The electron density solutions for the molecule H2 in question 1 are different sizes. Why is that? Select one: Solutions for the Schrödinger equation produce different eigenstates that have varia...
The electron density solutions for the molecule H2 in question 1 are different sizes. Why is that? Select one: Solutions for the Schrödinger equation produce different eigenstates that have variable shapes. Panel a represents the orbital when the electron spins are antiparallel and panel e represents it when they are parallel; the rest show the transition between those two extremes It is most likely that electrons will be found near the two hydrogen nuclei. Each orbital representation depicts a different energy level solution for H2 The relative distance between the two hydrogen nuclei cause the shape of the 01s orbital to vary.
The electron density solutions for the molecule H2 in question 1 are different sizes. Why is that? Select one: Solutions for the Schrödinger equation produce different eigenstates that have variable shapes. Panel a represents the orbital when the electron spins are antiparallel and panel e represents it when they are parallel; the rest show the transition between those two extremes It is most likely that electrons will be found near the two hydrogen nuclei. Each orbital representation depicts a different energy level solution for H2 The relative distance between the two hydrogen nuclei cause the shape of the 01s orbital to vary.