Angular Momentum in Quantum Mechanics

Angular Momentum and Commutation Relations in Quantum Mechanics

Angular Momentum in 3D Space

• A particle's position in 3D space is represented by a vector R . If its momentum is not aligned with R , it can exhibit circular motion, leading to angular momentum defined as L = R times P .

• The components of angular momentum are calculated using determinants:

• X component: L_x = YP_z - ZP_y

• Y component: L_y = ZP_x - XP_z

• Z component: L_z = XP_y - YP_x .

Operators in Quantum Mechanics

• In quantum mechanics, position and momentum are treated as operators:

• Position operators: X, Y, Z

• Momentum operators: P_x, P_y, P_z

• These can be expressed as differential operators:

• P_x = -ihbard/dx, P_y = -ihbard/dy, P_z = -ihbard/dz .

Components of Angular Momentum Operator

• The angular momentum operator components are defined similarly to classical mechanics but involve the aforementioned position and momentum operators:

• For example, the X component is given by:

$$ L_x = -ihbar(Yd/dz - Zd/dy) $$.

Importance of Commutation Relations

• Commutation relations dictate the order of operations for quantum mechanical operators. If two operators commute (e.g., their commutation relation equals zero), their order does not matter; otherwise, it does.

• Position operators commute with each other and so do momentum operators. However, position and momentum pairs do not commute (e.g., [X,P] ≠ 0) .

Finding Commutation Relations

• To find the commutation relation between two angular momentum components like L_x and L_y :

$$ [L_x,L_y] = iL_z $$

This indicates that the order of operations matters significantly when calculating these relations .

Detailed Calculation Example

• The calculation involves determining how different combinations of angular momentum components interact under commutation. For instance:

$$ [Y,P_Z] $$

shows that while some terms cancel out due to commuting properties, others do not because they involve non-commuting variables .

Understanding Commutation Relations in Quantum Mechanics

Commutation of Position and Momentum Operators

• The commutation relation between position Z and momentum p_z is highlighted, showing that they do not commute:

• [ [Z, p_z] = -ihbar ]

• This leads to the expression involving cyclic order:

• ihbar x p_y - y p_x [].

Angular Momentum Operators

• The discussion extends to angular momentum operators L_x, L_y, L_z :

• Their commutation relations are established:

• [L_x, L_y] = ihbar L_z

• [L_y, L_z] = ihbar L_x

• Emphasis on maintaining cyclic order when calculating these relations [].

Uncertainty Principle Implications

• The uncertainty principle for two operators A and B is introduced:

• For angular momentum components:

• It indicates that precise measurements of L_x and L_y cannot be made simultaneously.

• Expressed as:

• h^2/4 * E[L_z^2] , indicating incompatibility of observables [].

Commutation with Position Operators

• Examination of the commutation between position operator X and angular momentum operators:

• Results show that while some pairs commute (e.g., [X, P_X] = 0 ), others do not:

• Non-zero relations include:

• [P_X, L_Y] = ihbar P_Z; [P_X, L_Z] = -ihbar P_Y. [].

General Angular Momentum Relations

• Transitioning to general angular momentum denoted by vector J:

• Similar expressions for commutation relations are derived for components of J.

• Notably,

J_s = J_x^2 + J_y^2 + J_z^2

which commutes with each component [].

Hermitian Properties and Eigenvalues

• Discussion on the Hermitian nature of operators like J:

• They possess real eigenvalues.

• While Jx, Jy, and Jz can have simultaneous eigenfunctions with Js, they cannot share them among themselves due to non-commutativity [].

Raising and Lowering Operators Introduction

• Introduction of raising ( J_+ ) and lowering ( J_- ) operators defined as follows:

J_+ = J_x + iJ_y

J_- = J_x − iJ_y

These facilitate calculations involving eigenstates [].

Commutation Relations Among New Operators

• Establishment of new commutation relations using raising/lowering operators shows their utility in quantum mechanics.

[Js, J_+] = [Js, J_-] = 0

Commutation Relations and Eigenvalues in Quantum Mechanics

Commutation of Angular Momentum Operators

• The commutation relation between J_z and J_+ is found to be hbar J_+ , while the relation for J_z and J_- yields -hbar J_- .

• The expression for the product of operators J_+ J_- can be expressed in terms of J^2 and J_z , leading to a formulation involving non-commuting terms.

Expressions Involving Angular Momentum Operators

• The relationship between angular momentum squared, represented as j^2 = j_x^2 + j_y^2 + j_z^2 , allows simplification of expressions involving these operators.

• Using commutation relations, we derive eigenfunctions and eigenvalues for the operators acting on states denoted as alpha ( alpha ) and beta ( beta ).

Eigenstates and Eigenvalues Analysis

• When applying the operator J_z , it modifies the state by changing beta, resulting in eigenvalues expressed as hbeta_pm 1 .

• The action of raising ( J_+ ) or lowering ( J_- ) operators on states leads to new eigenstates with specific eigenvalues related to total angular momentum.

Constraints on Eigenvalue Relationships

• It is established that there exists an upper limit for beta based on expectation values derived from angular momentum squared minus its z-component.

• This leads to a conclusion that if we apply the raising operator multiple times, it will eventually reach a maximum state where further application results in zero.

Ladder Operator Dynamics

• By analyzing how raising and lowering operators interact with states, we find relationships that define limits for alpha based on beta's maximum value.

• A ladder analogy is used to describe transitions between states defined by their respective eigenvalues under operations performed by these angular momentum operators.

Final Formulation of Eigenstates

• Two potential solutions arise from equations relating maximum and minimum values of beta; however, only one solution remains viable within physical constraints.

• Ultimately, we establish that possible values for total angular momentum (J values ranging from integers to half-integers), along with corresponding M values spanning from negative to positive limits.

Summary of Results

• The final results yield orthonormality conditions among eigenfunctions represented as delta functions.

Understanding the Operators in Quantum Mechanics

The Role of Raising and Lowering Operators

• The discussion begins with the equation involving raising (J+) and lowering (J-) operators, leading to the identification of constants c_jm for both c_jm+ and c_jm- . It is noted that J+ is equivalent to J- , allowing for a reformulation of expressions.

• The operators can be expressed in terms of angular momentum components, specifically J_s and J_z . This allows for calculations involving states represented by quantum numbers.

• By manipulating these expressions, one can derive relationships between different states. When applying the raising operator on state |j,mrangle , it results in a new state while preserving the value of j .

Effects of Operators on Quantum States

• The action of the raising operator ( J+ ) increases the magnetic quantum number ( m ), while the lowering operator ( J- ) decreases it. This distinction highlights their roles as operators that raise or lower states within a defined system.

• Further exploration reveals how other angular momentum components like J_x and J_y can also be expressed using these raising and lowering operators. Notably, differences arise due to signs in their mathematical representations.

Expectation Values and Inner Products

• A critical point is made regarding expectation values of operators such as J_y and J_x. These values are examined within simultaneous eigenstates of other operators, emphasizing how they alter states like |j,mrangle.