实验一 1,2-二氯-1,2二氟乙烷分子几何构型及其计算
实验目的:
1. 2.
掌握分子几何构型的输入方法
掌握能量计算的方法及其结果进行分析
实验原理及步骤:
对于所给出的固定结构进行分析,使用单点计算能得到分子轨道,轨道能级,电荷分布,偶极矩,等信息。
实验数据记录和处理:
RR型1,2-二氯-1,2二氟乙烷的三种计算方法能量值比较
HF 6-31G(d) Total kinetic energy from orbitals= 1.193988377802D+03 HF STO-3G SCF Done: E(RHF) = -1181.19135160 A.U. after 5 cycles MP2 6-31G(d) Total kinetic energy from orbitals= 1.193951458646D+03
SS型1,2-二氯-1,2二氟乙烷的三种计算方法能量值比较
HF 6-31G(d) Total kinetic energy from orbitals= 1.193952433533D+03 HF STO-3G SCF Done: E(RHF) = -1181.19134809 A.U. after 5 cycles MP2 6-31G(d) Total kinetic energy from orbitals= 1.193951454773D+03
Meso型 1,2-二氯-1,2二氟乙烷的三种计算方法能量值比较
HF 6-31G(d)Total kinetic energy from orbitals= 1.193988377802D+03
HF STO-3G SCF Done: E(RHF) = -1181.19217941 A.U. after 5 cycles MP2 6-31G(d)Total kinetic energy from orbitals= 1.193949706777D+03
三种分子中各原子所带电荷之比较(HF6-31G) 1 2 3 4 5 6 7 8
三种分子中各原子所带电荷之比较(HF6-31G +d)
C H C H F F Cl Cl RR Atomic charge 0.036910 0.248896 0.036910 0.248896 -0.382480 -0.382480 0.096674 0.096674 SS 0.036872 0.248831 0.036872 0.248831 -0.382492 -0.382492 0.096789 0.096789 0.00000 MESO 0.029801 0.261731 0.029892 0.261739 -0.388968 -0.388926 0.097394 0.097338 0.00000 Sum Of Mulliken charges =0.00000 1 2 3 4 5 6 7 8
各型分子的偶极矩对比(DEBYE) RR SS MESO X=0.5432 X=0.0000 X=0.0021 Y=-0.0091 Y=0.0000 Y=0.0020 Z=-2.6744 Z=-2.7085 Z=0.0001 Tot=2.7290 Tot=2.7085 Tot=0.0029 C H C H F F Cl Cl SS M.CHARGES 0.142589 0.230156 0.142589 0.230156 -0.349875 -0.349875 -0.022870 -0.022870 RR 0.133047 0.241457 0.149974 0.235120 -0.346655 -0.346105 -0.017243 -0.049596 0.0000 MESO 0.136702 0.239319 0.136769 0.239316 -0.353706 -0.353667 -0.022354 -0.022379 0.0000 SumOfMulliken charges 0.0000
HOMO与LUMO轨道能量 构型 RR SS meso
EIGENVALUES = EIGENVALUES = EIGENVALUES = HOMO与LUMO轨道 31 (B)--O 32 (A)--O 33 (A)--O 34 (B)--V 35 (A)—V -0.49102 (B)--O -0.49099 (B)--O -0.49129 -0.48896 -0.47049 (A)--O (A)--O 0.14797 0.18233 (B)--V (A)—V -0.48895 -0.47044 (A)--O (A)--O 0.14794 0.18235 (A)--V (A)—V -0.48706 -0.47095 0.14848 0.18428
实验二 实验报告 丙烯分子几何构型的优化
实验目的和原理:通过几何构型的优化,寻找几何构型的最小值点,即得到平衡的构
型。
通过CALCULATE计算OPT,计算优化构型。 实验结果处理
一 计算方法与基组 HF/6-31G(d)
180度a型丙烯分子
Item Maximum RMS Maximum RMS Item Maximum RMS Maximum RMS Item Maximum RMS Maximum RMS Item Maximum RMS Maximum RMS Value Force Force Displacement Displacement Value Force Force Displacement Displacement Value Force Force Threshold 0.042111 0.010066 0.091234 0.036579 Threshold 0.006881 0.001935 0.062984 0.020443 Threshold 0.001493 0.000315 Converged? 0.000450 0.000300 0.001800 0.001200 Converged? 0.000450 0.000300 0.001800 0.001200 Converged? 0.000450 0.000300 0.001800 0.001200 NO NO NO NO YES YES YES YES NO NO NO NO NO NO NO NO Displacement 0.005786 Displacement 0.001649 Value Force Force Displacement Displacement Threshold 0.000301 0.000067 0.000961 0.000268 Converged? 0.000450 0.000300 0.001800 0.001200 SCF Done: E(RHF) = -117.066952286 A.U. after 12 cycles Convg = 0.2772D-08 -V/T = 2.0011
S**2 = 0.0000 (所记下的是满足收敛条件的能量值)
0度b型丙烯
Maximum RMS Maximum RMS Maximum RMS Force Force 0.042639 0.009704 0.000450 0.000300 0.001800 0.001200 0.000450 0.000300 NO NO NO NO NO NO Displacement 0.083480 Displacement 0.032809 Force Force 0.007534 0.001988 Maximum RMS Maximum RMS Maximum RMS Displacement 0.061117 Displacement 0.018919 Force Force 0.001019 0.000291 0.001800 0.001200 0.000450 0.000300 0.001800 0.001200 NO NO NO YES NO NO Displacement 0.006479 Displacement 0.002738 SCF Done: E(RHF) = -117.068173125 A.U. after 10 cycles Convg = 0.6819D-08 -V/T = 2.0006 S**2 = 0.0000 Maximum RMS Maximum RMS
SCF Done: E(RHF) = -117.068177488 A.U. after 9 cycles Convg = 0.2538D-08 -V/T = 2.0006 S**2 = 0.0000
Force Force 0.000277 0.000065 0.000450 0.000300 0.001800 0.001200 YES YES YES YES Displacement 0.000663 Displacement 0.000331 能量和偶极矩
类型 数据种类 能量 a型 180 b型 0 SCF Done: E(RHF) = SCF Done: E(RHF) = -117.066952286 A.U. after 12 -117.068177488 A.U. after cycles 9 cycles moment Dipole moment basis, (field-independent basis, Debye): X= 0.3054 Y=
偶极矩 Dipole (field-independent Debye): X= 0.3053 Y= 0.0284 Z= 0.0000 -0.0030 Z= 0.0000 Tot= 0.3067 Tot= 0.3053
实验四 几何构型优化----寻找过渡态
实验目的及原理