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1.1 - Chemical Reaction Engineering
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1.2 - Conservation Laws
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1.3 - Structure of Problem and Its Solution
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1.4 - Time and Length Scales
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1.5 - Start Up of A Well Mixed Reactor
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1.6 - Unsteady State Reactor
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2.1- Setting up the problem through balance equations
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2.2 - Constant Volume, Constant Density Assumptions
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2.3 - Solving the Equations
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2.4 - Design Equations for a Batch Reactor and a Plug Flow Reactor
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2.5 - The Energy Balance
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2.6 - Stoichiometric Table
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2.7 - Energy Balance around a Chemical Reactor
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3.1- Energy Balance around a Batch Reactor
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3.2 - Energy Balances Examples
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3.3 - Example Solutions
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4.1 - BATCH REACTOR CONSTANT PRESSURE
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4.2 - ACCOUNTING FOR VOLUME CHANGE
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4.3 - ACCOUNTING FOR VOLUME CHANGE IN A BATCH REACTOR
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4.4 - PLUG FLOW REACTOR AND BATCH REACTOR ANALOGY
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4.5 - ENERGY BALANCE IN A MIXED FLOW REACTOR
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5 - MULTIPLE STEADY STATES IN CHEMICAL REACTORS
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6 - PROPERTY ESTIMATIONS
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7 - AVERAGE HEAT CAPACITIES
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8.1 - CRE FOR COMPLEX REACTIONS
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8.2 - DESIGN EQUATION FOR A BATCH REACTOR
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8.3 - PERFORMANCE INDICATORS
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8.4 - PERFORMANCE INDICATOR REACTION EXTENT
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8.5 - EXAMPLE: OPTIMUM SPACETIME IN A CSTR (MFR)
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9.1 - LIMITS OF IDEAL REACTORS
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9.2 - NON-IDEAL REACTORS
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9.3 - NON-IDEAL REACTORS MICRO-MIXING VS MACRO-MIXING
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9.4 - NON-IDEAL REACTORS: AXIAL DISPERSION IN PFR
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10.1 - THEORY OF CHEMICAL KINETICS
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10.2 - SURFACE REACTIONS
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10.3 - THEORY OF CHEMICAL KINETICS HOMOGENEOUS REACTIONS
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11 - REACTIONS WITH AN INTERFACE
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13.2 - FLUIDIZED BED REACTOR DESIGN FOR HETEROGENEOUS CATALYZED REACTIONS MODELING
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1 - GENERAL INTRODUCTION TO CHEMICAL REACTION ENGINEERING
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2 - GENERAL MOLE BALANCE AND DESIGN EQUATIONS
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3 - TRANSIENT BEHAVIOR IN IDEAL REACTORS
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4 - REACTION HEATS AND HEAT CAPACITIES
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5 - THE ENERGY BALANCE
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6 - THE ENERGY BALANCE AROUND A BATCH REACTOR
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7 - VOLUME CHANGE DUE TO REACTION
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8 - MULTIPLE STEADY STATES IN CHEMICAL REACTORS
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9 - CRE FOR COMPLEX REACTIONS
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10 - CRE FOR COMPLEX REACTIONS EXAMPLE: OPTIMUM SPACE TIME IN A CSTR
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11 - LIMITS OF IDEAL REACTORS
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12 - NON IDEAL REACTORS
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13 - THEORY OF CHEMICAL KINETICS
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14 - REACTION RATES FOR COMPLEX HOMOGENEOUS REACTIONS
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15 - SURFACE REACTIONS
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16 - REACTIONS WITH AN INTERFACE
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17 - FIXED BED REACTOR DESIGN FOR SOLID CATALYZED REACTIONS
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18 - ADIABATIC REACTOR DESIGN FOR THERMODYNAMICALLY LIMITED REACTIONS
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19 - FLUIDIZED BED REACTOR DESIGN FOR HETEROGENEOUS CATALYZED REACTIONS
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20 - FLUIDIZED BED REACTOR MODELS
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A CRE PERSPECTIVE ON HUMAN METABOLISM
Description:
Explore advanced concepts in chemical reaction engineering through a comprehensive lecture series. Delve into topics such as conservation laws, reactor design equations, energy balances, complex reactions, non-ideal reactors, chemical kinetics, surface reactions, and heterogeneous catalysis. Learn to analyze and optimize various reactor types, including batch, plug flow, and fluidized bed reactors. Develop skills in problem-solving, mathematical modeling, and process design for industrial applications. Gain insights into the theoretical foundations and practical applications of chemical reaction engineering, from fundamental principles to advanced reactor modeling techniques.

Advanced Chemical Reaction Engineering - Prof. Dr. Deniz Üner

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1.1 - Chemical Reaction Engineering