用高效液相色谱等手段,分别研究了三者单一和混合情况下的γ辐照稳定性。结果表明:γ辐照剂量在0~1 000kGy范围内,正十二烷和DHOA未见明显辐射降解;吸收剂量小于100kGy时,TODGA辐射降解不明显;吸收剂量大于200kGy时,TODGA浓度迅速降低,但向TODGA/正十二烷体系中加入一定浓度的DHOA后,TODGA的耐辐照能力明显增强。0.1mol/L TODGA-1.0mol/L DHOA-正十二烷体系经γ辐照后的萃取试验结果表明:辐照吸收剂量小于100kGy时,体系对二价碱土金属离子和三价稀土金属离子的萃取分配比均随辐照剂量增加而缓慢降低;辐照吸收剂量大于200kGy时,萃取分配比随辐照剂量增加而迅速下降。

硅藻土负载TODGA分离-电感耦合等离子体质谱法测定氧化铈中氧化钆、氧化铽

建立了硅藻土负载N,N,N′,N′-四辛基-3-氧戊二酰胺(TODGA)分离柱分离,电感耦合等离子体质谱法(ICP-MS)测定氧化铈中氧化钆、氧化铽含量的方法。试样用50%(体积分数)硝酸溶液和30%过氧化氢溶解,取含氧化铈50 mg的样品溶液导入自制的硅藻土负载TODGA的分离柱(连接一个蠕动泵,用于控制流量),用pH 1.5的硝酸溶液以2.0 mL·min^(-1)流量淋洗分离柱,直至淋洗液中铈的质量浓度小于1000μg·L^(-1)。用60 mL pH 0.92的盐酸溶液以2.0 mL·min^(-1)流量反洗待测元素钆和铽,弃去前20 mL反洗液,收集后40 mL反洗液并用水稀释至50 mL。在线加入10μg·L^(-1)铯内标溶液,用ICP-MS分析样品溶液中目标物的含量。结果显示,氧化钆、氧化铽的质量浓度均在50.00μg·L^(-1)以内与其对应的待测元素与内标元素强度比值呈线性关系,检出限(3s)分别为0.102,0.049μg·g^(-1)。方法用于实际样品分析,氧化钆和氧化铽的测定值分别为0.73,0.68μg·g^(-1),测定值的相对标准偏差(n=11)为4.8%和5.2%,加标回收率分别为101%和99.0%。

H2C2O4对TODGA萃取Nd3+的影响

以N,N,N′,N′-四辛基-3-氧戊二酰胺(TODGA)为代表的酰胺荚醚类萃取剂可以有效萃取高放废液中的An(Ⅲ)和Ln(Ⅲ),为防止Zr^4+、Pd^2+等裂片元素萃入有机相,通常需要加入H2C2O4作为水相络合剂,目前,H2C2O4对TODGA萃取Ln(Ⅲ)的影响尚未报道。本工作研究了HNO3、H2C2O4浓度对TODGA或TODGA+TBP体系萃取Nd3+的影响,同时测定了有机相中的H2C2O4浓度,并用紫外-可见吸收光谱分析了有机相中的H2C2O4与有机相中Nd^3+的配位情况。研究结果表明:HNO3浓度在1.0~3.0 mol/L的范围内,Nd3+的分配比D(Nd3+)随HNO3浓度的增加而增加;H2C2O4浓度在0.1~0.5 mol/L的范围内,D(Nd^3+)随H2C2O4浓度的增加而增加。HNO3浓度在1.0~3.0 mol/L的范围内,萃入有机相中H2C2O4浓度随HNO3浓度的增加而减小,且存在于有机相中的H2C2O4并未与有机相Nd3+配位。

TODGA/HNO_3萃取La^(3+)的界面性质

利用滴体积法研究了La^(3+)/HNO_3/N,N,N',N'-四辛基-3-氧戊二酰胺(TODGA)/稀释剂体系的界面性质,考察了TODGA浓度、液滴形成时间、稀释剂种类、La^(3+)浓度、体系温度、离子强度和溶液酸度等因素对体系界面性质的影响.实验结果表明,体系达到界面饱和吸附时间约为120 s,可认为体系达到萃取平衡;TODGA浓度不同时,界面张力也不同,进而判定界面饱和吸附物种亦不相同;极性较小的稀释剂体系的界面张力降低较大,按照正辛烷>环己烷>苯>甲苯次序降低;HNO_3对TODGA的质子化作用使其表面活性显著增强,故硝酸浓度增大导致界面张力降低;Na NO_3的存在降低了界面上游离萃取剂分子的浓度,致使界面张力增大.

Effect of radiolysis of TODGA on the extraction of TODGA/n-dodecane toward Eu(Ⅲ):an experimental and DFT study

N,N,N′,N′-Tetraoctyl diglycolamide(TODGA)is one of the most promising extractants tailored for high-level liquid radioactive waste treatment during nuclear fuel reprocessing.Theγ-radiolysis of TODGA(0.2 mol/L)in n-dodecane(n DD)solution with and without pre-equilibrated 3.0 mol/L HNO_(3)was investigated using HPLC and UPLC-QTOF-MS and compared with theγ-radiolysis of neat TODGA in this study.With increased absorbed doses,the concentration of TODGA decreased exponentially for the studied systems.Moreover,pre-equilibration with HNO_(3)(3.0 mol/L)slightly influenced theγ-radiolysis of TODGA in n DD.Seven radiolytic products generated from the rupture of the C–C,C–O,and C–N bonds in TODGA were identified in the studied extraction system.The influence ofγ-radiation on TODGA/n DD for the extraction of Eu(Ⅲ)was evaluated using the first combination of extraction experiments and density functional theory(DFT)calculations,in which the complexations of Eu(Ⅲ)with TODGA and its radiolytic products were systematically compared.Based on the radiolysis kinetic model of TODGA,the slope curve of the distribution ratio of Eu(Ⅲ)(D_(Eu))and the absorbed dose,and fluorescence titration analysis,the empirical equation of the absorbed dose and D_(Eu)was obtained successfully.Below 300 kGy,the experimental D_(Eu)agreed well with the obtained empirical equation for TODGA/n DD.Conversely,at a high absorbed dose,the experimental D_(Eu)was higher than the theoretical D_(Eu)based on the empirical equation because the radiolytic products of TODGA with similar coordination structures still possessed partial complexation toward Eu(Ⅲ),which was confirmed by DFT calculations.This work provides a method to predict the extraction distribution ratio of an irradiated extractant system and to understand the complex extraction process.

TODGA树脂小柱分离-多接收电感耦合等离子体质谱(MC-ICP-MS)法测定岩石样品中Nd同位素比值

通过改进岩石样品分析物Nd的化学分离,实现Nd同位素比值的准确分析,为研究青藏高原岩石成因,揭示物质来源提供技术支持。采用TODGA萃淋树脂分离基体及其与Nd相邻的稀土元素,用多接收电感耦合等离子体质谱(MC-ICP-MS)法测定Nd同位素比值,建立了简捷实用的地质样品中Nd同位素分析方法。样品经HF-HNO_(3)分解,HNO_(3)(3 mol/L)-H_(3) BO_(3)(0.12 mol/L)提取,上柱后,先用6 mL HCl(2.8 mol/L)淋洗干扰轻稀土,再用6 mL HCl(2.2 mol/L)淋洗分析物Nd,Nd淋洗液由MC-ICP-MS测定其同位素比值。分析国际岩石标准物质BCR-2、BHVO-2和AGV-2,所得^(143) Nd/^(144) Nd同位素比值(平均值±2σ)分别为0.512638±0.000007、0.512990±0.0000012和0.512792±0.000016,这些同位素数据在误差范围内,与推荐值和文献值完全一致。方法适合各种类型地质样品,为西藏不同地区不同岩石提供了可靠的Nd同位素分析数据。

含Fe等杂质溶液中TODGA树脂对Am吸附性能研究

采用浸渍法合成了TODGA-JZC树脂并进行表征,研究了接触时间、硝酸浓度、金属离子杂质含量等对TODGA-JZC、TODGA-JZF树脂吸附Am(Ⅲ)的影响以及Eu静态容量。结果表明:两种TODGA树脂均具有较好的耐酸性;两种树脂对^(241)Am吸附分配比随接触时间的增加而升高,60 min趋于平衡;Fe等金属离子杂质(0~20 g/L)对241Am的吸附分配比影响较小;随着硝酸浓度的升高,241Am的吸附分配比增加,4 mol/L硝酸时TODGA-JZC和TODGA-JZF树脂对^(241)Am的吸附分配比分别为6.8×10^(4)和1.2×10^(5)mL/g;在4 mol/L HNO_(3)、1 mg/mL Eu体系中,TODGA-JZC、TODGA-JZF树脂对Eu的静态容量分别为18 mg/mL、9 mg/mL。

Th(Ⅳ) and U(Ⅵ) removal by TODGA in ionic liquids:extraction behavior and mechanism,and radiation effect

Extraction behavior of thorium(Ⅳ) and uranium(Ⅵ) from nitric acid(HNO_3) was studied using N,N,N',N'-tetraoctyldiglycolamide(TODGA) as extractant in different ionic liquids, and isooctane as comparison.Slope analyses with varying HNO_3 concentrations and diluents revealed the extraction mechanism. With increasing length of alkyl chain and HNO_3 concentration, the extraction mechanism of TODGA/IL system changed from cation exchange to neutral complex and/or anion exchange,and the molar ratio between TODGA and metal ions varied gradually from 2:1 to 1:1 for Th(Ⅳ) and 3:1 to 1:1 for U(Ⅵ). The kinetics and thermodynamic studies of Th(Ⅳ)and U(Ⅵ) by the best TODGA/[C_2mim][NTf_2] system showed that the extraction equilibrium was reached within 2 h and extraction reactions were endothermic. Compared to TODGA/isooctane system, TODGA/[C_2mim][NTf_2]system presented higher radiation stability under c-irradiation. Therefore, it would have a promising application in spent fuel reprocessing.

TODGA-TBP-OK体系对Sr(Ⅱ)、Eu(Ⅲ)萃取性能的研究

通过实验研究了以TODGA为萃取剂、TBP为改良剂、煤油为稀释剂的萃取体系在酸性溶液中对Sr(Ⅱ)、Eu(Ⅲ)的萃取性能的影响因素。结果表明:料液中HNO_(3)浓度在0.1~3.4 mol/L范围内,Sr(Ⅱ)分配系数随酸度的升高而增大;0.05mol/L的TODGA对Eu(Ⅲ)的萃取能力远远大于Sr(Ⅱ),可以实现料液中Sr(Ⅱ)与Eu(Ⅲ)的有效分离;Sr(Ⅱ)的分配系数随着料液浓度的升高而略有降低;TODGA萃取Sr(Ⅱ)的反应为放热反应,Sr(Ⅱ)的分配系数随温度的升高而降低;TODGA对Eu(Ⅲ)的萃取能力较强,料液酸度、浓度及环境温度变化对Eu(Ⅲ)分配系数影响不明显。

Adsorption behavior of Zr(IV) and Hf(IV) on a silica-based macroporous TODGA adsorbent

In order to separate Zr(IV) and Hf(IV) in acidic solution,several kinds of silica-based macroporous adsorbents were synthesized.Their adsorption selectivity for Zr(IV) and Hf(IV) in HCl solution was investigated,and the TODGA adsorbent for the two elements had the largest adsorption difference.The effects of acid type,HCl concentration,and temperature on the adsorption behavior of Zr(IV) and Hf(IV) onto the TODGA adsorbent were conducted by batch experiments.It was found that H+exhibited a quite strong influence on adsorption capacity of Zr(IV) and Hf(IV).Isotherm fitting showed that the Langmuir model agrees well with the experimental data.The thermodynamic parameters indicate that the adsorption processes for both elements are endothermic reactions.The TODGA adsorbent had the higher adsorption selectivity for Zr(IV) over Hf(IV) and could be promising for their mutual separation.

TODGA负载硅藻土分离-ICP-MS法测定钕中铽、镝和钬量

采用硝酸低温溶解试样,通过将TODGA负载到硅藻土上制成色谱柱分离钕基体,然后使用ICP-MS测定铽、镝和钬量。确定在2.0 mL/min的流速,2.4%盐酸淋洗分离钕基体,淋洗体积不小于50 mL条件下分离基体后,选择2.0 mL/min的流速,pH=0.48盐酸反洗铽、镝、钬,收集的待测元素溶液使用ICP-MS测定铽、镝和钬量,测定下限为0.39μg/g、0.17μg/g和0.13μg/g。经精密度和加标回收试验,方法精密度即RSD分别为5.6%、5.8%和6.9%,加标回收率分别为106.0%、99.4%和96.4%。

Extraction and back-extraction behaviors of 14 rare earth elements from sulfuric acid medium by TODGA

The unique physical and chemical properties of rare earth elements lay the foundation for their extensive application. N,N,N’,N’ Tetra-octyl-3-oxopentanediamide(TODGA) is excellent in its ability of extracting rare earth elements and it is favored for green initiative. In this paper, the extraction and back-extraction of14 rare earth elements by TODGA were studied. Experiments show that in conditions of 6 mol/L sulfuric acid, the extraction temperature of 25 ℃,the phase ratio of 1:1 and 0.04 mol/LTODGA(aviation kerosene as the diluent), the extraction rates of 14 rare earth elements including lanthanum, cerium, praseodymium,neodymium, europium, gadolinium, terbium, dysprosium, holmium, erbium, thulium, ytterbium, lutetium, and yttrium were 99.00%-99.73%. Mixed with hydrochloric acid and nitric acid(HCl 3.5 mol/L, HNO30.5 mol/L), the recoveries of the 14 rare earth elements are 91.52%-99.91% when the extraction temperature is 25 ℃ and the ratio is 1:1. The following application is based on the optimum conditions above with practical samples(from the roasting production line of China North Rare Earth High-tech Company Limited) for extraction and back-extraction experiments. Experiments show that TODGA has excellent enrichment effect on 14 rare earth elements, the extraction rates are 91.36%-99.80%, the back-extraction rates are 87.29%-99.64% and the total recoveries are 81.19%-99.44%.