diff --git a/src/8_differential_equations_2.md b/src/8_differential_equations_2.md
index 52868478bce35d7a2b774e70faf05cf42f9ea1e9..d4f7008fca31eda732eb32b5fac499ffe768c4ca 100644
--- a/src/8_differential_equations_2.md
+++ b/src/8_differential_equations_2.md
@@ -1,4 +1,20 @@
-# Higher order linear differential equations
+---
+title: Differential Equations 2
+---
+
+# Differential equations 2
+
+The lecture on differential equations consists of three parts, each with their own video:
+
+- [Higher order linear differential equations]()
+- [Partial differential equations: Separation of variables]()
+- [Self-adjoint differential operators](#solving-homogeneous-linear-system-with-constant-coefficients)
+
+**Total video length:  hour  minutes  seconds**
+
+## Higher order linear differential equations
+
+<iframe width="100%" height=315 src="https://www.youtube-nocookie.com/embed/ucvIiLgJ2i0?rel=0" frameborder="0" allow="accelerometer; encrypted-media; gyroscope; picture-in-picture" allowfullscreen></iframe>
 
 In the previous lecture, we focused on first order linear differential equations
 as well as systems of such equations. In this lecture we switch focus to DE's 
@@ -197,7 +213,11 @@ $$f(x) = e^{\lambda_1 x}, \ x e^{\lambda_1 x} , \ \cdots, \ x^{m_{1}-1} e^{\lamb
     
     $$f_1(x)=e^{0 x} = 1, \ f_{2}(x) = x e^{0 x} = x. $$
 
-# Partial differential equations
+## Partial differential equations: Separation of variables
+
+<iframe width="100%" height=315 src="https://www.youtube-nocookie.com/embed/I4ghpYsFLFY?rel=0" frameborder="0" allow="accelerometer; encrypted-media; gyroscope; picture-in-picture" allowfullscreen></iframe>
+
+### Definitions and examples
 
 A partial differential equation (PDE) is an equation involving a function of two or 
 more indepenedent variables and derivatives of said function. These equations
@@ -329,7 +349,7 @@ problem, a boundary value problem does not always have a solution. For example,
 in the figure below, regardless of the initial slope, the curves never reach $0$
 when $x=L$. 
 
-<img src="figures/DE2_1.png" width="650">
+![image](figures/DE2_1.png)
 
 For boundary value problems like this, there are only solutions for particular 
 eigenvalues $\lambda$. Coming back to the example, it turns out that solutions
@@ -382,7 +402,9 @@ Notice that there is one solution $\psi_{n}(x,t)$ for each natural number $n$.
 These are still very special solutions. We will begin discussing next how to 
 obtain the general solution in our example. 
 
-## Self-adjoint differential equations: Connection to Hilbert spaces! ##
+## Self-adjoint differential operators
+
+<iframe width="100%" height=315 src="https://www.youtube-nocookie.com/embed/p4MHW0yMMvY?rel=0" frameborder="0" allow="accelerometer; encrypted-media; gyroscope; picture-in-picture" allowfullscreen></iframe>
 
 As we hinted was possible earlier, let us re-write the previous equation by 
 defining a linear operator, $L$, acting on the space of functions which satisfy