Full Curriculum
5 modules. 42 lessons. One framework.
Not five disconnected subjects. Each module builds on the last, and all share the same underlying language: conservation, gradients, fluxes, kinetics, and free energy.
Module 01
Mathematical Language of Chemical Engineering
Stop fighting the notation. See the mathematical skeleton underlying every equation in the field.
2Steady-State vs. Transient Systemscoming soon∂/∂t = 0, or not
3Dimensional Analysis & Scalingcoming soonBuckingham π theorem
4ODEs in Engineering Contextcoming soonSeparation of variables, integrating factor
5PDEs and Boundary Conditionscoming soonWhere students fail
6Numerical Methods Overviewcoming soonEuler, RK4, finite differences
7Integration: Balance on a Real Systemcoming soonEverything together
Module 02
Thermodynamics from Molecules to Processes
Understand why things happen, not just how to calculate them.
1The First and Second Laws (Really)coming soonΔU = Q − W; ΔS_universe ≥ 0
2Enthalpy and When to Use Itcoming soonH = U + PV
3Entropy and Spontaneitycoming soonDisorder is not the right word
4Gibbs and Helmholtz Free Energycoming soonG = H − TS
5Chemical Potentialcoming soonμi = (∂G/∂ni)_{T,P}
6Phase Equilibria and the Phase Rulecoming soonF = C − P + 2
7Equations of Statecoming soonvan der Waals → Peng-Robinson
8Fugacity and Activity Coefficientscoming soonCorrections for real behavior
9Process Thermodynamicscoming soonCycles, efficiency, real systems
Module 03
Transport Phenomena
Heat, mass, and momentum transfer are the same equation wearing three different outfits.
1The Transport Analogycoming soonFlux = −(conductance) × gradient
2Momentum Transport: Newton's Law of Viscositycoming soonτ = −μ(dv/dy)
3Laminar Flow and the Navier-Stokes Equationscoming soonSimplified cases
4Energy Transport: Fourier's Lawcoming soonq = −k∇T
5Convective Heat Transfercoming soonh, Nu, Re, Pr
6Mass Transport: Fick's Lawcoming soonJ = −D∇c
7Convective Mass Transfercoming soonk_c, Sh, Sc
8The Boundary Layercoming soonVelocity, thermal, concentration
9The Transport Analogy Unifiedcoming soonChilton-Colburn, j-factors
Module 04
Reaction Engineering
Reactors are just balance equations with a generation term that isn’t zero.
1Reaction Rate and Rate Lawscoming soonr = k f(C)
2The Batch Reactorcoming soondN/dt = rV
3The CSTR: Perfect Mixingcoming soonSteady-state, well-mixed
4The PFR: Plug Flowcoming soonNo axial mixing
5Sizing and Comparing Reactorscoming soonLevenspiel plots
6Multiple Reactions: Selectivitycoming soonParallel and series reactions
7Temperature Effects: Arrheniuscoming soonk = A·exp(−Ea/RT)
8Non-Ideal Flow: RTD Theorycoming soonE(t), F(t), dispersion
9Heterogeneous Catalysiscoming soonLangmuir-Hinshelwood
Module 05
Process Systems and Design
See how every concept you’ve learned connects into one engineered system.
1Process Flowsheeting and Block Diagramscoming soonUnits, streams, specifications
2Material Balances: Multi-Unit Processescoming soonRecycle, bypass, purge
3Energy Balances: Multi-Unit Processescoming soonPinch analysis introduction
4Heat Integrationcoming soonMinimizing utility cost
5Process Control: The Feedback Loopcoming soonPID, control loops
6Economic Analysis and Profitabilitycoming soonCAPEX, OPEX, NPV, IRR
7Case Study: Ammonia Synthesiscoming soonEverything in one process
8Capstone: Design Your Own Processcoming soonStudent-directed