Energy Systems Fundamentals – Fall 2024

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U6072 – Energy Systems Fundamentals

COURSE SYLLABUS

Name Email Office Hours

Professor Travis Bradford [email protected] Friday 12-2 pm, TBD

- sign-up on CourseWorks –

TAs Gabriela Manriquez Roa

Izza Qayyum

Devraj Singhania

[email protected]

[email protected]

[email protected]

TBD

A. COURSE OVERVIEW

Existing energy sources and the infrastructures that deliver them to users around the world are undergoing

a period of rapid change.

Limits to growth, rapidly fluctuating raw material prices, and the emergence of

new technology options all contribute to heightened risk and opportunity in the energy sector. The purpose

of this course is to establish a core energy skill set for energy students and prepare them for more advanced

energy courses by providing a basic language and toolset for understanding energy issues.

Using theoretical and practical understanding of the process by which energy technologies are developed,

financed, and deployed, this course seeks to highlight the root drivers for change in the energy industry, the

technologies that are emerging, and the factors that will determine success in their commercialization.

Understanding these market dynamics also informs good policy design and implementation to meet a broad

range of social welfare goals.

Upon completing the course, students should not only understand the nature of conventional and emerging

energy generation and delivery, but also the tools for determining potential winners and losers and the

innovative pathways to drive their further deployment.

B. COURSE PROCEDURES

This course is designed to be inter-disciplinary, integrating skills from finance, marketing, technology,

regulation and policy, and entrepreneurship. However, no prior knowledge is required to excel in this

course. It is intended to establish a foundation of knowledge and framework for further study.

Methodologically, there are some basic skills for measuring, costing, and valuing energy and electricity

that must be understood, which are particular to the energy industry.

Therefore, non-trivial mathematical

and spreadsheet work will be required to show the necessary competence in these skills.

Students should

be reasonably comfortable with spreadsheet modeling for computation and financial projection before

beginning the course, or choose a good partner for completing problem sets.

The hardest part of any work in emerging technologies (particularly in the fast-changing energy sector) is

to integrate vast amounts of information into useful and actionable information.

It is vital to cut through

the haze of data and uncertainty to identify key drivers for success and then present the qualitative and

quantitative information necessary to determine the likelihood of and best pathway to success for a given

solution.

Such analysis will be messy and complex and will likely necessitate substantial supplemental

research, but in the end will derive great practical benefit in the skills of analysis and presentation that will

be useful in nearly every future career.

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C. COURSE MATERIAL

REQUIRED

1) The Energy System, Travis Bradford, MIT Press, 2018

(order online soon from Amazon, hardcopy or Kindle version, I recommend Kindle)

2) Thinking in Systems, Donella Meadows, Chelsea Green, 2008

(order online, fastest may be Amazon Kindle, or PC e-book app.)

3) Supplemental readings and videos from the syllabus below and occasional articles posted for

students

RECOMMENDED

1) Solar Revolution: The Transformation of the Global Energy Industry, Travis Bradford, MIT

Press, 2006

D. GRADING

Grading will be based on class participation, eight problem sets, and a final exam. Students cannot take

this course pass/fail.

1. Class participation (30%)

Class participation will count for 30% of the final grade. A number of factors will contribute to your class

participation grade:

a. Contributions in class and recitation: Thoughtful comments and focused questions that

contribute to the learning environment are encouraged (quality, not quantity, is the key

factor here). Additional participation is also possible for students who opt to give a short

presentation during recitation (prior coordination with TAs is required) to share energy

industry work experience and/or analysis of a select topic.

b. Attendance: students are expected to attend all classes and recitations.

c. Contributions outside class: Providing links to articles, publications, videos, and data that

support the classroom discussion (these can either be used this semester or may be used to

support future classes), actively creating a collaborative and collegial work environment

inside and outside the class, suggesting edits or additional articles and papers to support

the continued development for the class.

2. Seven (7) Problem Sets (35%)

Seven problem sets will be done in groups of up to 3-4 people and will account for 35% of the final grade.

These problem sets will reinforce concepts of measurement and metrics of energy, including generation

and capacities, energy conversions, and calculation methodologies of cost and value of energy, electricity,

and carbon.

The calculations will be supplemented with qualitative assessments of the results.

Problem sets will be submitted online via CourseWorks. The deadline for each problem set is at 2:00 PM

before the Friday recitation for the week they are due. Late problem sets will have grades deducted.

3. Final Exam (35%)

The final will count for 35% of the final grade. It will both qualitatively and quantitatively test the

fundamental concepts of class, the readings, lectures, and learnings from the problem sets. A list of the

learning objectives is provided below, but should not be considered exhaustive for the purposes of the

exam. Final Exams will only be given during the normal exam period.

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E. GRADING POLICY

Late Problem Set assignments will be docked one letter grade for each day they are turned in late, and

will not be accepted after that week’s recitation.

Any requests for grade review will require extraordinary

circumstances and will subject all other work to simultaneous review, which could result in either upward

or downward revision. Problem Sets are to be done in groups of up to 3-4 people (and not shared beyond

that).

Academic Integrity Statement:

I do not tolerate cheating and/or plagiarism in any form. Those students who violate the Code of

Academic & Professional Conduct will be subject to the Dean’s Disciplinary Procedures.

http://new.sipa.columbia.edu/code-of-academic-and-professional-conduct

Please familiarize yourself with the proper methods of citation and attribution. The School provides

some useful resources online; we strongly encourage you to familiarize yourself with these various

styles before conducting your research. Shared work beyond problem set groups (including any

use of web resources and Generative AI tools) will be considered plagiarism, and treated

accordingly. Be aware that, mathematically, one single zero on a problem set in such a competitive

class would work out to a substantial final grade impact).

F. COMPUTER AND DEVICE POLICY

As a strict rule, computers, phones, and other internet enabled devices cannot be used in class. It distracts

you, it distracts your classmates, and it distracts me.

Lie-flat note taking devices are allowed, but

absolutely cannot be use to surf, browse, read, or play with material other than class notes or slides. Any

violation of this policy will incur significant loss of participation grade in the course.

G. BLOGS AND NEWS SITES TO FOLLOW

I cannot emphasize this strongly enough!

You should begin the habit of reading relevant sector news

every day. (EVERY DAY!)

To keep up-to-date on current affairs in the E&E world, we recommend

regularly reviewing the following websites and blogs, but would also love to learn of other resources you

use that might be useful for others.

Conventional Energy

OilPrice.com

http://oilprice.com/

Fuel Fix

http://fuelfix.com/

Platts – Barrel Blog

http://blogs.platts.com/

Utility Dive

https://www.utilitydive.com/

Power Magazine

https://www.powermag.com/

Emerging Energy

The Energy Collective

http://theenergycollective.com/

Renewable Energy News

https://www.renewableenergyworld.com/#gref

Prometheus Institute

http://prometheus.org/

Next Billion

http://nextbillion.net/

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Other Course Policies

Participation and Attendance

You are expected to complete all assigned readings, attend all class sessions, and engage with others in online

discussions. Your participation will require that you answer questions, defend your point of view, and challenge the

point of view of others. If you need to miss a class for any reason, please discuss the absence with me in advance.

Citation & Submission

All written assignments must use standard citation format (e.g., MLA, APA, Chicago), cite sources, and be

submitted to the course website (not via email).

Copyright Policy

Please note—Due to copyright restrictions, online access to this material is limited to instructors and students

currently registered for this course. Please be advised that by clicking the link to the electronic materials in this

course, you have read and accept the following:

The copyright law of the United States (Title 17, United States Code) governs the making of

photocopies or other reproductions of copyrighted materials. Under certain conditions specified in

the law, libraries and archives are authorized to furnish a photocopy or other reproduction. One of

these specified conditions is that the photocopy or reproduction is not to be "used for any purpose

other than private study, scholarship, or research." If a user makes a request for, or later uses, a

photocopy or reproduction for purposes in excess of "fair use," that user may be liable for

copyright infringement.

Diversity Statement

It is our intent that students from all diverse backgrounds and perspectives be well-served by this course, that

students’ learning needs be addressed both in and out of class, and that the diversity that the students bring to this

class be viewed as a resource, strength and benefit. It is our intent to present materials and activities that are

respectful of diversity: gender identity, sexuality, disability, age, socioeconomic status, ethnicity, race, nationality,

religion, and culture.

Class Recordings

All or portions of the class may be recorded at the discretion of the Instructor to support your learning. At any

point, the Instructor has the right to discontinue the recording if it is deemed to be obstructive to the learning

process. If the recording is posted, it is confidential and it is prohibited to share the recording outside of the

class.

Etiquette and Netiquette

Etiquette (in person and online) is a way of defining professionalism for collaborations and communication that take

place in online environments. Here are some Student Guidelines for this class:

● Avoid using offensive language or language that is not appropriate for a professional setting.

● Do not criticize or mock someone’s abilities or skills.

● Communicate in a way that is clear, accurate and easy for others to understand.

● Balance collegiality with academic honesty.

● Keep an open-mind and be willing to express your opinion.

● Reflect on your statements and how they might impact others.

● Do not hesitate to ask for feedback.

● When in doubt, always check with your instructor for clarification.

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THE 10 LEARNING OBJECTIVES

10 things you should learn from this course (and will be tested on):

The list below sets out the objectives for the course and provides the basis for questions for the final exam.

You should note, however, that I will not treat these topics in the sequence and structure in which they are

presented here. Rather, I expect you to use this list as a roadmap to navigate the class. It is your own

responsibility to map the contents of the class to these ten objectives and ensure that, by the end of the class,

you are capable of answering questions related to these objectives using tools acquired in the course.

In

the end, meeting these objectives is also the list I hope you will use to evaluate the course.

1. Become fluent in Energy System concepts and terminology – technologies; current and

emerging sources of energy; four dimensions of energy transformation; final energy

services, and industry terminology and definitions

2. Understand the energy as a system – stocks, flows, and feedback; sustaining vs. reinforcing

loops; supply chains; five forms of capital; system dynamics; system resilience and buffers;

sustainable development

3. Describe the physical conversion of energy through the system – laws of thermodynamics;

power to energy conversion; losses; heat rates; temporal shifting; transmission and

transportation; efficiency; storage; and emission calculations

4. Link the energy system to micro-economic principles – Supply and Demand; supply curve

construction; market and market function; price formation; producer and consumer surplus;

profit (rent) maximization; average vs. marginal costs; short-term vs. long-term

5. Develop a complete framework of costing methods for both Energy and Power – Levelized

Cost of Electricity; fungible LCOE comparisons; capital costs; Total Cost of Ownership

(TCO); production cost; when costs are not independent; cycle cost; Cost per mile (CPM);

Break-even Price (BEP); abatement cost

6. Determine sources of value in energy systems – energy services; load; revenue; behavioral

limitations; total addressable market; integrated streams of values for power and energy;

fractured petroleum economics; indexing; energy/ GDP linkages; energy poverty

7. Develop and intelligently use scenarios and forecasts of the future energy system – bottom

up vs. top down methods; system peaks; margins and buffers; experience curves and

learning; feedstock linkages; constraints, limits, and bottlenecks; asset lock-in; co- dependence; the tension between innovation versus depletion

8. Recognize and describe the role of competition in energy markets – sustaining versus

disruptive loops; evolutionary changes vs. disruptive changes; market design; fungible

comparisons; parity and disruption; product differentiation; switching

9. Understand the role and methods of investment in the energy system – compounding,

financial analysis; project finance; project risk categories; debt vs. equity; venture capital;

R&D futures trading and speculation; retrofit and repowering; micro-finance

10. Know and apply tools used for analyzing energy market failures and solutions – myopia;

externalities; informational asymmetries; natural monopolies; cartels; collective security;

system collapse; policy interventions; market interventions

Energy Systems Fundamentals – Fall 2024

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COURSE OUTLINE BY WEEK – with assignments

COURSE READINGS AND ASSIGNMENTS

• Topic 1-2 (General Principles) has a fairly large amount of industry and background reading – the

course texts, “The Energy System” and “Thinking in Systems”, are introduced along with some

more academic papers about obstacles to change, policy design and impacts, tragedy of the

commons, externalities, etc. You should flip through and understand the data sources within the

World Energy Assessment, BP Energy Assessment, IEO, IPCC Reports, etc.

• Topic 3-7 (Electricity Systems) begins as an understanding of the existing electricity market and

uses that market to demonstrate how physical transformations are made and then valued in one of

the largest formal markets in the world. Understanding the pressures facing this market allow for

examination of various solutions including efficiency and demand response.

It also assesses all of

the utility- and distributed-scale generation options available today using a framework for

determining competitiveness, including fungibility and values. A number of practical, economic,

and forecasting competences will be developed throughout this section, including LCOE

methodology, price determination, disruption, and the role of storage.

• Topic 8-10 (Transportation Systems) begins by looking at the use of transportation services and

constraints imposed by access to petroleum resources. It then looks at where and how capital can

be deployed profitably to change this infrastructure, supplement fuels, or switch to other

combustion options, and the limiting forces to those innovations. Finally, examining how

transportation re-integrates with electricity architecture gives us an opportunity to examine the

nature of paired technologies.

• Topic 11-13 (Other Energy Systems) will integrate a wide range of situations and technology

options into an examination of comprehensive systems. The role of natural gas in the thermal

system, energy impacts on the economic system, carbon pricing, and new methods of delivering

vital energy to the world's poorest combine to help us spot emerging business opportunities now

and in the future.

• Links are Hot – You should be able to click through.

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Course Outline (Topic, Title, Assignments, Topics and Recitations)

Title Topics Recitation Assignment

General Principles (2 weeks)

Sep

9

1

Introduction to Energy Terms

and Conversions

Why Energy Matters, Energy vs. Power, Stocks

and Flows, Laws of Thermodynamics, Scenarios,

Conversions, Constraints, Normative vs. Positive

Sep 13

Recitation

Orientation

Bio Sheet

Sep

16

2 Energy as an Economic System

and Dealing with Market

Failures

Energy Systems Dynamics, Six Forms of Capital,

Cost vs. Value vs. Price, Fungibility, Market

Failures, Behavioral Economics, Interventions

Sep 20

Recitation

PS #1 –

Conversions

and Scenarios

Electricity Systems (5 weeks)

Sep

23

3 Understanding Organized

Electricity Markets

- The Grid

Generation, Transmission, Distribution, Cost of

Service Recovery, Deregulation, Load types,

Dispatchability, Interconnection

Sep 27

Recitation

Sep

30

4 Generation Supply, Demand,

and Price Determination

- Fossil Fuel generation

Bus Bar Costs, LCOE, Price of Electricity,

Multiple Value Streams of Electricity

Oct 4

Recitation

PS #2 – Cap.

Factors, Bid

Stack, LCOE

Oct

7

5 Project Finance and

Development

- Renewable generation

Project Finance, Cost of Capital (WACC), IRR,

Risk, Fungibility of Generation Alternatives

Oct 11

Recitation

PS #3 – Project

Finance

Oct

14

6 Demand Side Solutions

- Energy Efficiency, Demand

Response, and Storage

Devices, Load, Energy Efficiency, Economic

Demand Response Measures, Ancillary Services,

Storage Alternatives, Smart Grid

Oct 18

Recitation

Oct

21

7 Experience Curves,

Disruptions, and Solar Energy

- Distributed Generation

Experience Curves, Learning, Technology,

Disruptive Technologies, Net Metering,

Distributed Generation, Utility Transformation

Oct 25

Recitation

PS #4 –

Distributed

Resources

Transportation Systems (4 weeks)

Oct

28

8/

9

Oil and Transportation

Markets

- Transportation Systems

- Petroleum

Transportation Services, Passenger vs. Cargo,

CAFE Standards, Unintended Consequences,

Resource and Reserves, Quality, Peak Oil,

Fracking, Delivery Systems, Energy Security

Nov 1

COMPLETE OIL/

TRANSPORT

LECTURE

Nov

4

ACADEMIC HOLIDAY – Election

Day

Nov 8

No recitation

Nov

11

10 Alternate Fuel Sources

- Biofuels

- Natural Gas Vehicles

Feedstocks, Food vs. Fuel, Biofuels, RFS, Flex- Fuel Vehicles, Asset Lock-in and Co- Dependence, Cellulosic, Algae, Drop-in Fuels

Nov 15

Recitation

PS #5 -

Forecasting Oil

Prices

Nov

18

11 Electricity in Transportation

- Electric Vehicles

EV, PHEV, FCE, Charging Networks, Grid

Reliability, Stand-by Power, V2G, Spinning

Reserves, Total vs. Addressable Market

Nov 22

Recitation

PS #6 –

Biofuels and

EVs;

Other Energy Systems (2 weeks)

Nov

25

12 Thermal Systems and Natural

Gas

- Natural Gas

Thermal Energy, Natural Gas, Pipelines, Fracking

& Shale Gas, Liquefaction

Nov 29

No Recitation

- Thanksgiving

Dec

3

13 Energy and the Global

Economy

Energy and the Environment

Energy and Macroeconomics, Energy Security,

Energy and Development, Energy Access

Climate Change, Carbon Accounting and

Costing, Sustainable Development

Dec 6

TA Final

Review Session

PS #7 – Nat.

Gas/ Carbon

Final Exam

Dec ?? FINAL EXAM (9am-12noon)

Energy Systems Fundamentals – Fall 2024

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Lecture Readings, Assignments, and Questions

General Principles (2 Weeks)

1. INTRODUCTION TO ENERGY TERMS AND CONVERSIONS

Topics Covered:

Why Energy Matters, Energy vs. Power, Stocks and Flows, Laws of Thermodynamics, Scenarios,

Conversions, Constraints, Normative vs. Positive

Readings:

• The Energy System Preface & Chapter 1

• Holdren, J., “The Energy Innovation Imperative,” Spring 2006.

• McKinsey and Company, “The Energy Transition: Where Are We Really?,” August 2024

• OPTIONAL - The McGraw Center, Princeton. “Active Reading Strategies,” 2016.

2. ENERGY AS AN ECONOMIC SYSTEM AND DEALING WITH MARKET FAILURES

Topics Covered:

Energy Systems Dynamics, Six Forms of Capital, Cost vs. Value vs. Price, Fungibility, Market

Failures, Behavioral Economics, Interventions

Reading:

• Thinking in Systems [Through the end of Section 1]

• The Energy System Chapter 2 & 3

• “BP Energy Outlook,” BP, 2024 Edition

• REN21, “Renewables 2024 Global Status Report” [Pages 10-20, skim the rest]

• “energy [r]evolution: A Sustainable Global Energy Outlook ” Greenpeace International

and EREC, 2015

[Read Introduction, Executive Summary, Chapters 3 and 4, and SKIM Pages 58-92]

[Scan] Data Sources:

• “BP Statistical Review of World Energy” BP and Energy Institute, 2024

• “IEA World Energy Data and Statistics”, International Energy Agency, 2024

• “Monthly Energy Review” DOE Energy Information Agency (EIA), August 2024

[Optional] Reference:

• “Deploying Renewables: Best and Future Policy Practice”, IEA, 2011.

• “A Manual for the Economic Evaluation of Energy Efficiency and Renewable Energy

Technologies”, Short et. al., NREL, March 1995

Energy Systems Fundamentals – Fall 2024

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Electricity Systems (5 Weeks)

3. UNDERSTANDING ORGANIZED ELECTRICITY MARKETS

Topics Covered:

Generation, Transmission, Distribution, Cost of Service Recovery, Deregulation, Load types,

Dispatchability, Interconnection

Readings:

• The Energy System Chapter 4

• Binz, R. “Practicing Risk-Aware Electricity Regulation:

2014 Update,” CERES 2012

4. GENERATION SUPPLY, DEMAND, AND PRICE

Topics Covered:

Bus Bar Costs, LCOE, Price of Electricity, Multiple Value Streams of Electricity, Risk

Readings:

• Thinking in Systems [Section 2]

• The Energy System Chapter 5 & 6, (Particular focus on Appendix 5)

5. PROJECT FINANCE AND DEVELOPMENT

Topics Covered:

Project Finance, Cost of Capital (WACC), IRR, Fungibility of Generation Alternatives

Readings:

• The Energy System Chapters 7 & 8

• Lazard LCOE Plus – Version 2024

6. DEMAND SIDE SOLUTIONS

Topics Covered:

Devices, Load, Energy Efficiency, Economic Demand Response Measures, Ancillary Services,

storage alternatives, Smart Grid

Readings:

• The Energy System Chapters 9 & 10

7. EXPERIENCE CURVES, DISRUPTIONS, AND SOLAR ENERGY

Topics Covered:

Experience Curves, Learning, Technology, Disruptive Technologies, Net metering, Distributed

Generation, Utility Transformation

Readings:

• The Energy System Chapters 11 & 12

• [OPTIONAL] - Solar Revolution, Chapters 1, 6, 7, and 10

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Transportation Systems (4 Weeks)

8. OIL AND TRANSPORTATION MARKETS (DEMAND)

9. OIL AND TRANSPORTATION MARKETS (SUPPLY)

Topics Covered:

Transportation Services, Passenger vs. Cargo, CAFE Standards, Unintended consequences,

Resource and Reserves, Quality, Peak Oil, Fracking, Delivery Systems, Energy Security

Readings:

• The Energy System Chapters 13 & 14

10. ALTERNATE FUEL SOURCES

Topics Covered:

Feedstocks, Food vs. Fuel, Biofuels, RFS, Flex-Fuel Vehicles, Asset Lock-in and Co- Dependence, Cellulosic, Algae, Drop-in Fuels

Readings:

• The Energy System Chapter 15

11. ELECTRICITY IN TRANSPORTATION

Topics Covered:

EV, PHEV, FCE, Charging Networks, Grid Reliability, Stand-by Power, V2G, Spinning

Reserves, Total vs. Addressable Market

Readings:

• The Energy System Chapter 16, Review Chapter 10 (Storage)

Other Energy Systems (2 Weeks)

12. THERMAL SYSTEMS AND NATURAL GAS

Topics Covered:

Thermal Energy, Natural Gas, Pipelines, Fracking & Shale Gas, Liquefaction

Readings:

• The Energy System Chapters 17 & 18

13. ENERGY AND THE GLOBAL ECONOMY

Topics Covered:

Energy and Macroeconomics, Energy Security, Energy and Development, Energy Access

Readings:

• The Energy System Chapter 19

ENERGY AND THE ENVIRONMENT

Topics Covered:

Climate Change, UNFCCC, ETS Trading System, Carbon Accounting, Sustainable Development

Readings:

• The Energy System Chapters 20 and postscript

• [OPTIONAL] - Thinking in Systems [Section 3]

• IPCC 6th Assessment Synthesis Report for Policy Makers

Energy Systems Fundamentals – Fall 2024

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Energy System Fundamentals – Technical Video Links

Title Video

Link

The Future of Energy

The Future of Energy?

https://youtu.be/Gz_L6KuqvFI

Understanding Organized

Electricity Markets and Efficiency

- The Grid

- Energy Efficiency

Electricity Generation 101 (5 min.)

http://www.youtube.com/watch?v=20Vb6hlLQSg&feature=related

Overview of the Electricity Grid (4 min.)

http://www.youtube.com/watch?v=38EEmWHI0C8

Smart Grid (Institute of Electrical and Electronics Engineers, 9 min.)

http://www.youtube.com/watch?v=YrcqA_cqRD8&feature=related

A day in the life of the grid, July 21, 2011 (MISO, 33 min.) – Well worth the investment

https://www.youtube.com/watch?v=RdrMpElZWSM

[Optional] - Anatomy of a Transmission System (AEP, 4 min.)

http://www.youtube.com/watch?v=WTIQ_xcp0sU&feature=related

[Optional] - Anatomy of a Distribution System (AEP, 10 min.)

http://www.youtube.com/watch?v=YcBgxVfD70Q&feature=relmfu

Utility-Scale Generation Options

- Coal Thermal Power Plant

- Gas Fired Combined Cycle

- Co-Gen Plant

- Utility-scale Renewables

Coal Power Plant (MidAmerican Energy, 6 min.)

http://www.youtube.com/watch?v=j0e772Vo73k

Combined Cycle Natural Gas (Duke Energy, 7 min.)

http://www.youtube.com/watch?v=iNspo_s-1jY

Co-generation Plant at NYU (3 min.)

http://www.youtube.com/watch?v=9m9SgsTTgiA&feature=related

Biomass Co-Generation Plant at Nagda site (4 min.)

http://www.youtube.com/watch?v=tARuhig03To

Hydro Power (2 min.)

http://www.youtube.com/watch?v=Pj4dZM4SIls

Nuclear Power – How it works (5 min.)

http://www.youtube.com/watch?v=_UwexvaCMWA

Wind Turbines (UVSAR, 10 min.)

http://www.youtube.com/watch?v=LNXTm7aHvWc&feature=related

Offshore Wind Construction (Belwind, 14 min.)

http://www.youtube.com/watch?v=x9IntSh2K7c

Utility Scale Solar PV (ABB, 2 min.)

http://www.youtube.com/watch?v=edYNj_TrTXY&hd=1

Concentrating Solar Thermal (2 min.)

https://www.youtube.com/watch?v=tdivW7inP0k

Geothermal (3 min.)

https://www.youtube.com/watch?v=kjpp2MQffnw

Tidal and Wave Power (5 min.)

http://www.youtube.com/watch?v=tSBACzRE3Gw&feature=related

Energy Storage Options

- Electricity Storage

Columbia Social Enterprise Forum – Energy Storage and Battery Technology (56 min.)

http://www.youtube.com/watch?v=661-GIswZco&hd=1

Pumped Hydro Storage – in German with translation (2 min.)

http://www.youtube.com/watch?v=GJ7ltJlMY9E

Grid Storage – A123 Batteries (DoE, 9 min.)

http://www.youtube.com/watch?v=6C8Ji05UJaw

Oil and Transportation Markets

- Petroleum

- Supply Chain Analysis

Oil and Gas Drilling (4 min.)

https://www.youtube.com/watch?v=qhZ50NCbVKo

Refinery (14 min.)

http://www.youtube.com/watch?v=9Py8-Xy9MKo

Transportation Fuels – GHG implications (5 min.)

http://www.youtube.com/watch?v=hq2uWWBqe4M

Megastructures - Oil Sands (40 min.)

https://www.youtube.com/watch?v=5F17MXBZzc0

Shale Oil (Energy Now, 28 min.)

http://www.youtube.com/watch?v=U_T-AwYOhp4&feature=related

Biofuels Ethanol from Sugar Cane- Production Process (15 min.)

Energy Systems Fundamentals – Fall 2024

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- Biofuels

http://www.youtube.com/watch?v=kP1S2HGf5-E

Ethanol from Corn – Production Process (5 min.)

https://www.youtube.com/watch?v=uE7DJVCa5h0

How it is made – Biodiesel (4 min.)

http://www.youtube.com/watch?v=xLa83KIaEyw

Biofuels, Beyond Ethanol (10 min.)

http://www.youtube.com/watch?v=CkJJ-x7U5NI

Electricity in Transportation

Markets

- Electric Vehicles

- Fuel Cell Vehicles

The State of Electric Vehicles in America (29 min.)

http://www.youtube.com/watch?v=1ZGQgZPaQ6o&feature=relmfu

Energy 101 Fuel Cells (43 min.)

https://www.youtube.com/watch?v=41Nb6juV6MI

Natural Gas Markets

Natural Gas Production and Marketing (Chesapeake Energy, 10 min.)

http://www.youtube.com/watch?v=2Gw_Bn-JqDg

Natural Gas Pipelines Operation (9 min.)

http://www.youtube.com/watch?v=aTTJeTaYDyc

Hydraulic Fracturing (Marathon Oil, 3 min.)

https://www.youtube.com/watch?v=VY34PQUiwOQ

Natural Gas: The Energy to move Forward (Conoco Philips, 5 min.)

http://www.youtube.com/watch?v=BzLZnidztpI

History – I am Natural Gas – 1959 (3 min.)

http://www.youtube.com/watch?v=PKX0GeF9w-k

History – Natural Gas Pipeline Development – 1959 (1 min.)

http://www.youtube.com/watch?v=Wodvxh6WEs4

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