| 查看: 2364 | 回复: 8 | |||
| 当前只显示满足指定条件的回帖,点击这里查看本话题的所有回帖 | |||
[交流]
【求助】电子态1Δg,1∑+g,2p等怎么定义的,
|
|||
|
我最近看文献,一直看到这个。实在有点不明白这些电子态是什么意思。只知道它是电子态。望大侠们给我解析一下,必有重金酬谢 其他电子态的说明也可以在下面留言,与前几个电子态一视同仁,金币不是问题 求讲解 越详细越好 |
回复此楼» 猜你喜欢
已知面上挂了,小学校实验方向无平台,感觉太难了
已经有26人回复
-
求助立方晶体In(OH)3的CIF卡片
已经有2人回复
-
物理化学论文润色/翻译怎么收费?
已经有169人回复
-
求助各位大佬,球球了,在这科萨头
已经有0人回复
-
请问四氢呋喃溶解的聚合物用甲醇沉淀时,如何使沉淀过程加速?
已经有2人回复
-
[电子教材]天津大学物理化学(第七版)上、下册
已经有2人回复
-
阴离子交换膜电解二氧化碳还原
已经有0人回复
-
Chemical Bonding at Surfaces and Interfaces,最经典的一本表面上化学相互作用教材
已经有0人回复
-
九江学院2026年最新高层次人才招聘公告
已经有0人回复
-
深圳信息职业技术学院2026年教师招聘公告(最新)
已经有0人回复
» 本主题相关价值贴推荐,对您同样有帮助:
- 百鲜美食谱精典【转载】
已经有26人回复
- 罪与罚【陀思妥耶夫斯基】【已搜索无重复】
已经有37人回复
- 中外名人格言钢笔字帖(赵忱)【转载】
已经有61人回复
- 怎么根据态密度图积分算区间的电子数
已经有8人回复
- 金与什么有机物可以配合,且配合物整体呈正价态?
已经有4人回复
- 请教vulcanized rubber的定义
已经有6人回复
- flory分子量分布函数中定义t时基团反应概率为反应程度P,此处不懂,求助
已经有7人回复
- 脉冲筛板萃取柱中30块塔板可用周期边界条件简化定义边界么
已经有5人回复
- fluent中怎样定义边界层厚度和动量层厚度
已经有5人回复
- 晶界的表示:“Σ3”怎么定义的
已经有19人回复
- 等效位置的态密度分析
已经有9人回复
- ansys 13.0 网格划分和边界定义怎么设置,拜求高手
已经有13人回复
- 机械振动中的模态是怎么定义的
已经有7人回复
- 【求助】分子中是怎么定义成键态和反键态的
已经有18人回复
» 抢金币啦!回帖就可以得到:
-
湖南大学材料院陶益杰老师招收2026年秋季入学博士生一名及联合培养硕士学生一名
+1/199
-
Postdoctoral Research Fellow Position in Causal Inference Weill CorneIl Medicine
+1/92
-
黄汉民团队联合淮北师范大学招聘师资博士后(年薪30-40万)
+1/83
-
结构动力学与结构健康监测方向欧盟玛丽居里全奖博士招聘
+1/78
-
博后平台选择
+1/62
-
中国科学院深圳先进技术研究院——招聘博士后
+2/54
-
中国科学院深圳先进技术研究院——招聘客座研究生
+3/25
-
苏州大学招收申请考核制博士生、博士后(2026)
+1/21
-
武汉工程大学绿碳技术与智能材料课题组诚招2026年博士研究生
+2/16
-
新加坡 南洋理工大学- 智能光子/ 传感 PHD 全奖一名 2026 - 8 月入学
+1/15
-
中科院深圳先进院-免疫治疗方向-招收1名博士生(26年9月入学)
+1/10
-
青岛大学招收少数民族【少干计划】生物与医药博士研究生
+1/7
-
中国科学院深圳先进技术研究院——招聘博士后
+3/7
-
哈工大(深圳)物理招收2026年9月入学博士生1个名额
+1/7
-
推荐一款可以AI辅助写作的Latex编辑器SmartLatexEditor,超级好用,AI润色,全免费
+1/5
-
澳科大招收2026年秋季入学生物材料方向全奖博士研究生(3月5日截止)
+1/5
-
加氢裂化
+1/4
-
2026年博士申请考核+福州大学+管理科学与工程
+1/4
-
邵阳学院食品与化学工程学院硕士调剂
+1/3
-
武汉理工大学数学与统计学院张秀军教授课题组招收2026级秋季博士研究生
+1/3
★ ★
zhang302(金币+10): 很感谢呀,我是不太会用度娘 2011-04-01 09:11:58
小红豆(金币+2): 谢谢分享你的看法 2011-04-16 14:06:39
zhang302(金币+10): 很感谢呀,我是不太会用度娘 2011-04-01 09:11:58
小红豆(金币+2): 谢谢分享你的看法 2011-04-16 14:06:39
|
其实度娘真的很有用,动动手啥都有了 http://good.gd/1081561.htm |
4楼2011-03-31 19:51:38
2楼2011-03-31 11:39:19
3楼2011-03-31 15:37:45
★ ★ ★ ★ ★
zhang302(金币+10): 2011-04-01 09:10:58
小红豆(金币+5): 谢谢分享你的看法 2011-04-16 14:07:04
zhang302(金币+10): 2011-04-01 09:10:58
小红豆(金币+5): 谢谢分享你的看法 2011-04-16 14:07:04
|
In molecular physics, the molecular term symbol is a shorthand expression of the group representation and angular momenta that characterize the state of a molecule, i.e. its electronic quantum state which is an eigenstate of the electronic molecular Hamiltonian. It is the equivalent of the term symbol for the atomic case. However, the following presentation is restricted to the case of homonuclear diatomic molecules, or symmetric molecules with an inversion centre. For heteronuclear diatomic molecules, the u/g symbol does not correspond to any exact symmetry of the electronic molecular Hamiltonian. In the case of less symmetric molecules the molecular term symbol contains the symbol of the group representation to which the molecular electronic state belongs. It has the general form:  where * S is the total spin quantum number * Λ is the orbital angular momentum along the internuclear axis * Ω is the total angular momentum along the internuclear axis * u/g is the parity * +/− is the reflection symmetry along an arbitrary plane containing the internuclear axis For atoms, we use S, L, J and MJ to characterize a given state. In linear molecules, however, the lack of spherical symmetry destroys the relationship [\hat\mathbf L^2, \hat H]=0, so L ceases to be a good quantum number. A new set of operators have to be used instead: \{\hat \mathbf S^2, \hat\mathbf{S}_z, \hat\mathbf{L}_z, \hat\mathbf{J}_z=\hat\mathbf{S}_z + \hat\mathbf{L}_z\}, where the z-axis is defined along the internuclear axis of the molecule. Since these operators commute with each other and with the Hamiltonian on the limit of negligible spin-orbit coupling, their eigenvalues may be used to describe a molecule state through the quantum numbers S, MS, ML and MJ. The cylindrical symmetry of a linear molecule ensures that positive and negative values of a given ml for an electron in a molecular orbital will be degenerate in the absence of spin-orbit coupling. Different molecular orbitals are classified with a new quantum number, λ, defined as λ = |ml| Following the spectroscopic notation pattern, molecular orbitals are designated by a smallcase Greek letter: for λ = 0, 1, 2, 3,… orbitals are called σ, π, δ, φ… respectively. Now, the total z-projection of L can be defined as M_L=\sum_i {m_l}_i. As states with positive and negative values of ML are degenerate, we define Λ = |ML|, and a capital Greek letter is used to refer to each value: Λ = 0, 1, 2, 3… are coded as Σ, Π, Δ, Φ… respectively. The molecular term symbol is then defined as 2S+1Λ and the number of electron degenerate states (under the absence of spin-orbit coupling) corresponding to this term symbol is given by: * (2S+1)×2 if Λ is not 0 * (2S+1) if Λ is 0. Ω and spin-orbit coupling Spin-orbit coupling lifts the degeneracy of the electronic states. This is because the z-component of spin interacts with the z-component of the orbital angular momentum, generating a total electronic angular momentum along the molecule axis Jz. This is characterized by the MJ quantum number, where MJ = MS + ML. Again, positive and negative values of MJ are degenerate, so the pairs (ML, MS) and (−ML, −MS) are degenerate: {(1, 1/2), (−1, −1/2)}, and {(1, −1/2), (−1, 1/2)} represent two different degenerate states. These pairs are grouped together with the quantum number Ω, which is defined as the sum of the pair of values (ML, MS) for which ML is positive. Sometimes the equation Ω = Λ + MS is used (often Σ is used instead of MS). Note that although this gives correct values for Ω it could be misleading, as obtained values do not correspond to states indicated by a given pair of values (ML,MS). For example, a state with (−1, −1/2) would give an Ω value of Ω = |−1| + (−1/2) = −1/2, which is wrong. Choosing the pair of values with ML positive will give a Ω = 3/2 for that state. With this, a level is given by 2S + 1ΛΩ Note that Ω can have negative values and subscripts r and i represent regular (normal) and inverted multiplets, respectively.[1] For a 4Π term there are four degenerate (ML, MS) pairs: {(1, 3/2), (−1, −3/2)}, {(1, 1/2), (−1, −1/2)}, {(1, −1/2), (−1, 1/2)}, {(1, −3/2), (−1, 3/2)}. These correspond to Ω values of 5/2, 3/2, 1/2 and −1/2, respectively. Approximating the spin-orbit Hamiltonian to first order perturbation theory, the energy level is given by E = A ML MS where A is the spin-orbit constant. For 4Π the Ω values 5/2, 3/2, 1/2 and −1/2 correspond to energies of 3A/2, A/2, −A/2 and −3A/2. Despite of having the same magnitude, levels of Ω = ±1/2 have different energies associated, so they are not degenerate. With that convention, states with different energies are given different Ω values. For states with positive values of A (which are said to be regular), increasing values of Ω correspond to increasing values of energies; on the other hand, with A negative (said to be inverted) the energy order is reversed. Including higher order effects can lead to a spin-orbital levels or energy that do not even follow the increasing value of Ω. When Λ = 0 there is no spin-orbit splitting to first order in perturbation theory, as the associated energy is zero. So for a given S, all of its MS values are degenerate. This degeneracy is lifted when spin-orbit interaction is treated to higher order in perturbation theory, but still states with same |MS| are degenerate in a non-rotating molecule. We can speak of a 5Σ2 substate, a 5Σ1 substate or a 5Σ0 substate. Except for the case Ω = 0, these substates have a degeneracy of 2. Reflection through a plane containing the internuclear axis There are an infinite number of planes containing the internuclear axis and hence there are an infinite number of possible reflexions. For any of these planes, molecular terms with Λ > 0 always have a state which is symmetric with respect to this reflection and one state that is antisymmetric. Rather than labelling those situations as, e.g., 2Π±, the ± is omitted. For the Σ states, however, this two-fold degeneracy disappears, and all Σ states are either symmetric under any plane containing the internuclear axis, or antisymmetric. These two situations are labeled as Σ+ or Σ−. Reflection through an inversion center: u and g symmetry Taking the molecule center of mass as origin of coordinates, consider the change of all electrons’ position from (xi, yi, zi) to (−xi, −yi, −zi). If the resulting wave function is unchanged, it is said to be gerade (German for even); if the wave function changes sign then it is said to be ungerade (odd). For a molecule with a center of inversion, all orbitals will be symmetric or antisymmetric. The resulting wavefunction for the whole multielectron system will be gerade if an even number of electrons is in [[ungerade orbitals]], and ungerade if there is an odd number of electrons in ungerade orbitals, independently of the number of electrons in gerade orbitals. [ Last edited by jmlong on 2011-4-1 at 06:09 ] |
5楼2011-04-01 06:01:35