diff --git a/README.md b/README.md
index 4addc13..1d6f81e 100644
--- a/README.md
+++ b/README.md
@@ -143,26 +143,28 @@ Feel free to explore, contribute, and share your insights!
    
     * The formula to describe **Charles Bennett's (1993)** work based on the provided information can be expressed as follows:
 
- 3.1 **Reversible Computing**:  
+   3.1 **Reversible Computing**:  
    - Based on the concept of **reversible computation**, where operations can be undone without information loss, reducing energy dissipation (aligned with the second law of thermodynamics).  
 
    Simplified formula for energy and information conservation:  $\huge \color{DeepSkyBlue} \Delta S = 0 \quad \text{(Entropy remains constant for reversible systems)}$
    
 
- 3.2 **Quantum Teleportation**:  
+   3.2 **Quantum Teleportation**:  
    - Describes the transfer of quantum states between particles via quantum entanglement, without physically transferring the particle itself.  
 
    Generic formula for quantum teleportation:  
-   \[
-   |\psi\rangle_C = |\phi\rangle_A \otimes |\beta_{00}\rangle_{BC}
-   \]
+   
+   $\huge \color{DeepSkyBlue} \psi\rangle_C = |\phi\rangle_A \otimes |\beta_{00}\rangle_{BC}$
+   
    Where:  
-   - \(|\psi\rangle_C\) is the reconstructed state at the destination (C).  
-   - \(|\phi\rangle_A\) is the initial quantum state (A).  
-   - \(|\beta_{00}\rangle_{BC}\) represents the entangled particle pair (B and C).  
+   - \huge \color{DeepSkyBlue} \(|\psi\rangle_C\) is the reconstructed state at the destination (C).
+     
+   - \huge \color{DeepSkyBlue} \(|\phi\rangle_A\) is the initial quantum state (A).
+     
+   - \huge \color{DeepSkyBlue} \(|\beta_{00}\rangle_{BC}\) represents the entangled particle pair (B and C).  
 
 
-     
+