金属溶剂萃取的热力学研究 1.Er(NO_3)_3-TB -C_6H_(14) 体系2.CuSo_4-氨化P_(50)-16H_(14)体系

本文在溶液理论的基础上，用纯热力学方法研究了中性磷萃取剂-金属体系（TBP-Er(no_3)_3）和氨化P_(50)-金属体系（P_(50)-cus04）的平衡计算模型。对于TBP体系有下列萃取平衡Er(NO_3)_3 (a) + 3TBP_((0)) <-> Er(NO_3)_3. 3TBP_((0))对于氨化P50体系，在萃取剂大量过量下有下的平衡Er(NO_3)_3 (a) + 3TBP_((0)) <-> Er(NO_3)_3. 3TBP(0)对氧化P50体系，在萃取剂大量过量下有下的平衡Cu_((a))~(2+) + partial deriv H_2R_2_((0)) <-> Cu(HR_2)_2 + 2H~+。用Scatchard-hildebrand模型预测了C_6H_(24)-TBP二元体系的担力学性质，以近似地用于H_2O - 16H_4 - TBP三之体系，减少了实验工作量。用气相色谱法求得了三之体系H_2O - (6H_(14) - P_(50))的热力学平衡数据，由于改进了进样系统，使实验误差<2%。对二体系的水相，均采用Pitzer理论求算γ_(Er(WO_3)_3)，和γ_(Cn~(2+))。对有机相，用热力学关系求出了水，正已烷，萃取剂，的活度系数。实验结果用Scatchard-Hildebrand模型进行关联。使计算机上进行回归处理，求得萃取反应的热力学平衡常数Ka和萃合物的活度系数。计算中，将有效平衡常数进一步分解，以提出显函数项，并在图解数分中改进了计算方法，使得每条萃取等温成都解得到合理的积分值。Schatchard-Hildebrand模型能在较宽的有机相浓度区域应用。所得到的端值常数，可定性地分析各组分的相互作用。

First charge collection and position-precision data on the medium-resistivity silicon strip detectors before and after neutron irradiation up to 2x10(14) n/cm(2)

Test strip detectors of 125 mu m, 500 mu m, and 1 mm pitches with about 1 cm(2) areas have been made on medium-resistivity silicon wafers (1.3 and 2.7 k Ohm cm). Detectors of 500 mu m pitch have been tested for charge collection and position precision before and after neutron irradiation (up to 2 x 10(14) n/cm(2)) using 820 and 1030 nm laser lights with different beam-spot sizes. It has been found that for a bias of 250 V a strip detector made of 1.3 k Ohm cm (300 mu m thick) can be fully depleted before and after an irradiation of 2 x 10(14) n/cm(2). For a 500 mu m pitch strip detector made of 2.7 k Ohm cm tested with an 1030 nm laser light with 200 mu m spot size, the position reconstruction error is about 14 mu m before irradiation, and 17 mu m after about 1.7 x 10(13) n/cm(2) irradiation. We demonstrated in this work that medium resistivity silicon strip detectors can work just as well as the traditional high-resistivity ones, but with higher radiation tolerance. We also tested charge sharing and position reconstruction using a 1030 nm wavelength (300 mu m absorption length in Si at RT) laser, which provides a simulation of MIP particles in high-physics experiments in terms of charge collection and position reconstruction, (C) 1999 Elsevier Science B.V. All rights reserved.