I'm deep into the process of converting an upstairs bedroom in our home to an office. Actually, the job is almost complete. I'm just waiting for the new furniture to arrive. But I thought I would share some of my experience here...including my failed quest for a "sustainable floor". I must confess I did not fully appreciate the adventure before me as I contemplated the job a couple of months ago.
The subject bedroom was that of our daughter, who's now grown and on her own. The legacy of my daughter's habitation of the room included over 100 phosphorescent stars that had been attached to the ceiling with permanent glue, a similar number of flattened glass marbles and soda can "pull-tabs" that had been hot-glued to the wind facings, and (probably) 10,000 thumbtack holes in the sheetrock walls. Luckily, we had never papered the walls. So it was (simply, I thought) a matter of removing the stars, marbles, and pull-tabs, spackling the thumbtack holes, and repainting everything. Several trips to the Sherwin-Williams paint store, three gallons of paint (had to try a couple of different trim colors), and over two weeks later, this part of the job was complete.
Next came the removal of the bottom wall trim and carpet (I'm on a quest to remove every square inch of carpet from our home). No problem. The removal went well. The next step was installing over 200 screws to secure the sub-flooring to the floor joists to assure the floor would not squeak once it was installed. Wallah! No squeaks. Now I was ready for the new flooring.
Time to tour the local flooring sources to survey my options. This is when the trouble began. First, because my home was built in 1981, it has sub-flooring that is not compatible with either nailed or glued hardwood floors. So my only choice was so-called "floating floor" systems. No problem – there's lots of them on the market. But I love South American and African hardwood floors. The problem is I deplore what is being done to the South American and African forests to obtain the wood. So I decided months ago that those beautiful floors where not in my future. I wanted (you guessed it) a "sustainable floor".
Right now, it seems the king of sustainable floors is bamboo. If the marketing hype is to be believed, bamboo grows to harvestable size in only 8-10 years – rather than the many decades required for American, South American, or African hardwoods. Shazam! I'd found my solution.
I next located a "solid click woven bamboo" product my wife and I loved, at a local supplier. The stuff was beautiful, 3/4-inch thick, 55-year guarantee, hardness rating of "5" (as hard as they come). Perfect! So... we order the flooring – about $5 per square foot.
Three weeks later the flooring is delivered. Two weeks after that, the installer appears – a really nice husband and wife team who clearly knew their business (I know this because they were suitably impressed with those 200 screws I had put in the floor.) They began to work as I sat downstairs finishing my breakfast, sipping my morning tea, and reading the newspaper.
Forty-five minutes pass. The phone rings. It's the supplier telling me there's a problem with my floor. What? The installer is just upstairs and I've head nothing of this. I go up stairs. The installer meets me coming down the stairs. "Mr. Greene, I think you should look at this before we go any further. Our protocol required me to call the office before I spoke with you." Not promising.
I peek in the room. Approximately 1/3 of the flooring is installed. It's absolutely beautiful. Then the installer says, "walk on it". I took a step. "Snap!". Another step. "Crackle!". A third step. "Pop". I thought I was listening to a vintage 1960's breakfast cereal commercial. It was awful. Every step was followed with a chorus of sounds that only a depraved, acid-dropping percussionist would enjoy. "What's the problem," I asked. "We don't know. Some of the flooring is warped, but it's all within the manufacture's specification. We could probably stop the squeaking by gluing it down, but we called the manufacturer and they said don't do it. That would void the warranty."
"So what do we do," I asked. "The manufacture says to go ahead an install it. It should stop squeaking after about six weeks. If not, they'll come out and inspect it. Then they may choose to replace it." "No way," says I. "Rip it up and take it back to the store." Then, with a sheepish grin, the installer says, "That's what I thought you would say. After I saw those 200 screws and the trouble you went to to eliminate all of the squeaks in the sub flooring, I knew this wouldn't be acceptable." They spent the next hour or so ripping it out, carrying it out to the truck, and cleaning up the job site.
I spent that afternoon researching that specific flooring product and similar floating bamboo flooring systems, focusing on the squeaking issue. The consensus seems to be that current products are indeed beautiful. And they are rugged, long-lived systems. But... practically all of the floating bamboo floor system squeak. Though disappointed with this state of affairs, I prefer to think the real truth is that all these systems were engineered for installation in Japan, where the famous "talking floors" were used for centuries to alert sleeping nobility of a ninja attack...
The bottom line: I failed in my quest for a sustainable floor. It seems the technology (at least for floating floor systems) simply isn't there yet. I now have a high-end laminate flooring product installed. It's beautiful, has a lifetime warranty. And NO SQUEAKS!
But I still dream of that beautiful bamboo floor...
It's tough to be sustainable...
Just Thinking,
Sherrell
Sunday, January 8, 2012
Sunday, January 1, 2012
Post # 59: New Year's Resolutions ???
Happy New Year!
I wanted to take a moment to convey my well-wishes to each of you who frequent my blog, and to share a few of my New Year's Resolutions related to Sustainable Energy.
Studies show that, while most New Year's resolutions aren't kept for more than a brief period, those who do make specific resolutions are ten times more likely to achieve their goals than those who do not. It's also true that even if one isn't totally successful at keeping a resolution, the act of "failing-forward" generally leaves one in a superior state relative to one's beginning. So make those resolutions and either succeed, or fail-forward!
I tend to categorize my resolutions into two categories: HEALTH (Spiritual, Physical, Emotional, Financial), RELATIONSHIPS (God, Family, Friends & Neighbors, Colleagues, Clients, Society, and Planet Earth and the Biosphere I inhabit). These two categories aren't completely independent, of course. You may use other categories such as "personal" and "business/career", etc. But I find if I take care of my health, and invest in the people in my life who are dear to me (my relationships), everything else takes care of itself...
So here are four New Year's Sustainability Resolutions (from the last Relationships category) I intend to pursue:
1. Reuse, Repurpose, and Recycle more. I've been amazed to see that we've begun recycling ~85% (by volume) of our household refuse since curb-side recycling came to our neighborhood. This year I intend to maintain or improve further upon this metric, while giving more attention to personal reuse and "re-purposing" of "stuff" that no longer serves its original purpose in hour home.
2. Increase my personal consumption of drinking water, while decreasing my overall household water consumption. My wife constantly tells me I don't drink enough water. (I don't). So I intend to pay more attention to person hydration. But clean water is an endangered resource around the globe. Beyond that, the connection between surface water and energy production is an intimate one. So we'll endeavor this year to reduce our household "gray" and waste-water production.
3. Turn off the lights when I leave the room (Mom said so!) This feels right. Though I must admit I haven't fully investigated this practice from a life-cycle issue. I do wonder whether the frequent cycling of household lighting systems (of all technologies) tends to increase their failure rate and thus the overall life-cycle dollar and environmental costs of lighting. Are there usage patters or technologies in which it makes more sense to "let em burn"? I will investigate this issue and I welcome your comments on the subject.
Finally,
4. Simplify! De-clutter! Everything. My life. My time. My home... Less really can be more! So let's go explore!
Again, I wish each of you a joyous and prosperous 2012! And let's remember... over a billion people in this world live their lives without the benefits of electricity. Another three billion or so live with significantly less access to electricity than we enjoy in the western world. Let's commit ourselves to the goal of improving their lives while improving our stewardship of this wonderful planet we inhabit.
Just Thinking...
Sherrell
Publish Post
I wanted to take a moment to convey my well-wishes to each of you who frequent my blog, and to share a few of my New Year's Resolutions related to Sustainable Energy.
Studies show that, while most New Year's resolutions aren't kept for more than a brief period, those who do make specific resolutions are ten times more likely to achieve their goals than those who do not. It's also true that even if one isn't totally successful at keeping a resolution, the act of "failing-forward" generally leaves one in a superior state relative to one's beginning. So make those resolutions and either succeed, or fail-forward!
I tend to categorize my resolutions into two categories: HEALTH (Spiritual, Physical, Emotional, Financial), RELATIONSHIPS (God, Family, Friends & Neighbors, Colleagues, Clients, Society, and Planet Earth and the Biosphere I inhabit). These two categories aren't completely independent, of course. You may use other categories such as "personal" and "business/career", etc. But I find if I take care of my health, and invest in the people in my life who are dear to me (my relationships), everything else takes care of itself...
So here are four New Year's Sustainability Resolutions (from the last Relationships category) I intend to pursue:
1. Reuse, Repurpose, and Recycle more. I've been amazed to see that we've begun recycling ~85% (by volume) of our household refuse since curb-side recycling came to our neighborhood. This year I intend to maintain or improve further upon this metric, while giving more attention to personal reuse and "re-purposing" of "stuff" that no longer serves its original purpose in hour home.
2. Increase my personal consumption of drinking water, while decreasing my overall household water consumption. My wife constantly tells me I don't drink enough water. (I don't). So I intend to pay more attention to person hydration. But clean water is an endangered resource around the globe. Beyond that, the connection between surface water and energy production is an intimate one. So we'll endeavor this year to reduce our household "gray" and waste-water production.
3. Turn off the lights when I leave the room (Mom said so!) This feels right. Though I must admit I haven't fully investigated this practice from a life-cycle issue. I do wonder whether the frequent cycling of household lighting systems (of all technologies) tends to increase their failure rate and thus the overall life-cycle dollar and environmental costs of lighting. Are there usage patters or technologies in which it makes more sense to "let em burn"? I will investigate this issue and I welcome your comments on the subject.
Finally,
4. Simplify! De-clutter! Everything. My life. My time. My home... Less really can be more! So let's go explore!
Again, I wish each of you a joyous and prosperous 2012! And let's remember... over a billion people in this world live their lives without the benefits of electricity. Another three billion or so live with significantly less access to electricity than we enjoy in the western world. Let's commit ourselves to the goal of improving their lives while improving our stewardship of this wonderful planet we inhabit.
Just Thinking...
Sherrell
Publish Post
Tuesday, December 6, 2011
Post # 58: New Planets, Water, Fracking, and Energy
Water is the substance of life. You and I are mostly water. Life, as we know it, isn't possible without water. Just yesterday NASA announced the discover of a new "earth-like" planet – Kepler-22b. This planet joins a list of over 500 other recently-discovered planets that potentially have the right temperatures, atmospheres, and surface conditions to support life as we know it. The presence of liquid water is a key metric of the "friendly-to-life" assessment.
As a young boy I occasionally accompanied my father and grandfather, who were involved in the operation of a rural east Tennessee water utility district, on visits to the large springs that were the utility's water source. I was then and am still fascinated and amazed when I see enormous volumes of cool, clean water erupting from the ground. There's something magical about a spring.
Some of you know I'm a supporter of the Nature Conservancy, and a long-time member of Trout Unlimited - a cold water fishery conservation organization. As I sit here this morning typing these words, it's raining in East Tennessee. It rains a lot in East Tennessee. We are blessed with a abundant surface water - springs, ponds, streams, rivers, and man-made lakes. Or at least we have been blessed in the past. Surface water is a precious commodity. In recent years Tennessee, like many of our sister states in the southeast, has experienced some unusual extremes in weather, and repeated periods of drought. (Just last week, we experienced a period of heavy rain and flooding.)
I think a lot about water and energy-water nexus issues. This is one of the reasons I'm so interested in the increasing using of fracking in the natural gas and oil production industry. I'm not the only one watching this issue closely. Witness the Wall Street Journal's article in this morning's edition. Fracking, or hydraulic fracturing, is a technique in which water (normally surface water), sand, and chemicals is injected into deep natural gas and oil wells as a means to extract more "dino-fuel" from the surrounding geological deposits.
A typical oil or natural gas well drilling project in the eastern U.S. shale deposits might use ~ 65,000 to perhaps 600,000 gallons of water during the drilling process, and another 5,000,000 gallons during the natural gas extraction process. So, let's say ~ 6,000,000 gallons or so. Sources I've consulted indicate this about the amount of water used by New York City in ten minutes, by a 1 GWe coal-fired power plant in less than a day, a typical golf course in about a month, or perhaps 10 acres of corn in a season. But of course, the ultimate destiny (location, content, temperature, etc) of the water used in these differing applications is very different.
At this juncture, I'm not opposed to fracking. But I am increasingly concerned. Fracking is currently banned in France, and in portions of Australia, South Africa, and Canada. The natural gas industry is working hard to keep fracking safe, and is adamant that the probability of a major leak into a near-surface aquifer is extremely low. However, as I've mentioned before, the potential for a "Black Swan" event in which a fracking operation pollutes a major ground water aquifer is never far from my thinking. Such an event could radically change the outlook for fracking in the U.S. and elsewhere – along with the rosy predictions for abundant natural gas supplies in the coming decades.
Just like nuclear power, one of the "costs" of fracking will be eternal vigilance on the safety and environmental protection fronts. I'm not a geologist, but one has to wonder about the long-term disposition of these wells and whether there are "failure modes" that could provide pathways for ground water contamination over decades as the subterranean well structures age.
As a young boy I occasionally accompanied my father and grandfather, who were involved in the operation of a rural east Tennessee water utility district, on visits to the large springs that were the utility's water source. I was then and am still fascinated and amazed when I see enormous volumes of cool, clean water erupting from the ground. There's something magical about a spring.
Some of you know I'm a supporter of the Nature Conservancy, and a long-time member of Trout Unlimited - a cold water fishery conservation organization. As I sit here this morning typing these words, it's raining in East Tennessee. It rains a lot in East Tennessee. We are blessed with a abundant surface water - springs, ponds, streams, rivers, and man-made lakes. Or at least we have been blessed in the past. Surface water is a precious commodity. In recent years Tennessee, like many of our sister states in the southeast, has experienced some unusual extremes in weather, and repeated periods of drought. (Just last week, we experienced a period of heavy rain and flooding.)
I think a lot about water and energy-water nexus issues. This is one of the reasons I'm so interested in the increasing using of fracking in the natural gas and oil production industry. I'm not the only one watching this issue closely. Witness the Wall Street Journal's article in this morning's edition. Fracking, or hydraulic fracturing, is a technique in which water (normally surface water), sand, and chemicals is injected into deep natural gas and oil wells as a means to extract more "dino-fuel" from the surrounding geological deposits.
A typical oil or natural gas well drilling project in the eastern U.S. shale deposits might use ~ 65,000 to perhaps 600,000 gallons of water during the drilling process, and another 5,000,000 gallons during the natural gas extraction process. So, let's say ~ 6,000,000 gallons or so. Sources I've consulted indicate this about the amount of water used by New York City in ten minutes, by a 1 GWe coal-fired power plant in less than a day, a typical golf course in about a month, or perhaps 10 acres of corn in a season. But of course, the ultimate destiny (location, content, temperature, etc) of the water used in these differing applications is very different.
At this juncture, I'm not opposed to fracking. But I am increasingly concerned. Fracking is currently banned in France, and in portions of Australia, South Africa, and Canada. The natural gas industry is working hard to keep fracking safe, and is adamant that the probability of a major leak into a near-surface aquifer is extremely low. However, as I've mentioned before, the potential for a "Black Swan" event in which a fracking operation pollutes a major ground water aquifer is never far from my thinking. Such an event could radically change the outlook for fracking in the U.S. and elsewhere – along with the rosy predictions for abundant natural gas supplies in the coming decades.
Just like nuclear power, one of the "costs" of fracking will be eternal vigilance on the safety and environmental protection fronts. I'm not a geologist, but one has to wonder about the long-term disposition of these wells and whether there are "failure modes" that could provide pathways for ground water contamination over decades as the subterranean well structures age.
Access to clean air, clean water, and abundant energy are the most important enablers of a life on this planet relatively free from hunger, ignorance, and suffering. So these issues are inextricably intertwined from cradle to grave on both the production and utilization sides of the equation. We all have a stake in the continued safety of fracking - a process that seems destined to expand greatly as we seek to extract more oil and gas for an energy-hungry world.
Cheers,
Sherrell
Monday, November 21, 2011
Post # 57: Energy Technology: The Innovation Challenge
I've been doing a lot of thinking during the past several months about innovation (or the lack thereof) in the energy sector. By innovation, I mean the entire process from basic discovery though technology implementation and impact. (I'm all about impact these days...)
Why all the focus on innovation? Michael Mandel, the Chief Economic Strategist at the Progressive Policy Institute, recently posted on the Atlantic website a pointed article about the importance of innovation to our economy. The article, entitle "There Are Only Two Ways to Save the Economy: Innovation or Inflation" is good reading. His core message is that if our economy is to recover, we must either grow (through technical innovation that leads to job growth and overall economic growth), or we must purposefully inflate our way out of the mess we're in. He states, "...we have to shift from a consumer economy to a production economy. This is partly about a change in spending patterns, but also about a change in attitude. For example, we need to boost R&D and other investment in knowledge capital, but we also need federal regulatory agencies to encourage rather than discourage innovation. We need more infrastructure spending and other investment in physical capital, but it should be directed towards supporting exports and production in the U.S., rather than clearing up bottlenecks of imported consumer goods. This profound shift in policy and behavior is essential over the long run, but it won't be easy or quick."
This seems to be a timely topic. Time Magazine's current issue carries the title, "The Invention Issue." Of course, invention is but one step in the chain between discovery and impact. I thought I might offer some snippets from my current stream of consciousness about innovation in the energy sector. We'll focus on patents as one indicator of innovation. (Again, patents are only one indicator reflective of one milepost in the road between discover and impact.)
Why all the focus on innovation? Michael Mandel, the Chief Economic Strategist at the Progressive Policy Institute, recently posted on the Atlantic website a pointed article about the importance of innovation to our economy. The article, entitle "There Are Only Two Ways to Save the Economy: Innovation or Inflation" is good reading. His core message is that if our economy is to recover, we must either grow (through technical innovation that leads to job growth and overall economic growth), or we must purposefully inflate our way out of the mess we're in. He states, "...we have to shift from a consumer economy to a production economy. This is partly about a change in spending patterns, but also about a change in attitude. For example, we need to boost R&D and other investment in knowledge capital, but we also need federal regulatory agencies to encourage rather than discourage innovation. We need more infrastructure spending and other investment in physical capital, but it should be directed towards supporting exports and production in the U.S., rather than clearing up bottlenecks of imported consumer goods. This profound shift in policy and behavior is essential over the long run, but it won't be easy or quick."
I'm obviously sympathetic to Michael's argument. I recently had an extended discussion with Charles Barton of The Nuclear Green Revolution blog. Innovation was one of the many subjects we discussed. (Charles has posted most of the content of our discussion on his blog.) My comment to Charles was,
"The environment in today’s nuclear energy enterprise is hostile to innovation. Not by intent, but in reality nevertheless. The industry is highly regulated. It is very costly to do research, development, and demonstration. It’s a very capital-intensive business. The barriers to entry are incredibly high. The down-side risks of innovation are more easily rendered in practical terms than the upside gains. Often it seems everyone in the enterprise (federal and private sectors) are so risk-averse that innovation is the last thing on anyone’s mind. In this environment, “good-enough” is the enemy of “better”. Humans learn by failing. It’s the way we learn to walk, talk, and ride a bicycle. Our environment today has little tolerance for failures at any level. There’s no room for Thomas Edison’s approach to innovation in today’s world. On top of all of this, or perhaps because of it, the nuclear industry invests less on R&D, as a percentage of gross revenues, than practically every other major industry you might name."
So this got me to wondering about innovation in other energy sectors. One of the sources of information I turned to was the World Intellectual Property Organization (WIPO). WIPO's document, Patent-based Technology Analysis Report – Alternative Energy summarizes almost 78,000 recent alternative energy patent applications from the U.S., Europe, Japan, Korea, the People's Republic of China, and WIPO's patent office. The data roughly covered the period between 1976 and 2008. (In case you're wondering, only 15,326 of those patent applications came from the U.S. Patent Office. An amazing 42,842 of them came from the Japanese Patent Office. That's more than everyone else combined!) The analysis focuses on solar energy, wind energy, bio energy, hydro energy, geothermal energy, wave/tidal power, hydrogen, fuel cells, carbon capture and storage, and waste-to-energy (using stuff otherwise destined for landfills for direct burning or liquid fuels production). There are several interesting analyses in the report. One insight (their Figure 2) is that the global rate of patent filings peaked around 2003 and has since decreased (caveat: no data for 2009 and later years).
A second insight is that the rate of alternative energy patent applications in the U.S. peaked in 2002 at just a bit more than 1500, dropped by 20% to around 1300 in 2004, and was headed downward at a pretty fast clip at that time.
One of the most interesting observations is WIPO's analysis of the global pattern of patent activity. I quote from their report,
"A general model for patterns in patenting activity can be established to understand the stages of development of a particular technology. On the introduction of a new technology, only a small number of applicants are involved in patenting in the field and only few applications are filed. Following this growth period, the technology enters a development period, during which the technology develops rapidly as a result of active competition between numerous applicants, who together file many applications. As research and development continues, the growth in the number of applications stagnates or declines as does the number of applicants. This period can be termed a “maturity period”. As new technologies or even entirely new technology paradigms emerge, a period of decline begins for the original technology, at which point the number of applications and applicants in that field declines strongly. It is possible for a revival of interest to occur in the original technology, if a new application can be found for it, leading to resurgence in the number of applications and applicants (KIPI 2005)."
Figure 4 from their report is a graphic depiction of this pattern (I apologize for the poor quality of the clip):
One has to wonder how the superposition of the nuclear energy innovation challenges I mentioned above impacts this model. I believe most of these challenges lead to "technology lock-in" and "loitering" in Stage III of the process.
A number of other organizations, including the International Energy Agency (IEA) 2009 are engaged in the business of spurring and coordinating energy R&D. See, for instance, IEA's reports on global energy R&D portfolios.
Margolis and Kammen argued in the 30 July 1999 issue of Science (Vol 285 no. 5428 pp. 690-692) that R&D intensity in the U.S energy sector was extremely low and was reducing the capability of the sector to innovate. Looks like little has changed...
"The environment in today’s nuclear energy enterprise is hostile to innovation. Not by intent, but in reality nevertheless. The industry is highly regulated. It is very costly to do research, development, and demonstration. It’s a very capital-intensive business. The barriers to entry are incredibly high. The down-side risks of innovation are more easily rendered in practical terms than the upside gains. Often it seems everyone in the enterprise (federal and private sectors) are so risk-averse that innovation is the last thing on anyone’s mind. In this environment, “good-enough” is the enemy of “better”. Humans learn by failing. It’s the way we learn to walk, talk, and ride a bicycle. Our environment today has little tolerance for failures at any level. There’s no room for Thomas Edison’s approach to innovation in today’s world. On top of all of this, or perhaps because of it, the nuclear industry invests less on R&D, as a percentage of gross revenues, than practically every other major industry you might name."
So this got me to wondering about innovation in other energy sectors. One of the sources of information I turned to was the World Intellectual Property Organization (WIPO). WIPO's document, Patent-based Technology Analysis Report – Alternative Energy summarizes almost 78,000 recent alternative energy patent applications from the U.S., Europe, Japan, Korea, the People's Republic of China, and WIPO's patent office. The data roughly covered the period between 1976 and 2008. (In case you're wondering, only 15,326 of those patent applications came from the U.S. Patent Office. An amazing 42,842 of them came from the Japanese Patent Office. That's more than everyone else combined!) The analysis focuses on solar energy, wind energy, bio energy, hydro energy, geothermal energy, wave/tidal power, hydrogen, fuel cells, carbon capture and storage, and waste-to-energy (using stuff otherwise destined for landfills for direct burning or liquid fuels production). There are several interesting analyses in the report. One insight (their Figure 2) is that the global rate of patent filings peaked around 2003 and has since decreased (caveat: no data for 2009 and later years).
Total alternative energy patent applications and application growth rates (Ref: Figure 2 from "Patent-based Technology Analysis Report – Alternative Energy," WIPO.
A second insight is that the rate of alternative energy patent applications in the U.S. peaked in 2002 at just a bit more than 1500, dropped by 20% to around 1300 in 2004, and was headed downward at a pretty fast clip at that time.
One of the most interesting observations is WIPO's analysis of the global pattern of patent activity. I quote from their report,
"A general model for patterns in patenting activity can be established to understand the stages of development of a particular technology. On the introduction of a new technology, only a small number of applicants are involved in patenting in the field and only few applications are filed. Following this growth period, the technology enters a development period, during which the technology develops rapidly as a result of active competition between numerous applicants, who together file many applications. As research and development continues, the growth in the number of applications stagnates or declines as does the number of applicants. This period can be termed a “maturity period”. As new technologies or even entirely new technology paradigms emerge, a period of decline begins for the original technology, at which point the number of applications and applicants in that field declines strongly. It is possible for a revival of interest to occur in the original technology, if a new application can be found for it, leading to resurgence in the number of applications and applicants (KIPI 2005)."
Figure 4 from their report is a graphic depiction of this pattern (I apologize for the poor quality of the clip):
A general model for patent filing activity (Ref: Figure 4 from "Patent-based Technology Analysis Report – Alternative Energy," WIPO.
One has to wonder how the superposition of the nuclear energy innovation challenges I mentioned above impacts this model. I believe most of these challenges lead to "technology lock-in" and "loitering" in Stage III of the process.
A number of other organizations, including the International Energy Agency (IEA) 2009 are engaged in the business of spurring and coordinating energy R&D. See, for instance, IEA's reports on global energy R&D portfolios.
Margolis and Kammen argued in the 30 July 1999 issue of Science (Vol 285 no. 5428 pp. 690-692) that R&D intensity in the U.S energy sector was extremely low and was reducing the capability of the sector to innovate. Looks like little has changed...
So, I will continue to bombard the energy technology innovation issue with simple questions. "What is the innovation process, and how does the process work (or alternatively, why doesn't it work?" "Who's doing the innovating?" "Where is innovation happening?" "How can the innovative cycle be accelerated?" These are not simply intellectual sandbox exercises. The quality of life of billions of our fellow human beings around the world depend on the answers... Here's to success!
Just thinking...
Sherrell
Just thinking...
Sherrell
Wednesday, November 9, 2011
Post # 56: Sobering News From International Energy Agency
The International Energy Agency (IEA) released its World Energy Outlook 2011 today.
I'm still absorbing the analysis, but the best way to describe the message of the report is "sobering".
According to IEA analysis, unless the world takes "bold" action (their term) to change our energy policies, we will be locked into an "insecure, inefficient and high-carbon" energy system. They go on to say, "Governments need to introduce stronger measures to drive investment in efficient and low-carbon technologies. The Fukushima nuclear accident, the turmoil in parts of the Middle East and North Africa and a sharp rebound in energy demand in 2010 which pushed CO2 emissions to a record high, highlight the urgency and the sale of the challenge."
The IEA typically explores futures by scenario analysis. The "New Policies Scenario" is, given our current direction, probably the best that can be hoped for. In this scenario, recent government commitments are implemented in a "cautious" manner. Under this assumption, and given current population and economic mega-trends, the year 2035 looks like this:
I'm still absorbing the analysis, but the best way to describe the message of the report is "sobering".
According to IEA analysis, unless the world takes "bold" action (their term) to change our energy policies, we will be locked into an "insecure, inefficient and high-carbon" energy system. They go on to say, "Governments need to introduce stronger measures to drive investment in efficient and low-carbon technologies. The Fukushima nuclear accident, the turmoil in parts of the Middle East and North Africa and a sharp rebound in energy demand in 2010 which pushed CO2 emissions to a record high, highlight the urgency and the sale of the challenge."
The IEA typically explores futures by scenario analysis. The "New Policies Scenario" is, given our current direction, probably the best that can be hoped for. In this scenario, recent government commitments are implemented in a "cautious" manner. Under this assumption, and given current population and economic mega-trends, the year 2035 looks like this:
- Total global primary energy demand has increased by 1/3 relative to 2010 levels. Ninety percent of this demand growth is in non-OECD countries. China is consuming 70% more energy than the U.S., with per-capita demand still less than half that of the average American.
- The percentage of energy supplied by fossil fuels drops from today's 81% to 75%. Renewables share of energy production rises from 13% to 19%, based on subsidies that rise from $65B in 2910 to $250B in 2035. (Want to take odds on all those subsidies coming through?) It is worth noting, though that the IEA calculates that global fossil subsidies in 2010 amounted to $409B.
- Oil demand rises from 87 million barrels/day in 2010 to just 99 million barrels/day in 2035. Virtually all of this is driven by growth in the transportation sectors of emerging economies. (Everyone wants a personal automobile.)
- The 2035 price of oil is assumed to reach just $120/barrel in 2010 dollars. (I think this is a low-ball assumption).
- The use of coal RISES 65% by 2035.
- Nuclear power output rises by only 70% by 2035.
- Natural gas's share of energy production rises dramatically, almost equaling that of coal.
- Carbon dioxide emissions between 2010 and 2035 amount to 3/4 of the total emitted during the past 110 years.
- Approximately $38 Trillion in investments is required by 2035 – about $1.5 Trillion per year – to achieve this scenario. The investment breakdown is: $16.9 trillion in the Power sector, $10.0 trillion in the Oil sector, $9.5 trillion in the Gas sector, and $1.2 trillion in the Coal sector.
- The global average temperature rise is 3.5 ºC.
The IEA also looked at a "450 Scenario", which lays out a pathway to to achieving a 2ºC global average temperature rise. There's some really sobering news here. According to EIA's analysis, given the existing energy infrastructure in place, all of the emissions allowed through 2035 will be emitted by 2017. We are "locked-in". A major redirection of global policies would be required to address this problem. According to the EIA, "Delaying action is a false economy: for every $1 of investment in cleaner technology that is avoided in the power sector before 2020, an additional $4.30 would need to be spent after 2020 to compensate for the increased emissions." As they say, "the door to 2ºC is closing...
The IEA also conducted some interesting parametric analyses which they've not yet posted. They have a "low nuclear" variant in which nuclear energy drops by 15% by 2035. They also focus quite a bit of attention on China's per-capital energy demand growth... Most of the variants appear to make matters worse.
Given all of this news, and an attention deficit world awash in all sorts of distractions, it's not unreasonable to consider scenarios in which efforts to reduce carbon emissions are not successful. In that event, we can (a) hope the climate modelers are wrong, (b) pursue terra-forming to alter the atmospheric dynamics, or (c) prepare to deal with all of the ramifications of a warmer climate.
Quite a Gedanken Experiment!
Cheers,
Sherrell
Monday, November 7, 2011
Post # 55: Nuclear Energy - Fallen and Can't Get Up ?
Last week I attended the winter meeting of the American Nuclear Society (ANS) in Washington, D.C. It was a time to catch-up with friends and colleagues; let folks know that though I've "retired" from ORNL, I have not retired; and hear the latest technical and business updates from the nuclear energy community.
I must admit I left the meeting with a touch of the "blahs". The tone of the meeting, from beginning to the end, was "haunted" (Halloween occurred during the meeting) by three underlying thoughts: (1) the overall US and global economic malaise, (2) real and potential repercussions from the Fukushima Dai-ichi incident, and (3) the blessing/curse of cheap natural gas. These realities directly and indirectly resurfaced multiple times while I was there.
I'm reminded of the famous TV commercial from several years ago involving an elderly lady who's laying in her kitchen floor calling out, "Help! I've fallen and I can't get up!". I couldn't help but wonder, "Is this dear lady's exclamation a metaphor for nuclear energy?"
It seems every time during the past 25 years we were on the verge of a "nuclear renaissance", a major setback occurred... Is this "deja vu all over again" as Yogi Berra famously quipped? Sure looks like it - in the U.S. and Europe at any rate...
The continuing domestic and global economic malaise has two major short-term impacts on nuclear power: (1) it decreases electric load growth rates, and (2) it creates a risk aversion paranoia in the financial sector. The first factor enables utility planners to delay capacity additions needed to meet load growth. The second factor makes it more difficult for companies to proceed with capital-intensive endeavors. Small Modular Reactors (SMRs) have the potential to help in the second case, by reducing both the lump sums of capital to be borrowed, and providing earlier revenue generation from the capital that is borrowed. (More about SMRs later...)
I'm happy that natural gas prices are as low as they are. I cook with natural gas, dry my cloths with it, and heat my house with it. But I wonder... what if fracking turns out NOT to be the panacea it is currently believed to be by many in the gas industry? The future for domestic gas production would be severely impacted if fracking were to become an unacceptable practice. What might lead to this outcome? An "accident" in which a major aquifer becomes contaminated and unusable for human consumption. That could be a Black Swan for fracking. I hope it never occurs, but I shared here before my concern about the potential environment impacts of widespread fracking.
The echos of the Fukushima accident still ring loudly in the nuclear industry and will continue to do so for years to come. One of the immediate impacts of the Fukushima accident was a major scaling-back of business expansion and staffing plans by major nuclear vendors and suppliers.... a "hunkering-down" so to speak - in anticipation of a major knee-jerk response from governments and customers around the world who had new nuclear power construction plans on the table. And we have seen quite a bit of this response in Europe to be sure.
As I write this, futures prices for natural gas are sitting around $4 per million BTU. That's certainly not "too cheap to meter", but it's cheap. This reality is dominating the near-term behavior of energy suppliers in our country (and in many - but not all - other countries). One of the presentations I saw at the embedded ANS 2011 SMR Conference concluded that at natural gas prices of $6 per million BTU, virtually no other electrical generating technology (coal, SMRs, etc) will be competitive – unless carbon emissions are penalized. That means free market forces are unlikely to result in much new generating capacity other than gas-fired units for the foreseeable future.
So, am I bullish on nuclear energy? YES - in the mid-to-longterm! Friedman has said the world is "Flat, Hot, and Crowded". In my view, all three factors create a demand for safe, affordable, sustainable nuclear energy. Flat: the nuclear industry is global. Hot: Nuclear is among the lowest carbon emitting energy technologies on the planet. Crowded: Four billion people need energy – now. Nuclear energy is the only technology within our reach that can address a major portion of this need.
The middle-east appears poised to move ahead with nuclear energy. China and other parts of the Pacific Rim outside of Japan are moving. There are serious rumblings on the African and South American continents.
Where's the U.S. leadership?
I must admit I left the meeting with a touch of the "blahs". The tone of the meeting, from beginning to the end, was "haunted" (Halloween occurred during the meeting) by three underlying thoughts: (1) the overall US and global economic malaise, (2) real and potential repercussions from the Fukushima Dai-ichi incident, and (3) the blessing/curse of cheap natural gas. These realities directly and indirectly resurfaced multiple times while I was there.
I'm reminded of the famous TV commercial from several years ago involving an elderly lady who's laying in her kitchen floor calling out, "Help! I've fallen and I can't get up!". I couldn't help but wonder, "Is this dear lady's exclamation a metaphor for nuclear energy?"
It seems every time during the past 25 years we were on the verge of a "nuclear renaissance", a major setback occurred... Is this "deja vu all over again" as Yogi Berra famously quipped? Sure looks like it - in the U.S. and Europe at any rate...
The continuing domestic and global economic malaise has two major short-term impacts on nuclear power: (1) it decreases electric load growth rates, and (2) it creates a risk aversion paranoia in the financial sector. The first factor enables utility planners to delay capacity additions needed to meet load growth. The second factor makes it more difficult for companies to proceed with capital-intensive endeavors. Small Modular Reactors (SMRs) have the potential to help in the second case, by reducing both the lump sums of capital to be borrowed, and providing earlier revenue generation from the capital that is borrowed. (More about SMRs later...)
I'm happy that natural gas prices are as low as they are. I cook with natural gas, dry my cloths with it, and heat my house with it. But I wonder... what if fracking turns out NOT to be the panacea it is currently believed to be by many in the gas industry? The future for domestic gas production would be severely impacted if fracking were to become an unacceptable practice. What might lead to this outcome? An "accident" in which a major aquifer becomes contaminated and unusable for human consumption. That could be a Black Swan for fracking. I hope it never occurs, but I shared here before my concern about the potential environment impacts of widespread fracking.
The echos of the Fukushima accident still ring loudly in the nuclear industry and will continue to do so for years to come. One of the immediate impacts of the Fukushima accident was a major scaling-back of business expansion and staffing plans by major nuclear vendors and suppliers.... a "hunkering-down" so to speak - in anticipation of a major knee-jerk response from governments and customers around the world who had new nuclear power construction plans on the table. And we have seen quite a bit of this response in Europe to be sure.
As I write this, futures prices for natural gas are sitting around $4 per million BTU. That's certainly not "too cheap to meter", but it's cheap. This reality is dominating the near-term behavior of energy suppliers in our country (and in many - but not all - other countries). One of the presentations I saw at the embedded ANS 2011 SMR Conference concluded that at natural gas prices of $6 per million BTU, virtually no other electrical generating technology (coal, SMRs, etc) will be competitive – unless carbon emissions are penalized. That means free market forces are unlikely to result in much new generating capacity other than gas-fired units for the foreseeable future.
So, am I bullish on nuclear energy? YES - in the mid-to-longterm! Friedman has said the world is "Flat, Hot, and Crowded". In my view, all three factors create a demand for safe, affordable, sustainable nuclear energy. Flat: the nuclear industry is global. Hot: Nuclear is among the lowest carbon emitting energy technologies on the planet. Crowded: Four billion people need energy – now. Nuclear energy is the only technology within our reach that can address a major portion of this need.
The middle-east appears poised to move ahead with nuclear energy. China and other parts of the Pacific Rim outside of Japan are moving. There are serious rumblings on the African and South American continents.
Where's the U.S. leadership?
Wednesday, October 26, 2011
Post # 54: Faith and Nuclear Technology – The UT Baker Center Panel
It's been almost a month since I departed from ORNL. Doesn't seem possible. I believe I've been busier during the past four weeks than at any time in the past year! You may have guessed this from my absence here.... In any even, "I'm back ..." The length of this post will probably make up for my long absence (smile)...
Monday evening of this week I had the pleasure of participating in a public panel discussion hosted by the University of Tennessee's Howard H. Baker Jr. Center For Public Policy. The forum, entitled, "Nukes & Faith - Discussing Religion's Role in Nuclear Society and Energy". The forum was sponsored by the Tyson House Episcopal & Lutheran Campus Ministry, The Institute of Nuclear Materials Management, the UT Religious Studies Association, and the Baker Center. Mark Walker and David Burman, UT graduate students in nuclear engineering and religious studies, respectively, were the able organizers and moderators of the panel. My fellow panelists were Howard Hall (Governor's Chair Professor of Nuclear Engineering), Brandon Prins (Associate Professor of Political Science), and Jeffrey Kovac (Professor of Chemistry).
The UT Beacon ran an article today summarizing the lively and sometimes provocative discussions. Dr. Hall summarized the global status quo with regard to nuclear proliferation and some practical challenges associated with nuclear disarmament. Dr. Prins summarized extant research on the role of religion in major conflicts, and Dr. Kovac presented a nice synthesis of the various factors that combine to influence one's world view. Dr. Kovac and I were the two panel members who were explicitly asked by the organizers to discuss the role our faiths play in our approach to the challenges and opportunities posed by nuclear technologies. (Dr. Kovac is a Unitarian Universalist and I am an Evangelical Christian.)
The majority of the discussion dealt with nuclear weapons, nuclear proliferation, and nuclear disarmament. Nuclear energy was discussed to a somewhat lesser extent, though I focused much of my personal attention on nuclear energy.
So here is a condensed version of my comments on the major areas I was asked to address in the panel discussion:
1. What is the Evangelical Christian framework for consideration of matters such as nuclear proliferation and nuclear energy?
A Faith or a Belief System that does not equip and enlighten one to address the most profound matters of life is not really a "Faith". It's only a hobby. An Evangelical Christian will approach the topic of nuclear weapons and nuclear energy (or any major issue for that matter) by first synthesizing the relevant Biblical context. The Biblical context is then combined with temporal facts relevant to the topic. So, what are the relevant Biblical principles? Here's my personal list:
This is a really complicated question. The technologies being discussed by the Baker Center panel were nuclear weapons and nuclear power. One must begin by defining, precisely, the "technology" under consideration. A nuclear weapon is a particular embodiment of a suite of technologies and knowledge bases. Ditto a biological weapon – an integrated package. If one takes the view a biological weapon is intrinsically evil because it is intended for one purpose - the taking of human life - one then has to question the study of microbiology, microbe engineering, etc. – because they are some of the essential enablers of a biological weapon. In the case of nuclear weapons, it's the fission and fusion knowledge bases that are enabling. These weapons could not exist without these knowledge bases. However, the same knowledge base can be employed to end human life or save it. At what point along the pursuit of knowledge and integration of technologies does something become evil? Or is it simply the motives of the integrator or creator of a device? Or is it like the statement often made about pornography - you know it when you see it?
The history and (arguably) the success of the doctrine of Mutually Assured Destruction (MAD) is also a relevant anecdote. MAD is a cold war doctrine practice by the US and USSR. MAD basically stated that so long as each side could completely destroy each other, neither would launch an attack or provide an escalation of conventional conflict to the level that would trigger the use of nuclear weapons. I am one of many who believe the enormous stockpiles of nuclear weapons on the US and USSR sides during the cold war probably prevented a number of conventional wars that would have resulted in massive loss of life. IF this is indeed true, it challenges one's thinking about the evil of nuclear weapons. Is a nuclear weapon "evil" while it is sitting on a shelf, preventing the loss of life simply by its existence?
However, today's global situation is, in many ways, much more complex that the cold war situation. More dangers and threats from more directions than was the case in 1960. The US and Russia have made significant progress in reducing the number of warheads in our arsenals, while several other nations have joined the nuclear arms club. And then, of course, there are the "sub-national" and terrorist groups...
3. What is the Evangelical Christian view of nuclear weapons and nuclear proliferation?
Two of Christ's most relevant teachings are: (a) Luke 6:27 "But I say to you who hear, Love your enemies, do good to those who hate you..." (ESV); and (b) Luke 10:27 "You shall love the Lord your God with all your heart and with all your soul and with all your strength and with all your mind, and your neighbor as yourself." (ESV) Another relevant teaching is James 4:17 "So whoever knows the right thing to do and fails to do it, for him it is sin." (ESV) I also believe Paul's teaching in Romans Chapter 13:1-5 regarding the ordained role of governments to "bear the sword" and be an agent for good is relevant.
So, what am I to do when my "enemy" (whom I am to "love, do good to") and my "neighbor" (whom I am to "love as myself") are harming or killing each other? What am I to do when two neighbors (whom I am to love) are killing each other? What about when an "enemy" or a "neighbor" threatens to kill, inflict suffering on, or otherwise oppress the citizens of an entire country?
Love does not mean allowing someone to do whatever they wish - to themselves or to others. Love means acting in the best interests of others. If I have it within my power to prevent or stop killings, oppression, or suffering, when does Biblical doctrine require me to act? Christian theologians have wrestled with this issue for two thousand years. St. Augustine and Thomas Aquinas both offered considered views on the matter. Today, the "Just War Doctrine" traces it's origin in part to their thinking. Though too complex to discuss here, I believe, the Just War doctrine encompasses a Biblically-consistent decision framework for the use of force against our fellow man. However, it is far from perfect. I believe it is rare for a war to meet the "Just War" conditions. It is even more rare for a conflict that began as a "Just War" to continue to meet the conditions of a "Just War" as it progresses. Again, we live in an imperfect world. Sometime there are no good options.
Turning from the Biblical perspective to the more "mundane" global perspective, my view on nuclear weapons and nuclear proliferation is similar to my view about carbon in the atmosphere - more is not better. Though the "knowledge genie" is out of the bottle, it is right to work to limit the spread of weapons of mass destruction and to reduce the numbers of warheads as global conditions provide opportunities to do so.
4. What is the Evangelical Christian view of nuclear energy?
This is the easiest question of the four. As I type these words, we are days away from the birth of the 7 billionth person on this earth. One of the clear realities of our time is that the quality of life of an individual or a society is dominated by it's access to affordable and reliable energy - electricity in particular. Electricity is the key enabler of access to clean water, sanitation, conditioned living space, and food production. Currently, 25% of the human population of our planet has NO access to electricity. Another 35% or so have severely limited access. That's roughly 4 billion people whose quality of life and life expectancy is prisoner to the lack of electricity.
So how much electricity would be needed? I've run the numbers. Based on current per capita electricity consumption data, roughly 2 TW of new electrical generating capacity would be needed to raise the standard of living of those 4 billion people to that current enjoyed in the nation of South Africa (per capita electricity consumption ~ 5500 Kwh annually or an average of 630 watts continuously). Two-three times this much would be required to raise the standard of living of these 4 billion people to that enjoyed in the U.S and western Europe (~ 12,750 kwh annually or an average of 1455 watts continuously). The total global electrical generation capacity today is ~ 4.5 TW (4500 GW). This means we need to increase the net global electrical generating capacity by almost 50% in order to provide the South African standard of living to these 4 billion people, and we would have to more than double the total global generating capacity to raise their standard of living to that we enjoy in the U.S. This is a staggering challenge.
As a Christian, I feel we have a moral imperative to help our fellow man climb out of this energy supply "black hole". Beyond that, I feel strongly that the imbalance in quality of life and standard of living between those who have ready access to energy and those who do not will become one of the most disruptive global forces at play through the balance of this century. As a energy technologist, I'm convinced nuclear power is the only practical hope we have to address this enormous energy supply problem.
So there you have it... I've not related all the details of our Baker Center panel discussion, but enough to give you an idea of where I stand on these issues and why.
Cheers!
Sherrell
Monday evening of this week I had the pleasure of participating in a public panel discussion hosted by the University of Tennessee's Howard H. Baker Jr. Center For Public Policy. The forum, entitled, "Nukes & Faith - Discussing Religion's Role in Nuclear Society and Energy". The forum was sponsored by the Tyson House Episcopal & Lutheran Campus Ministry, The Institute of Nuclear Materials Management, the UT Religious Studies Association, and the Baker Center. Mark Walker and David Burman, UT graduate students in nuclear engineering and religious studies, respectively, were the able organizers and moderators of the panel. My fellow panelists were Howard Hall (Governor's Chair Professor of Nuclear Engineering), Brandon Prins (Associate Professor of Political Science), and Jeffrey Kovac (Professor of Chemistry).
The UT Beacon ran an article today summarizing the lively and sometimes provocative discussions. Dr. Hall summarized the global status quo with regard to nuclear proliferation and some practical challenges associated with nuclear disarmament. Dr. Prins summarized extant research on the role of religion in major conflicts, and Dr. Kovac presented a nice synthesis of the various factors that combine to influence one's world view. Dr. Kovac and I were the two panel members who were explicitly asked by the organizers to discuss the role our faiths play in our approach to the challenges and opportunities posed by nuclear technologies. (Dr. Kovac is a Unitarian Universalist and I am an Evangelical Christian.)
The majority of the discussion dealt with nuclear weapons, nuclear proliferation, and nuclear disarmament. Nuclear energy was discussed to a somewhat lesser extent, though I focused much of my personal attention on nuclear energy.
So here is a condensed version of my comments on the major areas I was asked to address in the panel discussion:
1. What is the Evangelical Christian framework for consideration of matters such as nuclear proliferation and nuclear energy?
A Faith or a Belief System that does not equip and enlighten one to address the most profound matters of life is not really a "Faith". It's only a hobby. An Evangelical Christian will approach the topic of nuclear weapons and nuclear energy (or any major issue for that matter) by first synthesizing the relevant Biblical context. The Biblical context is then combined with temporal facts relevant to the topic. So, what are the relevant Biblical principles? Here's my personal list:
- All humans are created in God's image, are precious to him, and have intrinsic dignity and worth based on this fact.
- We are called to be good stewards of God's creation - including of course, this planet we all inhabit.
- We live in a very imperfect world. Humankind and all creation is fallen - corrupted by sin. We have a "sinful nature" that places us in constant rebellion against God and our fellow man. This corruption distorts our reasoning, motivations, judgment, and actions toward God and our fellow man. Evil is real and exists in the hearts of men and women.
- Left to our own devices, we are helpless to restore our right standing with God and our fellow men. It is for this reason that Jesus Christ came into this world, born of a virgin, lived a perfect life, suffered and died on the Cross, and rose form the dead three days later – to pay the price for our rebellion and restore our relationship with a Holy God.
- It is by embracing the person of Jesus Christ and his finished work on the Cross that we are restored to a right relationship with God. Evangelical's speak of this as the "Gospel" or "Good News". We are called to share it with everyone. Note I said "share with". Not "force our views on" everyone.
- Evangelical Christians are called to live in obedience to Jesus's teachings and Biblical doctrine regarding accountability to God and to our fellow man. We are to share the Good News, resist evil, promote peace, and minister to our fellow man.
This is a really complicated question. The technologies being discussed by the Baker Center panel were nuclear weapons and nuclear power. One must begin by defining, precisely, the "technology" under consideration. A nuclear weapon is a particular embodiment of a suite of technologies and knowledge bases. Ditto a biological weapon – an integrated package. If one takes the view a biological weapon is intrinsically evil because it is intended for one purpose - the taking of human life - one then has to question the study of microbiology, microbe engineering, etc. – because they are some of the essential enablers of a biological weapon. In the case of nuclear weapons, it's the fission and fusion knowledge bases that are enabling. These weapons could not exist without these knowledge bases. However, the same knowledge base can be employed to end human life or save it. At what point along the pursuit of knowledge and integration of technologies does something become evil? Or is it simply the motives of the integrator or creator of a device? Or is it like the statement often made about pornography - you know it when you see it?
The history and (arguably) the success of the doctrine of Mutually Assured Destruction (MAD) is also a relevant anecdote. MAD is a cold war doctrine practice by the US and USSR. MAD basically stated that so long as each side could completely destroy each other, neither would launch an attack or provide an escalation of conventional conflict to the level that would trigger the use of nuclear weapons. I am one of many who believe the enormous stockpiles of nuclear weapons on the US and USSR sides during the cold war probably prevented a number of conventional wars that would have resulted in massive loss of life. IF this is indeed true, it challenges one's thinking about the evil of nuclear weapons. Is a nuclear weapon "evil" while it is sitting on a shelf, preventing the loss of life simply by its existence?
However, today's global situation is, in many ways, much more complex that the cold war situation. More dangers and threats from more directions than was the case in 1960. The US and Russia have made significant progress in reducing the number of warheads in our arsenals, while several other nations have joined the nuclear arms club. And then, of course, there are the "sub-national" and terrorist groups...
3. What is the Evangelical Christian view of nuclear weapons and nuclear proliferation?
Two of Christ's most relevant teachings are: (a) Luke 6:27 "But I say to you who hear, Love your enemies, do good to those who hate you..." (ESV); and (b) Luke 10:27 "You shall love the Lord your God with all your heart and with all your soul and with all your strength and with all your mind, and your neighbor as yourself." (ESV) Another relevant teaching is James 4:17 "So whoever knows the right thing to do and fails to do it, for him it is sin." (ESV) I also believe Paul's teaching in Romans Chapter 13:1-5 regarding the ordained role of governments to "bear the sword" and be an agent for good is relevant.
So, what am I to do when my "enemy" (whom I am to "love, do good to") and my "neighbor" (whom I am to "love as myself") are harming or killing each other? What am I to do when two neighbors (whom I am to love) are killing each other? What about when an "enemy" or a "neighbor" threatens to kill, inflict suffering on, or otherwise oppress the citizens of an entire country?
Love does not mean allowing someone to do whatever they wish - to themselves or to others. Love means acting in the best interests of others. If I have it within my power to prevent or stop killings, oppression, or suffering, when does Biblical doctrine require me to act? Christian theologians have wrestled with this issue for two thousand years. St. Augustine and Thomas Aquinas both offered considered views on the matter. Today, the "Just War Doctrine" traces it's origin in part to their thinking. Though too complex to discuss here, I believe, the Just War doctrine encompasses a Biblically-consistent decision framework for the use of force against our fellow man. However, it is far from perfect. I believe it is rare for a war to meet the "Just War" conditions. It is even more rare for a conflict that began as a "Just War" to continue to meet the conditions of a "Just War" as it progresses. Again, we live in an imperfect world. Sometime there are no good options.
Turning from the Biblical perspective to the more "mundane" global perspective, my view on nuclear weapons and nuclear proliferation is similar to my view about carbon in the atmosphere - more is not better. Though the "knowledge genie" is out of the bottle, it is right to work to limit the spread of weapons of mass destruction and to reduce the numbers of warheads as global conditions provide opportunities to do so.
4. What is the Evangelical Christian view of nuclear energy?
This is the easiest question of the four. As I type these words, we are days away from the birth of the 7 billionth person on this earth. One of the clear realities of our time is that the quality of life of an individual or a society is dominated by it's access to affordable and reliable energy - electricity in particular. Electricity is the key enabler of access to clean water, sanitation, conditioned living space, and food production. Currently, 25% of the human population of our planet has NO access to electricity. Another 35% or so have severely limited access. That's roughly 4 billion people whose quality of life and life expectancy is prisoner to the lack of electricity.
So how much electricity would be needed? I've run the numbers. Based on current per capita electricity consumption data, roughly 2 TW of new electrical generating capacity would be needed to raise the standard of living of those 4 billion people to that current enjoyed in the nation of South Africa (per capita electricity consumption ~ 5500 Kwh annually or an average of 630 watts continuously). Two-three times this much would be required to raise the standard of living of these 4 billion people to that enjoyed in the U.S and western Europe (~ 12,750 kwh annually or an average of 1455 watts continuously). The total global electrical generation capacity today is ~ 4.5 TW (4500 GW). This means we need to increase the net global electrical generating capacity by almost 50% in order to provide the South African standard of living to these 4 billion people, and we would have to more than double the total global generating capacity to raise their standard of living to that we enjoy in the U.S. This is a staggering challenge.
As a Christian, I feel we have a moral imperative to help our fellow man climb out of this energy supply "black hole". Beyond that, I feel strongly that the imbalance in quality of life and standard of living between those who have ready access to energy and those who do not will become one of the most disruptive global forces at play through the balance of this century. As a energy technologist, I'm convinced nuclear power is the only practical hope we have to address this enormous energy supply problem.
So there you have it... I've not related all the details of our Baker Center panel discussion, but enough to give you an idea of where I stand on these issues and why.
Cheers!
Sherrell
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