Working For Jobs

By David Roberts

Yesterday, I wrote about a new peer-reviewed paper from inventor Nathan Myhrvold and climate scientist Ken Caldeira. It found that, if there is to be any hope of staying in the zone of climate safety (or at least semi-safety), the transition to carbon-free energy must begin immediately and cannot include any merely “low carbon” sources like natural gas.

I sent Myhrvold a few follow-up questions. Here are his responses, lightly edited.

Q. Back when you were quoted in SuperFreakonomics, you seemed skeptical, if not contemptuous, toward the “immediate and precipitous anti-carbon initiatives” pushed by climate activists. But your paper seems to suggest that only such initiatives have any hope at all of keeping us in the zone of climate safety. Have you changed your mind about the need for immediate action? And/or the wisdom of activists?

A. Yes and no.

First, while I love the SuperFreakonomics book, it wasn’t my book and was never intended to fully represent my views on a complicated topic like this.

One thing we wanted to point out is how hard the problem is. There are many advocates who say that it will be easy to switch to a low-greenhouse-gas energy solution. They have a great “can do” attitude, but their schemes are hopelessly flawed. To beat one dead horse, that little book 50 Simple Things You Can Do to Save the Earth — well, it’s at best wishful thinking and at worse deeply disingenuous. Those “simple things” are not going to save us. At most they can let you foolishly think you are actually accomplishing something when you are not.

There are many more serious proposals to move to wind or solar energy — the so called “Pickens Plan,” for example, or a bunch of other people’s supposed “plans” to convert to solar or wind power — that simply don’t add up. I am contemptuous of “plans” that are not real and which at best fool people into thinking the problem is easy.

There is another set of people who have proposals that might work, but they are so draconian that no politician is going to implement them, and if they did, the population would revolt. Banning all new fossil fuel plants would surely help — try doing that. It is not realistic to think that you can get the world to change overnight. That is one reason why our paper models transitions lasting from one year (clearly an impossible lower bound) to 100 years (which is very slow).

The most galling examples are people who argue against researching geoengineering on the basis that we already know how to solve the climate problem. To them, the climate problem is a done deal, we just haven’t implemented yet. I think that is just absurd, but you see smart people make this argument.

There is a great quote attributed to Einstein: “Everything should be made as simple as possible, but not simpler.” Unfortunately, the clean-energy debate rarely avoids dipping into the “simpler” territory.

Q. More broadly, what do you see as the policy implications of your work? Is it, “We need to mobilize on the scale of WWII and build out clean power?” Or is it, “There’s no way to do this, so we need to spend money on adaptation and researching geoengineering?” Or some mix?

A. Some mix.

We need to invent new energy technologies. As one example, we can’t store energy worth a damn at the moment. Well, with pumped hydro we can store it in a dam, but only if we are lucky with geography. Without storage, wind and solar are very difficult to fully utilize.

We need higher efficiency in solar. We need new kinds of nuclear technology (I am working on this myself). We need lower cost for all of these things. It would be nice if carbon capture and sequestration would work — unclear how well it does, since it has never been tried at scale.

So there is a lot of energy invention to do.

I think we also need to investigate geoengineering. Right now, 2012 will have higher CO2 than 2011. Does anybody believe we are doing the things now so that 2013 or 2014 will be less than 2012? We are not over the hump yet, and until we are, I think that we need to understand that set of options — they may be real, they may not be, but it would be inexcusably irresponsible not to understand them.

We probably also need to investigate adaptation to a warmer world.

Q. Your finding with regard to natural gas flies directly in the face of enthusiasm (even among some greens) about fracking and the “100 year supply” of natural gas found in the U.S. Is the conclusion that natural gas can’t be a part of a clean energy solution at all? And have you heard from any of natural gas’s many fans, pushing back on your conclusion?

A. Natural gas is definitely cheap. It is definitely in big supply (100+ years). Those are true, and we don’t dispute them.

Prior to our study, nobody had looked in detail at the climate impact of converting to natural gas. People relied instead on the intuitive idea that emissions were “half of coal.” But climate change is nonlinear. It turns out that cutting by half is nowhere near enough to have an impact this century. In fact, it may take 200 years to get a measurable impact.

People are surprised by this and some people have pushed back, saying, “how can this be so?” Well, the detailed answer is all of our equations, but the simple answer is that due to the time lags in the system, you can’t get a near-term benefit until the emissions cut back is dramatic — like 10X.

The value of work like we have done is precisely that it highlights counterintuitive results. Those results may not fit with somebody’s first guess, or to the gas industry’s entrenched position. It is unfortunate that gas does not help, but that is where the science leads us.

One can try CCS with gas (our CCS cases include both coal and natural gas-based CCS), but even there you need to be careful, because the LCA estimates for CCS don’t show as much benefit as people think. Most CCS claims to eliminate 90 percent of CO2 emission from combustion, but the total LCA estimate must include leaks of natural gas during production and the reagents used in the CCS process. The net result is that CCS is far less impressive than you would think on an LCA emission basis.

One can also hypothesize better technology in the future (our paper has a whole section modeling what technological improvements could do), which is great, but it is important to realize when you are making up a fairy tale and when you are making a prediction based on current understanding. Future technology may be magical, but if it does not happen soon, it can’t matter all that much to climate change this century. It is already getting to be too late. That is the trouble with the time lags.

Right now, the best available LCA estimates on natural gas show it has at most very modest benefit over coal, so little that it should really not be viewed as being better for the climate than coal. Even a big reduction in this — as occurs for gas-based CCS — would still not make it a great solution.

I wish it were otherwise.

Q. The “carbon debt” incurred by the construction of power plants plays a big role in your paper, partially explaining why the carbon benefits of clean power take so long to manifest. Where did you get your info on carbon debt? Can you say a little about it and the role it plays?

A. There is a whole field of life-cycle analysis (LCA) wherein people study the total emissions required both to make a power plant and to operate it. This study by Sergio Pacca and Arpad Horvath is a good example and pretty readable (they are not all that way!). These studies tell you how much emissions come from each technology.

We surveyed the field and picked a high and a low LCA value for each technology we studied. That is where the basic emission data come from.

Ideally, the LCA studies would all agree. They don’t, because they have different assumptions. Solar photovoltaic cells require a lot of electricity to make. If you assume that your solar cells are built in Europe with a European mix of electricity generation, which includes French nuclear and some wind and other sources, you get one answer. If you build the identical solar cell in China, which has mostly coal-generated electricity, you get a different answer.

Now that our paper is out, it would be good for the people who make LCA studies to revisit their assumptions and try to narrow the gap between the high and low estimates that we used.

Q. Some energy analysts predict an increasingly tight oil supply and volatile/rising oil prices, which could stifle economic recovery and suppress growth. Have you thought about running scenarios where resource shortages (oil, water, etc.) play a role?

A. We wanted to isolate the climate effects alone of shifting a fixed amount of electrical power generation (1 TWe as base case). Since that is today’s coal-powered electricity load and we are currently growing that load, it would take a very severe downturn to keep demand such that coal is only 1 TW for the 40 to 60 or so years that a transition takes. So we already modeled a very conservative scenario.

More realistically, over a 40-to-60-year transition, demand will grow, so you need to convert a lot more than 1 TWe of coal.

Total per-capita energy use in China is about one-fourth to one-fifth that in the U.S. In the next 40 to 50 years, they will be a lot closer to the U.S. (and U.S. levels will also rise). That isn’t in our study — we assume fixed demand of 1 TWe.

The best thing that could happen for climate is for the price of fossil fuels to rise. Unfortunately, the development of cheap natural gas through fracking has done the opposite. There seems to be no shortage of cheap gas.

Q. Given the alarming results of your modeling, do you plan on getting more personally involved in the climate/energy area? If so, what might that look like?

A. Yes, if there is an opportunity. I am not a political guy, so I am not interested in advocacy or policy persuasion. It’s just not what I do, nor am I good at it. I can invent, and I like science. We have done a lot of invention around trying to solve clean energy problems. This paper with Ken was an effort to make a direct contribution to the science. If I see more opportunities — either in science or invention — I will definitely work on them.

Filed under: Article, Cleantech, Climate Change, Climate Policy, Coal, Natural Gas, Renewable Energy, Solar Power, Wind Power

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Strategic Energy Innovations/San Rafael, CA

Strategic Energy Innovations (SEI) is seeking a Project Coordinator to lead key K-12 education sector projects. This position requires working knowledge across the spectrum of primary and secondary education, in addition to training and grant-writing experience.

This is a full time position based out of SEI’s San Rafael office, working typical hours, Monday-Friday, with occasional field support. Applications will be reviewed and accepted on a rolling basis.

ABOUT SEI
SEI is a non-profit organization based in San Rafael, Marin County. Through funding from federal, state, municipal, private foundations and other client organizations, SEI is committed to actions that sustain our planet. We look to achieve this goal by partnering with key community groups that are integral to local climate and energy solutions, such as housing providers, schools, colleges and universities, and municipal governments. Our staff members work closely in a team-oriented environment supporting each other on projects and creatively developing new opportunities. We’re looking for a resourceful individual to join our team that enjoys supporting multiple projects simultaneously and has the ambition to grow with our organization. More details on current SEI programs and services can be found at: http://www.seiinc.org, and on Facebook at: http://www.facebook.com/StrategicEnergyInnovations.

PROJECT COORDINATOR RESPONSIBILITIES
The Project Coordinator will report to our Education Program Director, leading our efforts to plan for and implement projects within K-12 schools and related education venues. As needed, the Project Coordinator will work with and support the efforts of other SEI Program Managers/ Directors.

RESPONSIBILITIES WILL INCLUDE
Overall
➢ Assist the Education Program Director with the planning and implementation of all aspects of our K-12 Education Sector projects/programs, that includes grant/proposal writing, project scoping, budgeting, implementation, reporting and related follow up.
➢ Develop climate and energy-focused curriculum tailored to primary and secondary education.
➢ Plan for and lead instructor and classroom trainings relating to climate protection.
➢ Continue to foster and expand our K-12 sector network of partners and program implementers.
➢ Propose and present on our K-12 sector efforts at conferences, workshops and events.
➢ Plan for, travel to and facilitate meetings and provide for associated logistical support.
➢ Prepare reports, case studies and related written materials.
➢ Support the breadth of SEI programs as time and funding priorities dictate.

QUALIFICATIONS
Qualified candidates will possess the following qualities, skills, and experience:

Content Skills
➢ Bachelor’s degree (Master’s preferred) in an education, environmental or technical field.
➢ At least 5 years’ experience working in a training and K-12 education capacity.
➢ Demonstrated background and success writing grants or leading fundraising efforts.
➢ Experience developing and leading trainings/ curriculum across technical topics (e.g.: climate change; resource conservation; energy efficiency, building science, clean energy concepts, etc.)

General Skills
➢ Strong verbal, written communication, and analytical skills.
➢ Familiarity with proven group training and presentation techniques.
➢ Strong organizational skills and ability to follow through to meet multiple, concurrent deadlines.
➢ Interest and ability to take on additional and broader responsibilities over time.
➢ Competency across the Microsoft suite of office automation software (e.g.: MS Word, Excel, Power Point, etc.)
➢ Experience supervising junior staff, interns or volunteers

Personal Skills
➢ Strong interpersonal skills and an ability to build rapport with a wide range of people.
➢ Ability to work both under direct supervision and independently.
➢ Flexibility and adaptability to a rapidly changing schedule and set of priorities.

Additional Valued Skills
➢ Technical skills that include knowledge of and experience working within at least one of the following areas: building science, energy systems, energy auditing, and climate protection.
➢ Working knowledge developing websites and effectively using social media to advance project/program goals.

COMPENSATION
SEI offers a competitive salary and benefits package. Qualified applicants should submit a resume and brief cover letter describing their interest in this position and salary requirement.

APPLY TO
Email cover letter and resume to Strategic Energy Innovations at jobs338 @ seiinc.org (with no spaces in the email address). No phone calls please. Strategic Energy Innovations is an equal opportunity employer.

Apply To Job

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By David Roberts

Yesterday, I wrote about a new peer-reviewed paper from inventor Nathan Myhrvold and climate scientist Ken Caldeira. It found that, if there is to be any hope of staying in the zone of climate safety (or at least semi-safety), the transition to carbon-free energy must begin immediately and cannot include any merely “low carbon” sources like natural gas.

I sent Myhrvold a few follow-up questions. Here are his responses, lightly edited.

Q. Back when you were quoted in SuperFreakonomics, you seemed skeptical, if not contemptuous, toward the “immediate and precipitous anti-carbon initiatives” pushed by climate activists. But your paper seems to suggest that only such initiatives have any hope at all of keeping us in the zone of climate safety. Have you changed your mind about the need for immediate action? And/or the wisdom of activists?

A. Yes and no.

First, while I love the SuperFreakonomics book, it wasn’t my book and was never intended to fully represent my views on a complicated topic like this.

One thing we wanted to point out is how hard the problem is. There are many advocates who say that it will be easy to switch to a low-greenhouse-gas energy solution. They have a great “can do” attitude, but their schemes are hopelessly flawed. To beat one dead horse, that little book 50 Simple Things You Can Do to Save the Earth — well, it’s at best wishful thinking and at worse deeply disingenuous. Those “simple things” are not going to save us. At most they can let you foolishly think you are actually accomplishing something when you are not.

There are many more serious proposals to move to wind or solar energy — the so called “Pickens Plan,” for example, or a bunch of other people’s supposed “plans” to convert to solar or wind power — that simply don’t add up. I am contemptuous of “plans” that are not real and which at best fool people into thinking the problem is easy.

There is another set of people who have proposals that might work, but they are so draconian that no politician is going to implement them, and if they did, the population would revolt. Banning all new fossil fuel plants would surely help — try doing that. It is not realistic to think that you can get the world to change overnight. That is one reason why our paper models transitions lasting from one year (clearly an impossible lower bound) to 100 years (which is very slow).

The most galling examples are people who argue against researching geoengineering on the basis that we already know how to solve the climate problem. To them, the climate problem is a done deal, we just haven’t implemented yet. I think that is just absurd, but you see smart people make this argument.

There is a great quote attributed to Einstein: “Everything should be made as simple as possible, but not simpler.” Unfortunately, the clean-energy debate rarely avoids dipping into the “simpler” territory.

Q. More broadly, what do you see as the policy implications of your work? Is it, “We need to mobilize on the scale of WWII and build out clean power?” Or is it, “There’s no way to do this, so we need to spend money on adaptation and researching geoengineering?” Or some mix?

A. Some mix.

We need to invent new energy technologies. As one example, we can’t store energy worth a damn at the moment. Well, with pumped hydro we can store it in a dam, but only if we are lucky with geography. Without storage, wind and solar are very difficult to fully utilize.

We need higher efficiency in solar. We need new kinds of nuclear technology (I am working on this myself). We need lower cost for all of these things. It would be nice if carbon capture and sequestration would work — unclear how well it does, since it has never been tried at scale.

So there is a lot of energy invention to do.

I think we also need to investigate geoengineering. Right now, 2012 will have higher CO2 than 2011. Does anybody believe we are doing the things now so that 2013 or 2014 will be less than 2012? We are not over the hump yet, and until we are, I think that we need to understand that set of options — they may be real, they may not be, but it would be inexcusably irresponsible not to understand them.

We probably also need to investigate adaptation to a warmer world.

Q. The “carbon debt” incurred by the construction of power plants plays a big role in your paper, partially explaining why the carbon benefits of clean power take so long to manifest. Where did you get your info on carbon debt? Can you say a little about it and the role it plays?

A. There is a whole field of life-cycle analysis (LCA) wherein people study the total emissions required both to make a power plant and to operate it. This study by Sergio Pacca and Arpad Horvath is a good example and pretty readable (they are not all that way!). These studies tell you how much emissions come from each technology.

We surveyed the field and picked a high and a low LCA value for each technology we studied. That is where the basic emission data come from.

Ideally, the LCA studies would all agree. They don’t, because they have different assumptions. Solar photovoltaic cells require a lot of electricity to make. If you assume that your solar cells are built in Europe with a European mix of electricity generation, which includes French nuclear and some wind and other sources, you get one answer. If you build the identical solar cell in China, which has mostly coal-generated electricity, you get a different answer.

Now that our paper is out, it would be good for the people who make LCA studies to revisit their assumptions and try to narrow the gap between the high and low estimates that we used.

Q. Some energy analysts predict an increasingly tight oil supply and volatile/rising oil prices, which could stifle economic recovery and suppress growth. Have you thought about running scenarios where resource shortages (oil, water, etc.) play a role?

A. We wanted to isolate the climate effects alone of shifting a fixed amount of electrical power generation (1 TWe as base case). Since that is today’s coal-powered electricity load and we are currently growing that load, it would take a very severe downturn to keep demand such that coal is only 1 TW for the 40 to 60 or so years that a transition takes. So we already modeled a very conservative scenario.

More realistically, over a 40-to-60-year transition, demand will grow, so you need to convert a lot more than 1 TWe of coal.

Total per-capita energy use in China is about one-fourth to one-fifth that in the U.S. In the next 40 to 50 years, they will be a lot closer to the U.S. (and U.S. levels will also rise). That isn’t in our study — we assume fixed demand of 1 TWe.

The best thing that could happen for climate is for the price of fossil fuels to rise. Unfortunately, the development of cheap natural gas through fracking has done the opposite. There seems to be no shortage of cheap gas.

Q. Given the alarming results of your modeling, do you plan on getting more personally involved in the climate/energy area? If so, what might that look like?

A. Yes, if there is an opportunity. I am not a political guy, so I am not interested in advocacy or policy persuasion. It’s just not what I do, nor am I good at it. I can invent, and I like science. We have done a lot of invention around trying to solve clean energy problems. This paper with Ken was an effort to make a direct contribution to the science. If I see more opportunities — either in science or invention — I will definitely work on them.

Filed under: Article, Cleantech, Climate Change, Climate Policy, Coal, Natural Gas, Renewable Energy, Solar Power, Wind Power

View full post on Grist

By Sarah Laskow

Hey, remember yesterday, when we told you about a video that imagines a world in which climate skepticism is taught in schools? It turns out that that world is not imaginary — not at all. It exists today, and it is named … Canada.

For two years, Tom Harris, a man who according to the Heartland Institute is an “expert” on climate change, taught a course on the subject at Ottawa’s Carleton University. Harris’ course was meant for non-science majors, so, as the Guardian notes, it “may for many students be the only academic exposure they have to climate change while earning their undergraduate degree.” When a group of scientists reviewed Harris’ taped lectures they found 142 “erroneous” claims.

The group, Committee for The Advancement of Scientific Skepticism (that’d be actual scientific skepticism, not knee-jerk denial!), wrote that:

“Key messages for students contradict accepted scientific opinion. These messages include: denying that current climate change has an anthropogenic cause; dismissing the problems that carbon dioxide emissions cause because CO2 is plant food; denying the existence of the scientific consensus on the causes of climate change; and claiming that we should prepare instead for global cooling.”

Plant food. Cute.

Carleton’s not some out-of-the-way, third-tier school: it’s been ranked one of Canada’s top ten universities. And since college students — even Canadian college students! — are well known to believe that they know better than everyone else, you can be sure there’s now a coterie of Carletonians arguing late into the night that global warming just doesn’t exist. To quote the Climate Reality Project, “Of course it’s true. I learned it in school.”

Filed under: Climate Skeptics

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cKinetics/New Delhi, Delhi, India

Are you looking to get exposure in India?

cKinetics is looking for US based professionals with a passion and track record of reporting /generating content on Sustainability issues. The right candidate should be:
• Able to work in a fast paced start-up environment.
• Able and willing to take on a disproportionate level of responsibility at this stage of his/her career.

The candidate would be supporting the build out Sustainability Outlook (www.sustainabilityoutlook.in) and India Carbon Outlook (http://India.Carbon-Outlook.com) and shape state of the sector reports that are released from time to time.

Background:
cKinetics is an operational consulting and incubation firm catalyzing rapid adoption of low carbon sustainable growth practices in emerging economies through technology transfer, capital access and adaptation interventions. As emerging economies grow there exists an opportunity to leapfrog the development of newer industry and community infrastructure to be more efficient, sustainable and hence more profitable. cKinetics was founded in 2009 by a team passionate about using industry dynamics to address this most pressing issue of our time: sustainably driven growth through competitive market based models.

Role:
Selected person(s) will join cKinetics’ Access and Insights practice. This multi-disciplinary role envisages the following activities:
1. Researching ongoing happenings in sustainability domains across all verticals to ensure comprehensive coverage on areas such as green-tech, policy, etc. and articulating them in state of sector reports and weekly articles in the various publications.
2. Supporting editing activities for content getting generated for online and offline publications.
3. Providing logistical support for the print publication and for organizing round-tables and workshops.

About you:
• You have an exceptional writing and editorial skills
• You are looking to join a start-up in its early stages and share in the rewards of building an institution
• You are a proactive and independent person who has a demonstrated passion as relates to Sustainability issues: Sustainable Products, Resource Efficiency, Renewable Energy, Energy Efficiency, Policy

You must have:
• Have a Masters degree and 3 ~ 4 years of relevant work experience with a publication (online and/ or offline) or a think-tank or an industry association.
• Have Excellent English communication and strong analytical skills.
• Be web / technology savvy
• Strategic thinking abilities for business development
• Ability to work ‘hands-on’ and multi-task in an energetic start-up environment
• Demonstrated ability to be an individual contributor as also work in teams.

Location:
New Delhi, India

Compensation:
Linked to Experience. Compensation package includes a base salary with the opportunity for bonuses based on individual and company performance.

If you are interested, please write to us with a resume and also include a note on why you fit the profile.

Apply To Job

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By David Roberts

Several years ago, Nathan Myhrvold — former Microsoft exec, kajillionaire, inventor, founder of Intellectual Ventures, author of the world’s most high-tech cookbook, and all-around polymath genius type — was quoted in the book SuperFreakonomics saying dismissive things about climate activists. He was worried they might get “a real head of steam” behind their “immediate and precipitous anti-carbon initiatives.” (In retrospect, he needn’t have worried.) Instead, Myhrvold said, we should be … researching geoengineering.

He took some heat for it at the time and the experience apparently convinced him that he needs to get a better handle on things climate- and energy-related. For a guy like Myhrvold, that doesn’t just mean reading Wikipedia articles. Instead, he built a specialized set of models to capture the global temperature effects of transitions to low-carbon energy of varying speeds, using varying technologies. You know, like people do.

Flash forward a few years: Myhrvold is out with a paper on his results, co-authored with respected climate scientist Ken Caldeira, published in Environmental Research Letters.

The results are … grim.

Myhrvold and Caldeira ask the right question: What effect will deployment of clean energy have on global temperature? They take for granted that economic growth will continue as it has in the past (no small assumption, granted) and thus that 10-30 terawatts of carbon-neutral power will be needed by 2050 to meet global energy needs while limiting atmospheric CO2 concentrations to 450 ppm. (Always worth noting: 450 ppm would, according to the latest science, itself be quite dangerous.)

In their results, Myhrvold and Caldeira highlight a few poorly appreciated but crucial features of energy transitions. The first is that they take quite a while to have an appreciable effect on CO2 concentrations. The world’s oceans have considerable “thermal inertia” — it takes them a long time to absorb heat and a long time to release it. Even after CO2 concentrations start falling, it will take the oceans a while to stop releasing the excess heat they’ve already absorbed. Also, the building of a clean-energy infrastructure itself involves enormous expenditures of energy and thus CO2 emissions. For a given power source, the emissions released during its construction put it into “carbon debt” and it takes a while of generating carbon-free energy for it to work itself to the break-even point. Only then does it begin producing net reductions in CO2. Combine thermal inertia and carbon debt and you get a fairly long time lag between the energy transition and its carbon effects.

The second is that so much CO2 accumulation is already “baked in” that temperature will continue to rise for a while even in the context of rapid emission reductions. We’ve already gotten drunk on fossil fuels; there’s no way to avoid the hangover.

The consequences of this time lag are twofold. First, substantially affecting global temperature in the first half of the century is all but impossible; even to secure temperature reductions in the second half of the century, a rapid transition to clean energy needs to begin immediately. Second, lower-carbon energy — like, say, natural gas — just won’t do it. If we transitioned to something with half of coal’s emissions, it would take more than a century to produce even a 25 percent decline in CO2 relative to the status quo baseline. By then we’d be cooked.

In summary, Myhrvold and Caldeira have shown in pretty stark terms that, if we’re not willing to substantially reduce population growth or economic growth, we’re going to need an absolutely gargantuan amount of zero-carbon energy, without delay. They conclude:

Despite the lengthy time lags involved, delaying rollouts of low-carbon-emission energy technologies risks even greater environmental harm in the second half of this century and beyond. This underscores the urgency in developing realistic plans for the rapid deployment of the lowest-GHG-emission electricity generation technologies. Technologies that offer only modest reductions in emissions, such as natural gas and — if the highest estimates from the life-cycle analyses are correct — carbon capture and storage, cannot yield substantial temperature reductions this century. Achieving substantial reductions in temperatures relative to the coal-based system will take the better part of a century, and will depend on rapid and massive deployment of some mix of conservation, wind, solar, and nuclear, and possibly carbon capture and storage. [my emphasis]

In other words, the hippies are right: We’re going to need “immediate and precipitous anti-carbon initiatives.”

——

Here’s Caldeira discussing the paper:

——

For more on this theme, see:

• The gobsmackingly gargantuan challenge of shifting to clean energy
• The brutal logic of climate change
• The brutal logic of climate change mitigation

Filed under: Article, Climate Change

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GLOBAL GREEN USA.
CA – California, Los Angeles
Global Green USA seeks someone to work directly with the Chief Operating Officer (CFO) and the Office Manager in the support of the organization’s administrative support structure specializing in the…

Salary: non-disclosed. Date posted: 02/28/2012

View full post on Great Green Careers RSS Feed

By David Roberts

Several years ago, Nathan Myhrvold — former Microsoft exec, kajillionaire, inventor, founder of Intellectual Ventures, author of the world’s most high-tech cookbook, and all-around polymath genius type — was quoted in the book SuperFreakonomics saying dismissive things about climate activists. He was worried they might get “a real head of steam” behind their “immediate and precipitous anti-carbon initiatives.” (In retrospect, he needn’t have worried.) Instead, Myhrvold said, we should be … researching geoengineering.

He took some heat for it at the time and the experience apparently convinced him that he needs to get a better handle on things climate- and energy-related. For a guy like Myhrvold, that doesn’t just mean reading Wikipedia articles. Instead, he built a specialized set of models to capture the global temperature effects of transitions to low-carbon energy of varying speeds, using varying technologies. You know, like people do.

Flash forward a few years: Myhrvold is out with a paper on his results, co-authored with respected climate scientist Ken Caldeira, published in Environmental Research Letters.

The results are … grim.

Myhrvold and Caldeira ask the right question: What effect will deployment of clean energy have on global temperature? They take for granted that economic growth will continue as it has in the past (no small assumption, granted) and thus that 10-30 terawatts of carbon-neutral power will be needed by 2050 to meet global energy needs while limiting atmospheric CO2 concentrations to 450 ppm. (Always worth noting: 450 ppm would, according to the latest science, itself be quite dangerous.)

In their results, Myhrvold and Caldeira highlight a few poorly appreciated but crucial features of energy transitions. The first is that they take quite a while to have an appreciable effect on CO2 concentrations. The world’s oceans have considerable “thermal inertia” — it takes them a long time to absorb heat and a long time to release it. Even after CO2 concentrations start falling, it will take the oceans a while to stop releasing the excess heat they’ve already absorbed. Also, the building of a clean-energy infrastructure itself involves enormous expenditures of energy and thus CO2 emissions. For a given power source, the emissions released during its construction put it into “carbon debt” and it takes a while of generating carbon-free energy for it to work itself to the break-even point. Only then does it begin producing net reductions in CO2. Combine thermal inertia and carbon debt and you get a fairly long time lag between the energy transition and its carbon effects.

The second is that so much CO2 accumulation is already “baked in” that temperature will continue to rise for a while even in the context of rapid emission reductions. We’ve already gotten drunk on fossil fuels; there’s no way to avoid the hangover.

The consequences of this time lag are twofold. First, substantially affecting global temperature in the first half of the century is all but impossible; even to secure temperature reductions in the second half of the century, a rapid transition to clean energy needs to begin immediately. Second, lower-carbon energy — like, say, natural gas — just won’t do it. If we transitioned to something with half of coal’s emissions, it would take more than a century to produce even a 25 percent decline in CO2 relative to the status quo baseline. By then we’d be cooked.

In summary, Myhrvold and Caldeira have shown in pretty stark terms that, if we’re not willing to substantially reduce population growth or economic growth, we’re going to need an absolutely gargantuan amount of zero-carbon energy, without delay. They conclude:

Despite the lengthy time lags involved, delaying rollouts of low-carbon-emission energy technologies risks even greater environmental harm in the second half of this century and beyond. This underscores the urgency in developing realistic plans for the rapid deployment of the lowest-GHG-emission electricity generation technologies. Technologies that offer only modest reductions in emissions, such as natural gas and — if the highest estimates from the life-cycle analyses are correct — carbon capture and storage, cannot yield substantial temperature reductions this century. Achieving substantial reductions in temperatures relative to the coal-based system will take the better part of a century, and will depend on rapid and massive deployment of some mix of conservation, wind, solar, and nuclear, and possibly carbon capture and storage. [my emphasis]

In other words, the hippies are right: We’re going to need “immediate and precipitous anti-carbon initiatives.”

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Here’s Caldeira discussing the paper:

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For more on this theme, see:

• The gobsmackingly gargantuan challenge of shifting to clean energy
• The brutal logic of climate change
• The brutal logic of climate change mitigation

Filed under: Article, Climate Change

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Incoming search terms for the article:

• climate remidiation or geoengineering or climate engineering or geo-engineering or géo-engineering -chemtrails -or -chem trails

Starwood Hotels & Resorts Worldwide, Inc./Stamford, CT

Starwood Hotels & Resorts Worldwide, Inc., one of the leading hotel and leisure companies in the world with more than 1000 properties in over 100 countries, is a fully integrated owner, operator and franchisor of hotels and resorts with the following internationally renowned brands: St. Regis®, The Luxury Collection®, Sheraton®, Westin®, Four Points® by Sheraton, W®, Le Méridien®, Aloft® and ElementSM. Starwood Vacation Ownership, Inc., a subsidiary of Starwood Hotels & Resorts Worldwide, Inc. is one of the premier developers and operators of high quality vacation interval ownership resorts. For more information, please visit www.starwoodhotels.com or www.starwoodvacationownership.com.

Job Description
Starwood is in search of a Global Citizenship Analyst to work at the Global Corporate Headquarters in Stamford, Connecticut. The Global Citizenship Analyst will manage global tools and will be responsible for the data analysis, benchmarking and reporting for both environmental and community-based systems. This position will also identify opportunities for divisional and/or global performance improvement based on trending of global data or of a discreet project and provide project support for pilot level projects and analytical support for program rollouts.

20%- Mange GC Tools and Data Management and Internal Reporting:
Collaborate with Starwood Technology team and outside technology vendor to evolve and develop tools including EIAS, ITT and Reflex to meet the data collection, analysis and communication needs of the field and Divisional-based Global Citizenship (GC) team. Manage GC systems including the Sustainability Resource Center.

10%-Benchmarking:
Review information for GC tools to mark best practices and run reports to aggregate data. Conduct benchmarking research on various topics related to community involvement; collect relevant CSR news/press announcements. Identify opportunities for divisional and/or global performance improvement based on trending of global data or of a discreet project. Develop benchmarking system to drive company-wide performance against Starwood goals.

20%-Pilot Project Management:
Provide project support for pilot level projects and analytical support for program rollouts.

30%-Data Management and Reporting:
Manage annual and periodic environmental data gathering process. Develop roll-up divisional data reports. Spot check for accuracy of environmental data for Quality Control/ Quality Assurance. Support and communicate with Divisional GC-based team to assist with data accuracy in the division. Analyze corporate-wide data to identify trends then translate into insights for the team. Provide analytical support for external CSR reporting to include environmental and community metrics.

15%-Innovative Solutions:
Review calculations and assumptions used to estimate or measure savings due to environmental efficiency measures. Identify and analyze carbon offset options.

5%- Local Communities:
Provide analytical support to better understand footprint impact on local communities. Work with GC team to help establish and track metrics-based goals.

Requirements
• College Degree in Engineering, Sustainability, or Information Technology
• LEED Accredited Professional. Six Sigma/LEAN experience preferred.
• Strong organization skills
• Strong interpersonal skills, with the ability to present highly sensitive data in a manner that facilitates comprehension and decision-making by management and internal/external stakeholders.
• Ability to develop and maintain relationships at various levels within and outside of the organization
• Highly advanced analytical skills, with attention to detail, along with advanced written and oral communication skills including familiarity to Triple-Bottom Line cost-effectiveness analysis
• Able to handle multiple tasks accurately and sometimes under pressure. Ability to adjust to changing priorities, manage multiple tasks concurrently and work well under pressure and communicate with others.
• Strong computer skills # word processing, spreadsheets/database management, and PowerPoint are also needed.
• Three years of demonstrated experience with at least four of the following is desirable:
ï¶ Database management including report development.
ï¶ Cost & benefit analysis over a project life cycle.
ï¶ Experience with project budgeting and cost tracking.
ï¶ Assessment and estimation of energy & resource efficiency potential
ï¶ Building energy & resource use analysis, including the use of specialized benchmarking or building energy simulation software
ï¶ Understanding of statistics and energy forecasting
ï¶ Life-cycle analysis and carbon foot printing calculations.
ï¶ Building and/or development-scale energy engineering analysis; distributed or centralized.
ï¶ Sustainability/Energy assessment of existing buildings using at least one of the following frameworks: LEED-EBOM, Energy Star, Energy Performance Certificates.

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By Sarah Laskow

Step for a moment into this chilling alternative reality, in which fine young men and women believe “gravity is just a theory” and “cigarettes aren’t addictive”:

The video is from the Climate Reality Project, Al Gore’s current climate-change fighting outfit. What do y’all find the most terrifying moment? I lose it around “Scientists are, like, altering their data just to get paid.” That girl is really convincing! But the clincher is when they say, “Of course it’s true. I learned it in school.”

But, phew, it’s all fiction. For now. Unless organizations like the Heartland Institute get their way.

The Climate Reality Project has rigged up a petition to tell Heartland “keep climate denial out of our schools.” It’s probably worth signing, because if Heartland wins, your kid could come home one day and call you stupid for buying a Prius/living near public transit/sticking to the ground when you walk.

Filed under: Climate Skeptics

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