![1.31: The Position and Momentum Commutation Relation in Coordinate and Momentum Space - Chemistry LibreTexts 1.31: The Position and Momentum Commutation Relation in Coordinate and Momentum Space - Chemistry LibreTexts](https://chem.libretexts.org/@api/deki/files/178320/clipboard_e2a839e9a719b66e253a940e1f46b68fd.png?revision=1)
1.31: The Position and Momentum Commutation Relation in Coordinate and Momentum Space - Chemistry LibreTexts
![SOLVED: Derive the following commutator relationships between the components of angular momentum L and of p: [Ly, Pc] ihp- [Ly, p-] = ihpr [Ly, P2] 2ihprp = [Ly; p2] 2ihprp= You can ( SOLVED: Derive the following commutator relationships between the components of angular momentum L and of p: [Ly, Pc] ihp- [Ly, p-] = ihpr [Ly, P2] 2ihprp = [Ly; p2] 2ihprp= You can (](https://cdn.numerade.com/ask_images/d20c7c45a12548a5974045dfbe89d71d.jpg)
SOLVED: Derive the following commutator relationships between the components of angular momentum L and of p: [Ly, Pc] ihp- [Ly, p-] = ihpr [Ly, P2] 2ihprp = [Ly; p2] 2ihprp= You can (
![Tamás Görbe on Twitter: "Commutation relations like this form the basis of quantum mechanics. This example expresses the connection between position (X) and momentum (P): [X,P]=XP-PX=ih/2π, where h is Planck's constant. It Tamás Görbe on Twitter: "Commutation relations like this form the basis of quantum mechanics. This example expresses the connection between position (X) and momentum (P): [X,P]=XP-PX=ih/2π, where h is Planck's constant. It](https://pbs.twimg.com/media/E_o9UrsXsAQCKX1.png:large)