利用XRD研究了ScMn2合金及其氢(氘)化物的晶体结构;利用Sieverts装置测量了合金的吸氢活化性能、P-C-T曲线及吸氢动力学曲线;利用热重-差热分析仪(TG-DSC)研究了ScMn2H3.6钝化后的放氢动力学.结果表明,ScMn2的氢(氘)化物保持了母合金C14型Laves相结构,吸氢造成的晶胞体积膨胀约为25%;ScMn2在室温常压下能与H(D)迅速发生反应,具有优异的活化性能;100kPa,298K时,1molScMn2合金的贮氢量和贮氘量分别约为3.7和3.6mol;ScMn2具有较低的吸、放氢滞后临界温度,优异的平台特征以及较低的平台压,适于H及其同位素贮存.与室温平台压对应的合金氢化物的△H和△S分别为-45kJ/mol和-80J/(K·mol);ScMn2在113kPa初始H2(D2)压强下吸氢(氘)动力学可用JMA模型描述,反应级数为0.4,吸氢和吸氘的表观活化能分别为(16±0.3)和(19±1.7)kJ/mol,此活化能的差异使ScMn2有可能用于H同位素分离;钝化后的合金氢化物在639K时能完全放氢,放氢的表观活化能为(144±14)kJ/mol.
参考文献
| [1] | Pebler A,Gulbransen E A.Electrochem Technol,1966;4:211 |
| [2] | Pourarian F,Fujii H,Wallace W E,Sinha V K,Kevin Smith H.J Phys Chem,1981;85:3105 |
| [3] | Moriwaki Y,Gamo T,Iwaki T.J Less-Common Met,1991;172:1028 |
| [4] | Li G,Nishimiya N,Satoh H,Kamegashira N.J Alloys Compd,2005;393:231 |
| [5] | Guo X M,Wu E D.J Alloys Compd,2008;455:191 |
| [6] | Li W H,Wu E D.J Alloys Compd,2012;511:169 |
| [7] | Dwight A E.Trans Am Soc Met,1961;53:479 |
| [8] | Park J M,Lee J Y.J Less-Common Met,1991;167:245 |
| [9] | Kost M E,Raevskaya M V,Shilov A L,Yaropolova E I,Mikheeva V I.Russ J Inorg Chem,1979;24:1803 |
| [10] | Griessen R,Driessen A,De Groot D G.J Less-Common Met,1984;103:235 |
| [11] | Shilov A L,Kost M E,Kuznetsov N T.J Less-Common Met,1985;105:221 |
| [12] | Hunter B A,Howard C J.LHPM:A Computer Program for Rietveld Analysis of X-ray and Neutron Powder Diffraction Patterns,ANSTO Report,1998 |
| [13] | Srinivas G,Sankaranarayanan V,Ramaprabhu S.Int J Hydrogen Energy,2007;32:2480 |
| [14] | Von Buch F,Lietzau J,Mordike B L,Pisch A,Schmid-Fetzer R.Mater Sci Eng,1999;A263:1 |
| [15] | Manchester F D,Khatamian D.Mater Sci Forum,1988;31:261 |
| [16] | Liu B H,Kim D M,Lee K Y,Lee J Y.J Alloys Compd,1996;240:214. |
| [17] | Wu E D,Li W H,Li J.Int J Hydrogen Energy,2012;37:1509 |
| [18] | Hu Z L.Hydrogen Storage Materials.Beijing:Chemical Industry Press,2002:441(胡子龙.贮氢材料.北京:化学工业出版社,2002:441) |
| [19] | Broom D P.Hydrogen Storage Materials.London:Springer-Verlag,2011:89 |
| [20] | Ohtani Y,Hashimoto S,Uchida H.J Less-Common Met,1991;172-174:841 |
| [21] | Srinivas G,Sankaranarayanan V,Ramaprabhu S.J Alloys Compd,2008;448:159 |
| [22] | Kissinger H E.Anal Chem,1957;29:1702 |
| [23] | Hu R Z,Shi Q Z.Thermal Analysis Kinetics.Beijing:Science Press,2001:1(胡荣祖,史启祯.热分析动力学.北京:科学出版社,2001:1) |
| [24] | Fang Y Z,Liao M S,Hu L L.Thermochim Acta,2006;443:179 |
| [25] | Hsieh Y C,Chou Y C,Lin C P,Hsieh T F,Shu C M.Aerosol Air Qual Res,2010;10:212 |
上一张
下一张
上一张
下一张
计量
- 下载量()
- 访问量()
文章评分
- 您的评分:
-
10%
-
20%
-
30%
-
40%
-
50%