The Wendy Schmidt Ocean Health XPRIZE is a $2 million global competition that challenges teams of engineers, scientists and innovators from all over the world to create pH sensor technology that will affordably, accurately and efficiently measure ocean chemistry from its shallowest waters… to its deepest depths.
There are two prize purses available (teams may compete for, and win, both purses):
A. $1,000,000 Accuracy award – Performance focused ($750,000 First Place, $250,000 Second Place): To the teams that navigate the entire competition to produce the most accurate, stable and precise pH sensors under a variety of tests.
B. $1,000,000 Affordability award – Cost and Use focused ($750,000 First Place, $250,000 Second Place): To the teams that produce the least expensive, easy-to-use, accurate, stable, and precise pH sensors under a variety of tests.
The Need for the Prize - The Problem
Our ocean is currently in the midst of a silent crisis. Rising levels of atmospheric carbon are resulting in higher levels of acidity. The potential biological, ecological, biogeochemical and societal implications are staggering. The absorption of human CO2 emissions is already having a profound impact on ocean chemistry, impacting the health of shellfish, fisheries, coral reefs, other ecosystems and our very survival.
The Need for the Prize - The Market Failure
While ocean acidification is well documented in a few temperate ocean waters, little is known in high latitudes, coastal areas and the deep sea, and most current pH sensor technologies are too costly, imprecise, or unstable to allow for sufficient knowledge on the state of ocean acidification.
The Need for the Prize - The Solution
Breakthrough sensors are urgently needed for scientists, managers and industry to turn the tide on ocean acidification and begin healing our ocean. A competition to incentivize the creation of these sensors for the study and monitoring of ocean acidification’s impact on marine ecosystems and ocean health will drive industry forward by providing the data needed to take action and produce results.
The Need for the Prize - Impact
Making a broad impact—one that reaches far beyond new sensing technologies—is critical to the success of the prize. It begins with a breakthrough pH sensor that will catalyze our ability to measure—and thus respond to—ocean acidification.
But the breakthroughs go far beyond this impact:
* Provide tools for the study and monitoring of ocean acidification’s impacts on marine creatures and ecosystems, and thus ocean health
* Catalyze ocean acidification research
* Catalyze the development of the ocean services industry – data, information, forecasting and more for global industry
* Inspire innovations in ocean sensing technology broadly for deployment in many platforms and to effectively monitor the health of the ocean
* Create both tools and support for policymakers and public officials
* Inspire the public to engage in solving ocean acidification
To learn more about the science behind ocean acidification, visit
NOAA’s Pacific Marine Environmental Laboratory
For more information on the impacts of ocean acidification on humans and marine life, visit
the NRDC’s website
NRDC has produced a film diving into the causes and consequences of ocean acidification:
http://www.nrdc.org/oceans/acidification/aboutthefilm.asp
For more on what you can do to help, visit the Deeper Dive at Ocean Conservancy:
http://www.oceanconservancy.org/our-work/ocean-acidification/deeper-dive.html
Counter Acting Ocean Acidication
Ten Ways States Can Combat Ocean Acidification (and Why they should) by Ryan P. Kelly* and Margaret R. Caldwell [48 page paper by Stanford researchers]
The ocean is becoming more acidic worldwide as a result of increasing atmospheric concentrations of carbon dioxide (“CO2”) and other pollutants. This fundamental change is likely to have substantial ecological and economic consequences globally. In this Article, we provide a toolbox for understanding and addressing the drivers of ocean acidification. We begin with an overview of the relevant science, highlighting known causes of chemical change in the coastal ocean. Because of the difficulties associated with controlling diffuse atmospheric pollutants such as CO2, we then focus on controlling smaller-scale agents of acidification, discussing ten legal and policy tools that state government agencies can use to mitigate the problem. This bottom-up approach does not solve the global CO2 problem, but instead offers a more immediate means of addressing the challenges of a rapidly changing ocean. States have ample legal authority to address many of the causes of ocean acidification; what remains is to implement that authority to safeguard our iconic coastal resources.
Mitigating Acidification
Ocean Acidification: Cause, Effect, and Potential Mitigation Approaches by Joanna M. Norton
The accumulation of carbon dioxide in Earth’s atmosphere is mirrored by an increase in dissolved carbonic acid in the oceans. Carbon dioxide dissolves easily into liquid, so the surface layers of the ocean are always in equilibrium with atmospheric pressures of the gas and provide a massive sink. Some of the dissolved carbon dioxide remains as carbonic acid, some breaks down further to form carbonate ion, but most is present in the form of bicarbonate (HCO3-); these are the components of the ocean’s buffering system to guard against pH changes. However, the buffer can be overwhelmed by continued inputs of carbon dioxide and lose its buffering capacity.
1) Sequestering carbon on the ocean floor by fertilizing certain ocean regions with iron, which can be a limiting nutrient in these areas
2) Addition of powdered limestone to ocean water to react with carbon dioxide and form bicarbonate has also been proposed (Rau and Caldiera 1999; Harvey 2007). This would neutralize the acidity of the added carbon dioxide, as well as push the oceanic carbon equation towards carbonic acid and allow for more calcium carbonate to stay undissolved in the shells of marine life. The ocean has a large, untapped ability to hold dissolved bicarbonate, if enough calcium carbonate (limestone) is made available for the reaction (Rau et al 2006). This process would essentially increase the buffering capacity of the ocean, by adding carbonate ion to offset the carbon dioxide absorbed by the ocean. Rau et al (2006) calculate that the ocean could hold enough bicarbonate that all the carbon in existing fossil fuel stores could be sequestered. In fact, this is how past rises in atmospheric carbon were eventually modulated, gradually, over millennia. They suggest accelerated weathering of limestone at locations of CO2 production. Harvey (2007) investigates adding powdered limestone to areas that would carry it in upwelling current. This method could be especially cheap and effective, and no negative side effects have been found, but these issues have not been thoroughly examined.
If you liked this article, please give it a quick review on ycombinator or StumbleUpon. Thanks
There are two prize purses available (teams may compete for, and win, both purses):
A. $1,000,000 Accuracy award – Performance focused ($750,000 First Place, $250,000 Second Place): To the teams that navigate the entire competition to produce the most accurate, stable and precise pH sensors under a variety of tests.
B. $1,000,000 Affordability award – Cost and Use focused ($750,000 First Place, $250,000 Second Place): To the teams that produce the least expensive, easy-to-use, accurate, stable, and precise pH sensors under a variety of tests.
The Need for the Prize - The Problem
Our ocean is currently in the midst of a silent crisis. Rising levels of atmospheric carbon are resulting in higher levels of acidity. The potential biological, ecological, biogeochemical and societal implications are staggering. The absorption of human CO2 emissions is already having a profound impact on ocean chemistry, impacting the health of shellfish, fisheries, coral reefs, other ecosystems and our very survival.
The Need for the Prize - The Market Failure
While ocean acidification is well documented in a few temperate ocean waters, little is known in high latitudes, coastal areas and the deep sea, and most current pH sensor technologies are too costly, imprecise, or unstable to allow for sufficient knowledge on the state of ocean acidification.
The Need for the Prize - The Solution
Breakthrough sensors are urgently needed for scientists, managers and industry to turn the tide on ocean acidification and begin healing our ocean. A competition to incentivize the creation of these sensors for the study and monitoring of ocean acidification’s impact on marine ecosystems and ocean health will drive industry forward by providing the data needed to take action and produce results.
The Need for the Prize - Impact
Making a broad impact—one that reaches far beyond new sensing technologies—is critical to the success of the prize. It begins with a breakthrough pH sensor that will catalyze our ability to measure—and thus respond to—ocean acidification.
But the breakthroughs go far beyond this impact:
* Provide tools for the study and monitoring of ocean acidification’s impacts on marine creatures and ecosystems, and thus ocean health
* Catalyze ocean acidification research
* Catalyze the development of the ocean services industry – data, information, forecasting and more for global industry
* Inspire innovations in ocean sensing technology broadly for deployment in many platforms and to effectively monitor the health of the ocean
* Create both tools and support for policymakers and public officials
* Inspire the public to engage in solving ocean acidification
To learn more about the science behind ocean acidification, visit
NOAA’s Pacific Marine Environmental Laboratory
For more information on the impacts of ocean acidification on humans and marine life, visit
the NRDC’s website
NRDC has produced a film diving into the causes and consequences of ocean acidification:
http://www.nrdc.org/oceans/acidification/aboutthefilm.asp
For more on what you can do to help, visit the Deeper Dive at Ocean Conservancy:
http://www.oceanconservancy.org/our-work/ocean-acidification/deeper-dive.html
Counter Acting Ocean Acidication
Ten Ways States Can Combat Ocean Acidification (and Why they should) by Ryan P. Kelly* and Margaret R. Caldwell [48 page paper by Stanford researchers]
The ocean is becoming more acidic worldwide as a result of increasing atmospheric concentrations of carbon dioxide (“CO2”) and other pollutants. This fundamental change is likely to have substantial ecological and economic consequences globally. In this Article, we provide a toolbox for understanding and addressing the drivers of ocean acidification. We begin with an overview of the relevant science, highlighting known causes of chemical change in the coastal ocean. Because of the difficulties associated with controlling diffuse atmospheric pollutants such as CO2, we then focus on controlling smaller-scale agents of acidification, discussing ten legal and policy tools that state government agencies can use to mitigate the problem. This bottom-up approach does not solve the global CO2 problem, but instead offers a more immediate means of addressing the challenges of a rapidly changing ocean. States have ample legal authority to address many of the causes of ocean acidification; what remains is to implement that authority to safeguard our iconic coastal resources.
Mitigating Acidification
Ocean Acidification: Cause, Effect, and Potential Mitigation Approaches by Joanna M. Norton
The accumulation of carbon dioxide in Earth’s atmosphere is mirrored by an increase in dissolved carbonic acid in the oceans. Carbon dioxide dissolves easily into liquid, so the surface layers of the ocean are always in equilibrium with atmospheric pressures of the gas and provide a massive sink. Some of the dissolved carbon dioxide remains as carbonic acid, some breaks down further to form carbonate ion, but most is present in the form of bicarbonate (HCO3-); these are the components of the ocean’s buffering system to guard against pH changes. However, the buffer can be overwhelmed by continued inputs of carbon dioxide and lose its buffering capacity.
1) Sequestering carbon on the ocean floor by fertilizing certain ocean regions with iron, which can be a limiting nutrient in these areas
2) Addition of powdered limestone to ocean water to react with carbon dioxide and form bicarbonate has also been proposed (Rau and Caldiera 1999; Harvey 2007). This would neutralize the acidity of the added carbon dioxide, as well as push the oceanic carbon equation towards carbonic acid and allow for more calcium carbonate to stay undissolved in the shells of marine life. The ocean has a large, untapped ability to hold dissolved bicarbonate, if enough calcium carbonate (limestone) is made available for the reaction (Rau et al 2006). This process would essentially increase the buffering capacity of the ocean, by adding carbonate ion to offset the carbon dioxide absorbed by the ocean. Rau et al (2006) calculate that the ocean could hold enough bicarbonate that all the carbon in existing fossil fuel stores could be sequestered. In fact, this is how past rises in atmospheric carbon were eventually modulated, gradually, over millennia. They suggest accelerated weathering of limestone at locations of CO2 production. Harvey (2007) investigates adding powdered limestone to areas that would carry it in upwelling current. This method could be especially cheap and effective, and no negative side effects have been found, but these issues have not been thoroughly examined.
If you liked this article, please give it a quick review on ycombinator or StumbleUpon. Thanks
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