Saturday, July 7, 2018

Numerous Benefits of 100% Clean, Renewable Energy

An excellent new paper by Mark Jacobson et al. describes 100% clean and renewable Wind, Water, and Sunlight (WWS) all-sector energy roadmaps for 53 towns and cities in North America.

In the video below, Mark Jacobson discusses the 'Path to a 100% Renewable World'.


Clean and renewable energy is not only cheaper, it also avoids health and climate damage many times greater than those savings.

Additionally, clean and renewable energy provides more long-term full-time jobs, provides more robust and stable energy and provides greater energy safety and security, all with less need for land and water.

Furthermore, clean and renewable energy avoids costs of insurance against nuclear accidents, avoids conflicts over fossil fuel resources, avoids pollution of oceans, soil and groundwater and avoids infrastructure for transport of drilling & mining equipment and fuel.

Reductions in mining, drilling and fracking can also avoid falls in land values, with benefits for land owners and for councils in terms of greater rates revenues.


As described in the earlier post 100% clean, renewable energy is cheaper, the price of fuel looks set to go up over time due to decreasing economies of scale for fuel, while the price of clean, renewable energy looks set to keep coming down, in line with ongoing innovation, efficiency improvements and economies of scale. Examples are induction cookingbatteries, heat pumpsLED lights, refrigeration and smelters.

The transition to clean & renewable energy will avoid a lot of energy, time and money spent on planning, constructing and maintaining the ports, railways, pipelines and supply of water for cooling that is needed to keep conventional power plants going. The savings in efficiency are huge, as illustrated by the image below, the total demand reduction is 57.9% of what the demand would be if business were to continue as usual (BAU).


Debt

Many of the costs associated with fossil fuel are currently not incorporated in its price. Continued emissions would drive the world further in debt, due to rising costs of health care, removal of carbon dioxide, etc.

There is also the price of conflict. As an example, fossil fuel adds to the cost of conflict over resources and securing of fuel transport. A 2017 report puts the cost of U.S. military intervention in Syria, Iraq, Afghanistan, and Pakistan over the period FY2001-FY2018 at $5.6 trillion, or $23,386 for the average taxpayer. The report adds that, unlike past US wars, these wars have been paid for largely through borrowing. The $5.6 trillion includes the interest the US has already paid on this debt, but it does not include projected future interest. Even if the US stopped spending money on these wars right now, cumulated interest costs on borrowing will ultimately add more than $7.9 trillion to the national debt over the next several decades.

Climate Plan

Sam Carana's Climate Plan suggests that local feebates can most effectively and rapidly achieve the necessary transition to clean & renewable energy. As an example, fees can be imposed on sales of fuel, with the revenues used to fund rebates on local supply of clean & renewable energy. Another example is to impose fees on registration of vehicles with internal combustion engines, with the revenues used to fund rebates on registration of battery-electric or hydrogen-powered vehicles. Local feebates can best help areas each get their preferred mix (of local supply/storage, of grid interconnection and imports/exports of electricity, and of demand response).

The Climate Plan calls for dramatic cuts in emissions through such policies, while also calling for further lines of action. For more on the benefits of feebates, see the feebates and policies pages.


Links

• Climate Plan
https://arctic-news.blogspot.com/p/climateplan.html

• 100% clean and renewable Wind, Water, and Sunlight (WWS) all-sector energy roadmaps for 53 towns and cities in North America, by Mark Jacobson et al.
https://web.stanford.edu/group/efmh/jacobson/Articles/I/TownsCities.pdf

• 100% Clean and Renewable Wind, Water, and Sunlight All-Sector Energy Roadmaps for 139 Countries of the World, by Mark Jacobson et al.
http://web.stanford.edu/group/efmh/jacobson/Articles/I/CountriesWWS.pdf

• Matching demand with supply at low cost in 139 countries among 20 world regions with 100% intermittent wind, water, and sunlight (WWS) for all purposes, by Mark Jacobson et al.
http://web.stanford.edu/group/efmh/jacobson/Articles/I/CombiningRenew/WorldGridIntegration.pdf



Sunday, July 1, 2018

Can we weather the Danger Zone?

[ click on image to enlarge ]
As an earlier Arctic-news analysis shows, Earth may have long crossed the 1.5°C guardrail set at the Paris Agreement.

Earth may have already been in the Danger Zone since early 2014. This is shown by the image on the right associated with the analysis, which is based on NASA data that are adjusted to reflect a preindustrial baseline, air temperatures and Arctic temperatures.

As the added 3rd-order polynomial trend shows, the world may also be crossing the higher 2°C guardrail later this year, while temperatures threaten to keep rising dramatically beyond that point.

What is the threat?

As described at the Threat, much carbon is stored in large and vulnerable pools that have until now been kept stable by low temperatures. The threat is that rapid temperature rise will hit vulnerable carbon pools hard, making them release huge amounts of greenhouse gases, further contributing to the acceleration of the temperature rise.


Further release of greenhouse gases will obviously further speed up warming. In addition, there are further warming elements that could result in very rapid acceleration of the temperature rise, as discussed at the Extinction page.

The Danger Zone

Below are some images illustrating just how dire the situation is, illustrating how vulnerable carbon pools are getting hit exactly as feared they would be with a further rise in temperature.

On July 5, 2018, it was as hot as 33.5°C or 92.3°F on the coast of the Arctic Ocean in Siberia (at top green circle, at 72.50°N). Further inland, it was as hot as 34.2°C or 93.5°F (at bottom green circle, at 68.6°N).


The satellite image below shows smoke from fires over parts of Siberia hit strongly by heat waves.


The fires caused carbon monoxide levels as high as 20,309 ppb over Siberia on July 3, 2018.


Methane levels that day were as high as 2,809 ppb.


On July 4, 2018, forest fires near the Lena River cause smoke over the Laptev Sea and East Siberian Sea. CO (see inset) and CO₂ levels that day were as high as 45080 ppb and 724 ppm (at the green circle), as illustrated by the image below.


The Copernicus image below shows aerosol forecasts for July 4, 2018, 21:00 UTC, due to biomass burning.


Another Copernicus forecast shows high ozone levels over Siberia and the East Siberian Sea.


EPA 8-hour ozone standard is 70 ppb and here's a report on recent U.S. ozone levels. See Wikipedia for more on the strong local and immediate warming impact of ozone and how it also makes vegetation more vulnerable to fires.

The global 10-day forecast (GFS) below, run on July 3, 2018, with maximum 2 meter temperature, shows that things may get even worse over the coming week or more.


Could we move out of the Danger Zone?

What can be done to improve this dire situation?

One obvious line of action is to make more effort to reduce emissions that are causing warming. There's no doubt that this can be achieved and has numerous benefits, as described in an earlier post. Emission cuts can be achieved by implementing effective policies to facilitate changes in energy use, in diet and in land use and construction practices, etc.

One complication is that the necessary transition away from fossil fuel is unlikely to result in immediate falls in temperatures. This is the case because there will be less sulfur in the atmosphere to reflect sunlight back into space. Furthermore, there could also be an increase in biomass burning, as discussed at the Aerosols page, while the full wrath of recent carbon dioxide emissions is yet to come. As said, the resulting rise in temperature threatens to trigger numerous feedbacks that could accelerate the temperature rise even further. For more on how much temperatures could rise, see the Extinction page.

While it's clear that - besides emission cuts - further action is necessary, such as removing greenhouse gases from the atmosphere and oceans, the prospect is that such removal will have to continue for decades and decades to come before it can bring greenhouse gases down to safer levels. To further combat warming, there are additional lines of action to be looked at, but as long as politicians remain reluctant to even consider pursuing efforts to reduce emissions, we can expect that the world will be in the Danger Zone for a long time to come.

The situation is dire and calls for comprehensive and effective action, as described in the Climate Plan.



Links

• How much warmer is it now?
https://arctic-news.blogspot.com/2018/04/how-much-warmer-is-it-now.html

• 100% clean, renewable energy is cheaper
https://arctic-news.blogspot.com/2018/02/100-clean-renewable-energy-is-cheaper.html

• Feedbacks
https://arctic-news.blogspot.com/p/feedbacks.html

• How much warming have humans caused?
https://arctic-news.blogspot.com/2016/05/how-much-warming-have-humans-caused.html

• IPCC seeks to downplay global warming
https://arctic-news.blogspot.com/2018/02/ipcc-seeks-to-downplay-global-warming.html

• The Threat
https://arctic-news.blogspot.com/p/threat.html

• Extinction
https://arctic-news.blogspot.com/p/extinction.html

• Aerosols
https://arctic-news.blogspot.com/p/aerosols.html

• How extreme will it get?
https://arctic-news.blogspot.com/2012/07/how-extreme-will-it-get.html

• Climate Plan
https://arctic-news.blogspot.com/p/climateplan.html


Wednesday, June 27, 2018

'Electrogeochemistry' captures carbon, produces fuel, offsets ocean acidification

Researchers analyze global potential for 'negative emissions energy' using electricity from renewable sources to generate hydrogen fuel and capture carbon dioxide.

Greg Rau with a monument in the background marking
the Arctic circle along the unfrozen coast of Norway 
Limiting global warming to 2 degrees Celsius will require not only reducing emissions of carbon dioxide, but also active removal of carbon dioxide from the atmosphere. This conclusion from the Intergovernmental Panel on Climate Change has prompted heightened interest in "negative emissions technologies."

A new study published June 25 in Nature Climate Change evaluates the potential for recently described methods that capture carbon dioxide from the atmosphere through an "electrogeochemical" process that also generates hydrogen gas for use as fuel and creates by-products that can help counteract ocean acidification.

First author Greg Rau, a researcher in the Institute of Marine Sciences at UC Santa Cruz and visiting scientist at Lawrence Livermore National Laboratory, said this technology significantly expands the options for negative emissions energy production.

The process uses electricity from a renewable energy source for electrolysis of saline water to generate hydrogen and oxygen, coupled with reactions involving globally abundant minerals to produce a solution that strongly absorbs and retains carbon dioxide from the atmosphere. Rau and other researchers have developed several related methods, all of which involve electrochemistry, saline water, and carbonate or silicate minerals.

"It not only reduces atmospheric carbon dioxide, it also adds alkalinity to the ocean, so it's a two-pronged benefit," Rau said. "The process simply converts carbon dioxide into a dissolved mineral bicarbonate, which is already abundant in the ocean and helps counter acidification."

The negative emissions approach that has received the most attention so far is known as "biomass energy plus carbon capture and storage" (BECCS). This involves growing trees or other bioenergy crops (which absorb carbon dioxide as they grow), burning the biomass as fuel for power plants, capturing the emissions, and burying the concentrated carbon dioxide underground.

"BECCS is expensive and energetically costly. We think this electrochemical process of hydrogen generation provides a more efficient and higher capacity way of generating energy with negative emissions," Rau said.

He and his coauthors estimated that electrogeochemical methods could, on average, increase energy generation and carbon removal by more than 50 times relative to BECCS, at equivalent or lower cost. He acknowledged that BECCS is farther along in terms of implementation, with some biomass energy plants already in operation. Also, BECCS produces electricity rather than less widely used hydrogen.

"The issues are how to supply enough biomass and the cost and risk associated with putting concentrated carbon dioxide in the ground and hoping it stays there," Rau said.

The electrogeochemical methods have been demonstrated in the laboratory, but more research is needed to scale them up. The technology would probably be limited to sites on the coast or offshore with access to saltwater, abundant renewable energy, and minerals. Coauthor Heather Willauer at the U.S. Naval Research Laboratory leads the most advanced project of this type, an electrolytic-cation exchange module designed to produce hydrogen and remove carbon dioxide through electrolysis of seawater. Instead of then combining the carbon dioxide and hydrogen to make hydrocarbon fuels (the Navy's primary interest), the process could be modified to transform and store the carbon dioxide as ocean bicarbonate, thus achieving negative emissions.

"It's early days in negative emissions technology, and we need to keep an open mind about what options might emerge," Rau said. "We also need policies that will foster the emergence of these technologies."

In addition to Rau and Willauer, coauthor Zhiyong Jason Ren at the University of Colorado in Boulder (now at Princeton University) also contributed to the paper. This work was supported by Lawrence Livermore National Laboratory, Office of Naval Research, and National Science Foundation.


Links

• 'Electrogeochemistry' captures carbon, produces fuel, offsets ocean acidification, News release by Tim Stephens at UC Santa Cruz
https://news.ucsc.edu/2018/06/electrogeochemistry.html

• The global potential for converting renewable electricity to negative-CO2-emissions hydrogen, by Greg H. Rau, Heather D. Willauer, Zhiyong Jason Ren.
https://www.nature.com/articles/s41558-018-0203-0

• Olivine weathering to capture CO2 and counter climate change
https://arctic-news.blogspot.com/2016/07/olivine-weathering-to-capture-co2-and-counter-climate-change.html

• Climate Plan
https://arctic-news.blogspot.com/p/climateplan.html



See comments at the facebook geoengineering group

Wednesday, June 13, 2018

High Temperatures Over Arctic Ocean In June 2018

It was 6.6°C or 44°F (at 850 hPa) over the North Pole due to hot air flowing from Siberia over the Arctic Ocean on June 13, 2018, 15:00 UTC (left panel). Earlier, temperatures as high as 7°C or 44.5°F were forecast. At the same time, the Jet stream (250 hPa) crosses the Arctic Ocean and goes circular over North Canada and Baffin Bay (right panel).


As the combination image below shows, it was as hot as 32.7°C or 90.9°F (left panel, at the green circle) on June 11, 2018, on the coast of Hudson Bay. The right panel shows the jet stream crossing the Arctic, while numerous cyclones are visible on both images.


The combination image below shows that it was as hot as 30.7°C or 87.3°F (at the green circle, left panel) on the coast of the Laptev Sea, on June 10, 2018. The right panel shows the jet stream crossing the Arctic at speeds as fast as 161 km/h or 100 mph (at the green circle).


Three ways in which heat enters the Arctic Ocean are:

1. Heat is reaching the Arctic Ocean directly, i.e. air is warming up the water of the Arctic Ocean or is melting the sea ice from above.

2. Rivers that end in the Arctic Ocean can carry huge amounts of heat.

3. Heat is also entering the Arctic Ocean from the Atlantic Ocean and the Pacific Ocean.

Feedbacks, such as changes to the jet stream, can further speed up warming of the Arctic Ocean.

As the Arctic warms up faster than the rest of the world, the temperature difference between the Arctic and the Equator decreases, making the Jet Stream wavier, with longer loops that allow more warm air to enter the Arctic and at the same time allow more cold air to flow out of the Arctic (feedback #10 on the feedbacks page).

The top image on the right shows that the sea surface in the Atlantic Ocean off the coast of North America on May 29, 2018, was as much as 9.8°C or 17.6°F warmer than 1981-2011 (at the green circle).

As temperatures keep rising, increasingly stronger winds over oceans are also causing more heat to enter the Arctic Ocean from the North Atlantic, and from the Pacific Ocean.

On June 4, 2018, the sea surface in the Pacific Ocean near Bering Strait was as much as 7.2°C or 12.9°F warmer than 1981-2011 (at the green circle), as the next image on the right shows.

The next image on the right shows that water near Svalbard was as warm as 16.1°C or 61°F on June 4, 2018, versus 3°C or 37.4°F in 1981-2011 (at the green circle).

On June 4, 2018, sea surface temperature near Svalbard was as warm as indicated by the color yellow on the image on the right, i.e. 16-18°C or 60.8-64.4°F. For more background on the warm water near Svalbard, also see the earlier post Accelerating Warming of the Arctic Ocean.

This heat will warm up the water underneath the sea ice, thus melting the sea ice from below.

Furthermore, as the sea ice retreats, more sunlight will be absorbed by the Arctic Ocean, instead of being reflected back into space, thus further speeding up sea ice decline.


Oceans take up over 90% of global warming, as illustrated by above image. Ocean currents make that huge amounts of this heat are entering the Arctic Ocean from the Pacific Ocean and the Atlantic Ocean.

The right-hand panel of the image below shows the extent of the permafrost on the Northern Hemisphere. The subsea permafrost north of Siberia is prone to melting due to the increasingly higher temperatures of the water. Increasingly high air temperatures are melting the sea ice and, where the sea ice is gone, they are warming up the water directly.


High air temperatures are also warming up the water from rivers flowing into the Arctic Ocean, as illustrated by the left panel of above image.

On June 15, 2018, it was as warm as 31.5°C or 88.6°F at 06:00 UTC and 31.7°C or 89.1°F at 09:00 UTC over the Kotuy/Khatanga River that ends in the Laptev Sea in the Arctic Ocean (green circle).

On June 20, 2018, it was even warmer, as the image on the right shows. It was as warm as 32.3°C or 90.1°F at 1000 hPa over the Yenisei River that ends in the Kara Sea in the Arctic Ocean (green circle). It was actually even warmer at surface level, but just look at the temperatures on the image over Greenland and the Tibetan Plateau at 1000 hPa. See also this post.

As the water of the Arctic Ocean keeps warming, the danger increases that methane hydrates at the bottom of the Arctic Ocean will destabilize.

Methane releases from the seafloor of the Arctic Ocean can dramatically warm up the atmosphere, especially at higher latitudes. Ominously, very high methane peaks are increasingly appearing, as high as:
- 2899 ppb on May 04, 2018, a.m.
- 2498 ppb on May 16, 2018, p.m.
- 2820 ppb on May 21, 2018, a.m.
- 2616 ppb on May 22, 2018, p.m.
- 3006 ppb on May 27, 2018, p.m.
- 2878 ppb on June 05, 2018, p.m.
- 2605 ppb on June 07, 2018, a.m.

Mean global methane level was as high as 1880 ppb on June 15, 2018, at 254 mb, further confirming that more methane is increasingly accumulating at greater heights in the atmosphere.

NOAA records show that the average May 2018 CO₂ level was 411.25 ppm at Mauna Loa, Hawaii, while the hourly average peaked at well above 416 ppm.

"CO₂ levels are continuing to grow at an all-time record rate because burning of coal, oil, and natural gas have also been at record high levels,” said Pieter Tans, lead scientist of NOAA's Global Greenhouse Gas Reference Network in a news release. "Today's emissions will still be trapping heat in the atmosphere thousands of years from now."

Greenhouse gas levels are particularly high over the Arctic Ocean. CO₂ levels were 420 ppm over the North Pole on June 12, 2018.

The situation is getting even more critical as we've left the La Niña period behind and are now moving into an El Niño period, as illustrated by the images on the right and below.

A further danger is that earthquakes can be triggered as more ice is melting on Greenland, as discussed earlier in posts such as this one and this one. Earthquakes can send out strong tremors through the sediment and shock waves through the water, which can trigger further earthquakes, landslides and destabilization of methane hydrates. The situation is especially dangerous when combined with extreme weather events that can cause cracks and movement in sediments. The image below shows earthquakes that hit the seas around Greenland between May 30, 2018, and June 17, 2018.


Given the above, it's amazing that the IPCC in its 'final draft 1.5°C report' insists that "If emissions continue at their present rate, human-induced warming will exceed 1.5°C by around 2040" (according to a recent Reuters report). The final draft is now going to governments for their scrutiny, with the danger that the dire situation may be watered down even further.

Governments should be urged to confirm that temperatures could rise dramatically over the next few years. Accordingly, comprehensive and effective action needs to be taken, as described at the Climate Plan page.


Links

• Climate Plan
http://arctic-news.blogspot.com/p/climateplan.html

• Feedbacks
http://arctic-news.blogspot.com/p/feedbacks.html

• Accelerating Warming of the Arctic Ocean
https://arctic-news.blogspot.com/2016/12/accelerating-warming-of-the-arctic-ocean.html