Paraffin–CaCl_(2)·6H_(2)O dosage effects on the strength and heat transfer characteristics of cemented tailings backfill

The challenge of high temperatures in deep mining remains harmful to the health of workers and their production efficiency The addition of phase change materials (PCMs) to filling slurry and the use of the cold storage function of these materials to reduce downhole temperatures is an effective approach to alleviate the aforementioned problem.Paraffin–CaCl_(2)·6H_(2)O composite PCM was prepared in the laboratory.The composition,phase change latent heat,thermal conductivity,and cemented tailing backfill (CTB) compressive strength of the new material were studied.The heat transfer characteristics and endothermic effect of the PCM were simulated using Fluent software.The results showed the following:(1) The new paraffin–CaCl_(2)·6H_(2)O composite PCM improved the thermal conductivity of native paraffin while avoiding the water solubility of CaCl_(2)·6H_(2)O.(2) The calculation formula of the thermal conductivity of CaCl_(2)·6H_(2)O combined with paraffin was deduced,and the reasons were explained in principle.(3) The“enthalpy–mass scale model”was applied to calculate the phase change latent heat of nonreactive composite PCMs.(4)The addition of the paraffin–CaCl_(2)·6H_(2)O composite PCM reduced the CTB strength but increased its heat absorption capacity.This research can give a theoretical foundation for the use of heat storage backfill in green mines.

MgCl_(2)·6H_(2)O溶液对方镁石-镁铝尖晶石耐火材料性能的影响

以电熔镁砂和电熔镁铝尖晶石为原料,以18°Be’、24°Be’、30°Be’三种不同浓度的MgCl_(2)·6H_(2)O溶液和酚醛树脂为结合剂,制备方镁石-镁铝尖晶石耐火材料。以酚醛树脂为对照组,通过研究MgCl_(2)·6H_(2)O溶液对材料常温抗折强度、常温耐压强度、烧结性能、抗热震性能的影响,探明MgCl_(2)·6H_(2)O溶液对材料的作用机理。结果表明,在常温下MgCl_(2)·6H_(2)O溶液能与镁砂反应生成氯氧镁水泥(MOC),MOC在微观下表现为交错互锁的晶须结构,使得耐火材料在干燥后具有非常高的机械强度。当热处理温度为1 700℃、溶液浓度为24°Be’时,材料的常温耐压强度达到79.1 MPa,相较于酚醛树脂提高了58.2%;当热处理温度为1 700℃、溶液浓度为18°Be’时,材料的显气孔率达到16.8%,相较于酚醛树脂降低了13.4%。MgCl_(2)·6H_(2)O溶液浓度的增加有利于提高材料的断裂韧性。MOC和Mg(OH)_(2)在烧成过程中会分解产生活性MgO,促进材料的烧结。此外,分解产生的活性MgO呈类球状,它们分散填充在镁砂颗粒内部裂隙处,形成微孔结构,有利于减缓热震时的热应力冲击。

CO_(2)/C_(3)H_(6)O在金属氧化物耦合吡咯氮生物炭表面的共/竞吸附机理研究

本研究采用密度泛函理论,通过比较吸附量、吸附能以及态密度和电荷差分密度的分析,探究了不同金属氧化物耦合吡咯氮生物炭(CN5@MOx,MOx=ZnO、CaO、Na2O)表面CO_(2)与C_(3)H_(6)O(CO_(2)&C_(3)H_(6)O)的吸附机理。首先从CO_(2)/C_(3)H_(6)O单组分方面计算了其在CN5@MOx表面吸附量和吸附能,计算结果表明,在333 K、100 kPa时CN5@Na2O表面对CO_(2)/C_(3)H_(6)O单组分吸附量分别为3.65、15.34 mmol/g,吸附能分别为-145.86、-132.47 kJ/mol,均高于CO_(2)/C_(3)H_(6)O单组分在CN5@CaO及CN5@ZnO表面吸附。得出Na2O掺杂吡咯氮生物炭对CO_(2)/C_(3)H_(6)O单组分吸附效果最优。进一步研究了CO_(2)&C_(3)H_(6)O在CN5@MOx表面共/竞吸附及机理。计算结果表明,CO_(2)&C_(3)H_(6)O在CN5@Na2O、CN5@CaO、CN5@ZnO表面吸附存在临界温度(分别为333、353、393 K),超过临界温度以后CO_(2)&C_(3)H_(6)O共存体系在CN5@MOx表面吸附量较CO_(2)/C_(3)H_(6)O单组分有所提高。CO_(2)&C_(3)H_(6)O在CN5@Na2O、 CN5@CaO、 CN5@ZnO表面吸附能分别比CO_(2)或C_(3)H_(6)O单组分吸附时至少高141.59、112.77、31.75 kJ/mol,CN5@MOx表面对CO_(2)和C_(3)H_(6)O的吸附表现为协同促进作用,且CN5@Na2O对CO_(2)&C_(3)H_(6)O共同吸附效果最佳。采用电荷差分密度和态密度分析CO_(2)&C_(3)H_(6)O在CN5@MOx表面协同吸附作用机理,得出CO_(2)的吸附作用力是通过C_(3)H_(6)O与CO_(2)的间接相互作用产生的,Na2O中Na与C_(3)H_(6)O电子云重叠,发生电荷转移,增强了两者间相互作用力,CN5@Na2O表面C_(3)H_(6)O与CN5在p轨道主要共振峰结合能较CN5@ZnO低了3.43 eV,使得C_(3)H_(6)O在CN5@Na2O表面吸附最稳定。

相变储能材料CaCl_(2)·6H_(2)O的研究进展

综述了无机水合盐相变储能材料CaCl_(2)·6H_(2)O近年来的研究进展,指出过冷、相分离、低热导率和易泄漏问题是制约其发展的主要障碍。介绍了不同成核剂和增稠剂对CaCl_(2)·6H_(2)O过冷和相分离问题的改善,概述了提高热导率和解决泄漏问题的研究现状,总结了现阶段研究中的优点以及不足,并对相变储能材料CaCl_(2)·6H_(2)O未来的研究发展方向进行了展望。

基于氧同位素示踪技术的H_(2)O对SF_(6)电弧放电分解产物的影响研究

SF_(6)分解产物与SF_(6)开关设备故障放电类型和严重程度存在内在联系,可通过分解产物分析实现对开关设备的故障诊断。H_(2)O对SF_(6)电弧放电分解产物具有显著影响,但其影响规律及相关作用机制目前尚不清楚,严重制约了分解产物分析法的工程应用。为解决这一问题,文中搭建了SF_(6)开关设备电弧放电分解产物实验研究平台,利用H_(2)^(18)O作为示踪剂开展了电弧放电实验,利用气相色谱质谱联用仪分析了放电过程中和放电后含^(18)O同位素物质的变化规律,明确了电弧放电下SF_(6)分解产物的形成途径及H_(2)O对SF_(6)分解产物的影响,阐明了其深层化学反应机理。研究发现,H_(2)O会直接参与SOF_(2)、SO_(2)、SO_(2)F_(2)和CO_(2)的生成反应,化学反应机理的不同导致各物质的形成与演化规律具有显著差异。其中,SOF_(2)和SO_(2)F_(2)的生成主要由放电过程中发生的分解反应和复合反应主导,SO_(2)的生成主要由放电后发生的分子间反应主导,CO_(2)的生成则来自两者的共同作用。

AlCl_(3)·6H_(2)O在FeCl_(3)、CaCl_(2)、KCl及KCl–FeCl_(3)溶液中溶解度的实验及预测

如何将AlCl_(3)·6H_(2)O从众多组分中选择性地结晶分离是从煤矸石中提Al的关键,而AlCl_(3)·6H_(2)O在煤矸石酸浸体系中的热力学平衡数据对于结晶过程的控制至关重要。在25~85℃的温度范围内,测定了不同温度和溶液浓度下AlCl_(3)·6H_(2)O在FeCl_(3)、CaCl_(2)、KCl及KCl-FeCl_(3)溶液中的溶解度。实验发现温度对AlCl_(3)·6H_(2)O在所有溶液体系中溶解度的影响均不明显,溶解度只随温度的升高略有增加;溶液浓度是影响溶解度的主要因素,AlCl_(3)·6H_(2)O在所有溶液体系中的溶解度均随溶液浓度的升高而明显下降,分析其原因是由于溶液浓度的增大使得Cl^(–)同离子效应增强。为了提高OLI软件预测结果的准确性,对其嵌入Bromley-Zemaitis模型中“Al^(3+)–Cl^(-)”离子对的交互参数进行了修正。随后验证了修正模型的实用性,结果表明它可应用于AlCl_(3)·6H_(2)O在FeCl_(3)、CaCl_(2)及KCl的任意单、混溶液中溶解度的预测。

Experimental study on thermal and mechanical properties of tailings-based cemented paste backfill with CaCl_(2)·6H_(2)O/expanded vermiculite shape stabilized phase change materials

CaCl_(2)·6H_(2)O/expanded vermiculite shape stabilized phase change materials(CEV)was prepared by atmospheric impregnation method.Using gold mine tailings as aggregate of cemented paste backfill(CPB)material,the CPB with CEV added was prepared,and the specific heat capacity,thermal conductivity,and uniaxial compressive strength(UCS)of CPB with different cement-tailing ratios and CEV addition ratios were tested,the influence of the above variables on the thermal and mechanical properties of CPB was analyzed.The results show that the maximum encapsulation capacity of expanded vermiculite for CaCl_(2)·6H_(2)O is about 60%,and the melting and solidification enthalpies of CEV can reach 98.87 J/g and 97.56 J/g,respectively.For the CPB without CEV,the specific heat capacity,thermal conductivity,and UCS decrease with the decrease of cement-tailing ratio.For the CPB with CEV added,with the increase of CEV addition ratio,the specific heat capacity increases significantly,and the sensible heat storage capacity and latent heat storage capacity can be increased by at least 10.74%and 218.97%respectively after adding 12%CEV.However,the addition of CEV leads to the increase of pores,and the thermal conductivity and UCS both decrease with the increase of CEV addition.When cement-tailing ratio is 1:8 and 6%,9%,and 12%of CEV are added,the 28-days UCS of CPB is less than 1 MPa.Considering the heat storage capacity and cost price of backfill,the recommended proportion scheme of CPB material presents cement-tailing ratio of 1:6 and 12%CEV,and the most recommended heat storage/release temperature cycle range of CPB with added CEV is from 20 to 40℃.This work can provide theoretical basis for the utilization of heat storage backfill in green mines.

CaO-B_2O_3-CO_2-H_2O体系中合成Ca_2B_6O_(11)·H_2O

非线性光学晶体Ca2 B6O11·H2 O(或者 2CaO·3B2 O3 ·H2 O) ,Ca[B3 O5 (OH) ]的阴离子基团为(B3 O8) 7-。虽然 (B3 O8) 7-基团的 2级极化率小于 (B3 O6) 3 -和 (B3 O7) 5 -,但其结构中 ,每个(B3 O8) 7-基团的排列方位一致 ,有利于微观 2级极化率的叠加 ,并且其单位体积内含阴离子基团 (B3 O8) 7-的个数达到 0 .97× 1 0 -2 个 / 1 0 -3 nm3 ,其值是BBO ,LBO的 1 .5倍左右 ,因而仍具有较大倍频效应。该化合物中的阴离子基团 [B3 O7(OH) ]6-含有一个 (OH)基 ,(OH)基取代氧原子不仅对晶体的非线性系数影响不大 ,而且使 (B3 O8) 7-上的 4个终端氧原子分别与硼原子和氢原子相连 ,致使阴离子基团中无“孤氧”存在 ,即 (OH)基取代氧原子反而有利于晶体吸收边的紫移。在CaO B2 O3 H2 O水热体系中存在着如下反应 :3H3 BO3 [B3 O3 (OH) 4]-+H++ 2H2 O ( 1 )[B3 O3 (OH) 4]+H2 O [B3 O3 (OH) 5 ]2 -+H+( 2 )n[B3 O3 (OH) 5 ]2 -[B3 O4(OH) 3 ]n2n-+nH2 O ( 3)[B3 O4(OH) 3 ]2n-n [B3 O5 (OH) ]2n-n +nH2 O ( 4)方程 ( 3) ( 4)受温度控制和硼酸的浓度控制 ,方程 ( 1 ) ( 2 )还要受到pH值的影响。当体系中存在着CO2 时 ,由于CO2 与H2 O的作用气液两相中pH值均降低 ,在降低 [B3 O3 (OH) 5 ]2 -形成速度的同时 ,增加?

CaTiF_(6)·2H_(2)O:Mn^(4+)窄带红色荧光粉的发光性能及其高显指暖白光LED应用

报道了一种新型的Mn^(4+)掺杂水合六氟钛酸钙CaTiF_(6)·2H_(2)O:Mn^(4+)红色荧光粉,详细研究了基质的结构转变和荧光粉的发光性能及高显色指数(显指)暖白光LED应用。CaTiF_(6)·2H_(2)O:Mn^(4+)在130~200℃间脱水转化为CaTiF_(6):Mn^(4+),荧光光谱发生改变,重新吸附水分子可恢复到CaTiF_(6)·2H_(2)O:Mn^(4+),发光性能不可逆。重要的是,该荧光粉在较长波626 nm和635 nm处分别发射锐线极强的零声子线(ZPL)和ν6振动峰,色坐标为(0.701,0.299),更接近人眼敏感的红光边界650 nm(色坐标x~0.72,y~0.28),有助于提高暖白光LED的显色指数、拓宽背光源的色域。晶体结构和晶体场强度计算指出,Mn^(4+)在CaTiF_(6)·2H_(2)O:Mn^(4+)中占据低对称性的格位,所受到的晶体场强度较弱,Mn—F键的共价性较强。另外,通过表面疏水化显著提升了荧光粉耐湿性能,共掺小离子半径的Si^(4+)增强了荧光粉发光热稳定性。以CaTiF_(6)·2H_(2)O:Mn^(4+)作为红光成分,获得了高显色指数(R_(a)=90,R_(9)=68)的暖白光LED,在高品质的暖白光照明中具有潜在的应用。

二维异核配位聚合物{[Ag_(2)Fe(SCN)_(6)](C_(5)H_(6)N)(H_(2)O)}_(∞)的合成与晶体结构

合成了二维异核配位聚合物{[Ag_(2)Fe(SCN)_(6)](C_(5)H_(6)N)(H_(2)O)}_(∞)(化学式:C_(11)H_(8)Ag_(2)FeN_(7)OS_(6)),并对其结构进行了X射线表征.单晶衍射结果表明,该配合物属三斜晶系,空间群P1,晶包参数a=076285(4)nm,b=084576(4)nm,c=091531(3)nm,α=99953(2)°,β=99821(2)°,γ=95479(2)°,V=056836(4)nm^(3),Z=1.八面体配位的Fe(Ⅲ)中心通过六个1,1,3μ3 SCN^(-)和周围的三个Ag_(2)S_(2)环连接成二维的阴离子网状骨架结构,质子化的吡啶以阳离子的形式和水分子一起存在于晶体结构中.

H_(2)O浓度对填充床式反应器降解SF_(6)影响的实验研究

SF_(6)的强温室效应对全球气候的潜在影响已经引起了人们的高度担忧,对SF_(6)进行降解是处理SF_(6)的一种有效手段。文中基于填充床式反应器(PBR),针对系统中H_(2)O浓度对降解SF_(6)的影响进行了研究,并从降解效率与产物两个角度进行了分析。研究结果表明H_(2)O能够在PBR中产生大量的OH与H自由基,这些活性自由基能够与SF_(6)的初级分解产物进行次级反应从而促进其分解,提高了其降解率。实验发现,当SF_(6)体积分数为2%时,最有利于促进SF_(6)降解的水汽浓度为1%,其降解率达到95.69%。同时,H_(2)O的分解需要吸收环境中的自由电子,从而对PBR中的细丝放电存在抑制作用。H_(2)O浓度也对SF_(6)降解产物的体积分数与选择性存在较大影响,H_(2)O浓度的增加会使得最终生成物SO_(2)的体积分数增加,SOF_(4)体积分数降低;文中的研究增加了人们对于SF_(6)降解机理的理解,也为之后的工业应用作了铺垫。

超声强化NH_(3)-C_(4)H_(6)O_(6)-H_(2)O体系浸出氧化锌烟尘提锌工艺

采用响应曲面法优化超声强化NH_(3)-C_(4)H_(6)O_(6)-H_(2)O体系浸出氧化锌烟尘提锌工艺条件,分别考察超声功率、反应时间、酒石酸浓度、液固比四因素及其交互作用对锌浸出率的影响。结果表明,酒石酸浓度与液固比间的交互作用对锌浸出率影响最为显著。优化提锌工艺条件为:控制超声功率300 W、浸出时间30 min、氨水浓度7 mol/L、酒石酸浓度0.5 mol/L、液固比5∶1、浸出温度45℃、搅拌速度100 r/min,该优化条件下的锌浸出率可达80.05%,较常规浸出相比、超声条件下锌浸出率提高5.25个百分点;NH_(3)-C_(4)H_(6)O_(6)-H_(2)O体系下ZnFe_(2)O_(4)、Zn_(2)SiO_(4)、ZnS物相难浸出;羧酸根可与Zn^(2+)形成络合离子,强化锌浸出。

MgCl_(2)·6H_(2)O吸附储热材料储热微观机理及性能研究

在实现跨季节热量储存技术中,以水合盐作为储热材料的热化学吸附储热技术因其具有高储热密度、低能量损失以及可长期热储存几乎无热损失的优势,聚集了大批学者的目光,占据储热技术的关键地位。采用MgCl_(2)·6H_(2)O作为化学吸附材料,通过分子动力学模拟计算其热导率、质量扩散系数和吸附能的变化,在分子层面上探究整个系统储热过程中的微观作用形式。研究结果表明,随着温度的升高,MgCl_(2)·6H_(2)O的晶体密度呈现下降趋势。建立了热导率分子模型,计算得到体系的热导率在0.95 W/(m·K)左右。各粒子的扩散系数随着温度的升高而上升,其中H2O扩散系数最大,吸附能力随着粒子距离的增大而降低。

298.2 K四元体系MgCl_(2)+CaCl_(2)+AlCl_(3)+H_(2)O相平衡研究

为获取粉煤灰含铝溶浸液中铝与共存钙、镁之间的作用规律,采用等温溶解平衡法开展了298.2 K时四元体系MgCl_(2)+CaCl_(2)+AlCl_(3)+H_(2)O相平衡研究,测定了平衡液相组成及平衡液相密度,同时,绘制了该四元体系的干基相图、水图、密度-组成图。研究发现:298.2 K四元体系MgCl_(2)+CaCl_(2)+AlCl_(3)+H_(2)O稳定相图由2个共饱点、4个结晶区以及5条单变量曲线组成,有复盐溢晶石(2MgCl_(2)·CaCl_(2)·12H_(2)O)生成,为复杂四元体系。4个结晶区分别对应3个单盐结晶区MgCl_(2)·6H_(2)O、CaCl_(2)·6H_(2)O、AlCl_(3)·6H_(2)O和1个复盐结晶区2MgCl_(2)·CaCl_(2)·12H_(2)O,结晶区按照AlCl_(3)·6H_(2)O、MgCl_(2)·6H_(2)O、CaCl_(2)·6H_(2)O、2MgCl_(2)·CaCl_(2)·12H_(2)O顺序依次减小,对应AlCl_(3)·6H_(2)O溶解度最小,2MgCl_(2)·CaCl_(2)·12H_(2)O溶解度最大。

Analysis of Ground-state Zero-field Splitting for Mn^(2+) Ions in[Co(H_(2)O)]XY_(6) (X=Si,Sn,Pt;Y=F,Cl)

The electron paramagnetic spectra of trigonal Mn^(2+) centers in[Co(H_(2)O)_(6)]SiF6,[Co(H_(2)O)_(6)]SnF6,and[Co(H_(2)O)_(6)]PtCl6 crystals were studied on the basis of the complete energy matrices for a d5 configuration ion in a trigonal ligand field.When Mn^(2+) is doped in the[Co(H_(2)O)_(6)]SiF6,[Co(H_(2)O)_(6)]SnF6,and[Co(H_(2)O)_(6)]PtCl6 crystals crystals,there is a similar local distortion.The experimental results show that the local lattice structure around a trigonal Mn^(2+) center has an elongation distortion along the crystalline C3 axis.From the EPR calculation,the local lattice structure parameters R=2.278A,θ=52.6406? for[Co(H_(2)O)_(6)]SiF6,R=2.280,θ=52.4936° for[Co(H_(2)O)_(6)]SnF6 and R=2.244A,θ=53.0616? for[Co(H_(2)O)_(6)]PtCl6 were determined.

Platinum-Induced Pseudo-Zn-Air Reaction Massively Increases the Electrochemical Capacity of Aqueous Zn/V_(5)O_(12)·6H_(2)O Batteries

How to effectively improve Zn^(2+)-storage properties is now becoming an urgent issue in the development of high-energy-density aqueous zinc-ion batteries.Here,a new method is proposed to massively increase the electrochemical capacity of aqueous Zn/V_(5)O_(12)·6H_(2)Obatteries.By adding a small amount of platinum(Pt,1.5 wt.%)and keeping other factors constant,the V_(5)O_(12)·6H_(2)O-Pt electrodes deliver a much higher specific capacity(440 m Ah g^(-1)at 500 m A g^(-1))than do V_(5)O_(12)·6H_(2)Oelectrodes(270 m Ah g^(-1)at500 m A g^(-1)).The structural and morphological evolution of V_(5)O_(12)·6H_(2)Oduring cycling results in Zn^(2+)ion insertion/extraction and the formation/disappearance of the zinc hydroxyl complex(Zn_(4)SO_(4)(OH)_(6)·5H_(2)O,ZHS),where the latter is closely related to the surface redox reaction,promoting Zn^(2+)ion stripping/plating on the Zn anode and consequently leading to extra electron transfer.Electrochemical tests in the absence of oxygen reveal that the Pt additive has no contribution and is even counterproductive to electric conductivity but favors remarkable enhancement of the pseudocapacitance.Accordingly,it is apparent that a strong causal relationship exists between Pt and the ZHS.In consideration of the catalytic application for oxygen reduction,Pt is expected to play a vital role in enhancing the electrochemical capacity through the pseudo-Zn-air reaction.This finding introduces a new strategy for achieving high-performance aqueous zinc-ion batteries.

水热时间对水系锌离子电池正极材料HNaV_(6)O_(16)·4H_(2)O电化学性能的影响

本文利用水热法制备出纳米带状HNaV_(6)O_(16)·4H_(2)O,研究了水热反应时间对产物电化学性能的影响。首先采用XRD、SEM和TEM对HNaV_(6)O_(16)·4H_(2)O结构与形貌进行表征,然后利用电池测试仪和电化学工作站分析了HNaV_(6)O_(16)·4H_(2)O的电化学性能。研究结果表明:水热时间为18 h时,HNaV_(6)O_(16)·4H_(2)O纳米带的电化学性能最佳,在0.5 A·g^(-1)下拥有457 mAh·g^(-1)的高比容量,经过100次循环后其比容量仍可达434 mAh·g^(-1);在2 A·g^(-1)的大电流密度下循环2000次的比电容量为372 mA·g^(-1),容量保持率高达99.5%。

钒-砷氧簇合物[Zn_(2)(dien)_(3)]_(1/2){[Zn_(2)(dien)_(3)]As_(6)V_(15)O_(42)}·2H_(2)O的合成与晶体结构表征

本文以氯化锌、五氧化二钒以及三氧化二砷为原料,合成了[Zn_(2)(dien)_(3)]_(1/2){[Zn_(2)(dien)_(3)]As_(6)V_(15)O_(42)}·2H_(2)O,讨论了其晶体结构并进行了结构表征。

氯化铁［FeCl＿3·6H＿2O］样品的穆斯堡尔谱驰豫效应研究

本文利用穆斯堡尔谱技术，研究了ＦｅＣｌ＿３·６Ｈ＿２Ｏ样品的温度驰豫过程。随温度升高，驰豫频率加快，不对称双峰逐渐对称。四极劈裂逐渐减小，表明这一过程主要是由于顺磁自旋驰豫过程的作用，它不同于Ｇｏｌｄａｎｓｋｉｉ一Ｇａｒｇａｇｉｎ效应，由此可以区分电子顺磁自旋驰豫过程和ＧＯｌｄｓｋｉｉ一Ｇａｒｇａｇｉｎ效应。不对称线宽也可能由于样品厚度影响所致，但在本实验中可忽略这种效应。随温度升高，由Ｑ·Ｓ值突变可以判断相转点及物相转变点温度。

Mg(NO_(3))_(2)·6H_(2O)-Assisted insitu-Fabrication of Tea Residual Biochar for Ultra-Fast and High Adsorption of Rhodamine B

In this work,porous biochar(MN-TRB_(750))was fabricated via direct pyrolysis of tea residue(TR)and Mg(NO_(3))_(2)·6H_(2)O(MN).The as-synthesized MN-TRB_(750) reached a specific surface area of 839.54 m^(2)·g^(-1)and an average pore size of 3.75 nm with multi-level pore architecture.MN decreased TR's carbonization temperature and promoted the aromatics extent,pore structure for the frizzly flake-like biochar.Rhodamine B(RhB)was chosen as the adsorbate to explore the removal performance of organic dyes in this study.The results indicated that the maximum adsorption capacity of RhB on MN-TRB_(750) at 20℃ is up to 809.0 mg·g^(-1)with isotherms fitted well to Freundlich and Dubinin-Radushkevic models.The adsorption kinetics followed pseudo-second-order and Elovich models with an equilibrium adsorption capacity of 757.6 mg·g^(-1)as the initial concentration of RhB is 260 mg·L^(-1).High pore filling,hydrogen bond,π-πinteraction determined the adsorption of RhB onto MN-TRB850 through a multi-active center and exothermic chemical sorption process.