15/03/2018

IPCC Cities Conference Tackles Gaps Between Science And Climate Action On The Ground

The Conversation

The IPCC’s first cities conference revealed the challenges in bridging the gaps between scientific knowledge and policy practice, and between cities in developed and developing nations. Cities IPCC/Twitter
Some 600 climate scientists, urban researchers, policymakers and practitioners attended the International Panel on Climate Change’s (IPCC) first ever conference on cities last week. Hosted in Edmonton, Canada, it was organised as a forum to share knowledge and advice in support of the sixth IPCC Assessment Report (AR6) due in 2021.
The significance of a UN-organised global scientific conference on climate change and cities should not be underestimated. Urbanisation has been a United Nations concern since 1963. Policy attention strengthened in the 1970s when the UN Habitat agency was established. This focus was redoubled in the mid-2000s when it was reported that more than half of the global population was now urban.
Climate change has been a topic of UN action since 1988, with policy attention intensifying in the late 1990s and mid-2010s. Appreciation has since grown that with 55% of the world’s people now living in cities, this is where where efforts to mitigate and adapt to climate change must be focused.

A collision of science, practice and politics
By venturing onto urban terrain the IPCC faces some interesting scientific questions. To a large degree biological or physical systems can be studied as objective phenomena that behave according to discoverable and predictable patterns. Carbon dioxide objectively traps solar radiation leading to climatic warming; biological species die at temperatures above their tolerance.
By contrast cities are riven with historical, social, economic, cultural and political dynamics. The theoretical and conceptual frames that scientists apply to cities are subject to many biases.
We certainly can calculate the emissions a city produces and chart the likely impacts on it from a changing climate. But the reasons why a city came to emit so much and how it responds to the need to reduce emissions and adapt to impacts are highly contingent. Objective validation and verification are difficult. Identifying causality and forward pathways is very difficult.
There is also a vast divide between the physical and social science of cities and the policymakers and practitioners who shape urban development. Research shows that most urban professionals simply do not read urban science. Instead they draw on practice knowledge acquired from peer practitioners via an array of non-scientific channels and networks.
These difficulties were observable at the IPCC cities conference. It was scientific in purpose but a subtle politics was at play. Rather than being convened by a scientific body, the conference was co-ordinated as an instrument of the world’s national polities and the IPCC, organised by a mix of UN organisations and NGO networks, and sponsored by a local, provincial and national government.
Fewer than two-thirds of delegates were scientists; the remaining 40 per cent were policy officials and practitioners. The problem of connecting scientific and practice knowledge was often on display.
Many cities have accepted the clear scientific evidence on climate change and accompanying global targets. These cities are striving at the local scale to cut emissions and adapt to changing climate patterns. For many, their main need is for knowledge of practical policies and programs, rather than more evidence of climate change impacts or mitigation technologies.
Often these cities are racing far ahead of slow and certain science. They are sharing practical experience of mitigation and adaptation strategies via self-organising peer-city networks. Finding ways to link inventive but unsystematic practice knowledge with the formal peer-reviewed processes of orthodox science will be a critical task for climate change scientists and policymakers.
Policymakers are also grappling with how to implement global agreements within complex international arrangements. There face myriad tiers of national, regional, city and local governance, involving a plethora of discrete public, private and civic actors.
For this group, their priorities at the IPCC cities conference concerned policy processes and institutional design, political commitment and implementation instruments. Their needs are for policy, institutional and political science as much as for further scientific detail on climate change.

What did these encounters reveal?
The conference generated many fascinating insights. One major theme was the question of informality.
Many cities beyond the developed world are weakly governed. Multiple dimensions of urban life, including housing and infrastructure, are organised via informal institutions. Achieving effective action in these circumstances is a considerable policy problem.
A related problem is the gross geographical imbalance in scientific effort and focus on urban climate questions. Most research focuses on the cities of the developed West. And most of those are comparatively well resourced to respond to climate change.
In contrast, the cities of the developing world lack a systematic data and research base to enable effective and timely climate action. Yet these are the cities where many of the most severe climate impacts will be felt. Resolving this inequity is a fundamental international scientific challenge, as is growing the capacity to build a better evidence base.
Another question the IPCC needs to navigate is the boundary between science and politics in urban climate policy. During conference plenaries, the moderator — a former city mayor — excluded questions about specific political representatives’ stances on climate change according to apolitical IPCC rules. Yet questions about the effects on cities of neoliberalism were deemed permissible.
Urban scientists will require an especially nuanced framing of their research agenda if they are to address the very material politics of urban climate policy via theoretical abstraction alone.
The conference also provided some memorable highlights. William Rees, the originator of ecological footprint theory, lambasted delegates for not adequately appreciating the absolute material limits to resource exploitation. And the youth delegates received a standing ovation as the cohort who will be grappling with urban climate effects long after their older peers have departed.

William Rees explains the origins of the ecological footprint.

An agenda for urban climate action
The conference released a research agenda. This outlines the urgent need for inclusive and socially transformative action on climate change, improved evidence and information to support climate responses, and new funding and finance mechanisms to make this possible. It’s a very high-level guide for climate and urban scientists seeking to better understand climate change impacts on cities.
The conference appears to have met the IPCC’s needs to compile and review a large volume of scientific and practice insight for its assessment reporting. Whether it will have a wider effect on climate policy and action in cities remains unclear.
The participating scientists and practitioners certainly shared a general commitment to advancing the urban climate agenda. But it remains uncertain whether methodical scientific processes will be timely enough to meet the accelerating and expanding demands of urgent urban climate action.

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Extreme Winter Weather Becoming More Common As Arctic Warms, Study Finds

The Guardian

Scientists found a strong link between high temperatures near the pole and unusually heavy snowfall and frigid weather farther south.
Freezing weather conditions dubbed the ‘Beast from the East’ brought snow and sub-zero temperatures to the UK. Photograph: Matt Cardy/Getty Images
The sort of severe winter weather that has rattled parts of the US and UK is becoming more common as the Arctic warms, with scientists finding a strong link between high temperatures near the pole and unusually heavy snowfall and frigid weather further south.
A sharp increase in temperatures across the Arctic since the early 1990s has coincided with an uptick in abnormally cold snaps in winter, particularly in the eastern US, according to new research that analyzed temperature data from 1950 onwards.
Extreme cold winter weather is up to four times more likely when temperatures in the Arctic are unusually high, the study found. Researchers compared daily temperatures from across the Arctic region with something called the accumulated winter season severity index, which grades winter weather based on temperature, snow fall and snow depth, across 12 US cities.
“There’s a remarkably strong correlation between a warm Arctic and cold winter weather further south,” said Judah Cohen, a climatologist at Atmospheric and Environmental Research. “It’s a complex story – global warming is contributing to milder temperatures but is also having unforeseen consequences such as this.”
The Arctic has just experienced its toastiest winter on record, with parts of the region 20C (68F) warmer than the long-term average, a situation scientists have variously described as “crazy,” “weird,” and “simply shocking”. The far north latitudes are warming around twice as quickly as the global average, diminishing glaciers and sea ice and imperiling creatures such as polar bears.
Two large winter storms recently swept the US east coast in less than a week, unloading up to three inches of snow per hour in places, resulting in several deaths, thousands of cancelled flights, closed schools and snarled traffic.
The cold front even reached Florida, contributing to a recent surge in manatee deaths. So far this year, 166 of the marine mammals have been found dead off the state’s coast, with stress from the cold the leading cause of mortality. “Manatees may join polar bears as one of the first iconic victims of extinction in the wild from climate change,” said Jeff Ruch, executive director of Public Employees for Environmental Responsibility.
The US storms follow freezing winds from Siberia – dubbed the ‘beast from the east’ – that battered parts of Europe, with the British army deployed to help liberate hundreds of stranded drivers on UK motorways.
“This winter is a great example of what we can expect from climate change,” said Cohen. “In the US we had the ‘bomb cyclone’ in January, followed by July-like warm weather in February that I’d never seen before. And now we’ve had a parade of powerful winter storms and the beast from the east. It’s mind boggling.”
The research didn’t look at the reasons behind the trend of see-sawing temperatures between the Arctic and areas to the south but Cohen said it was consistent with the theory that the polar vortex – which shot to public consciousness during a 2014 cold spell – is being disrupted as the earth heats up.
The polar vortex is a low pressure system that swirls around the polar region. Sometimes it can stray further south, bringing cold Arctic air with it. There is continuing conjecture over the impact climate change is having but some scientists believe warming temperatures could be weakening the polar vortex’s flow, allowing it to meander towards the equator.
This nuanced picture of the consequences of climate change has been derided by Donald Trump, with the president using Twitter to mockingly reference cold weather during almost every winter in recent years. In December, Trump tweeted that “perhaps we could use a little bit of that good old Global Warming” amid plunging temperatures.
Scientists say this stance overlooks the complicated changes underway in the environment as the world warms due to human activity, by an average of around 1C over the past century. This temperature rise hasn’t been uniform across the globe and has fueled an array of conditions, from increased flood risk in some areas to drought conditions and heatwaves in others.
Richard Alley, a leading glacier and climate expert at Penn State who was not involved in Cohen’s research, said the study is “fascinating” and “important” but added the discrepancy between Arctic temperatures and winter weather elsewhere could have other drivers, such as a warm Gulf of Mexico feeding extra energy into storms along the US east coast.
“The broadest picture is that we are indeed warming the world’s climate, primarily from carbon dioxide release from fossil-fuel burning, and this will impact us and other living things,” said Alley.
The Arctic’s role is seen quite differently by some other scientists, however, who point out that occasional outbursts of cold weather haven’t altered the trend that winters in the US northeast have been getting warmer, particularly since the 1970s.
“There have always been cold outbreaks. The cold air has to go somewhere,” said Kevin Trenberth, senior scientist at the National Center for Atmospheric Research.
“The issue is whether the air stays put or gets loose. Some years it is contained, other years it breaks out. The question is where and what is the cause. This study reaffirms the relationship but not its cause. The Arctic likely plays a modest role in terms of feedbacks but it is unlikely it is a cause.”

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'Game Changer': New Vulnerability To Climate Change In Ocean Food Chain

Fairfax - Peter Hannam

Excessive rates of carbon dioxide affects the health of key micro-organisms in the oceans, potentially undermining the base of critical marine food chains, according to new research by US scientists.
A team of researchers from the Scripps Institution of Oceanography and the J. Craig Venter Institute (JCVI) applied techniques from the emerging field of synthetic biology to understand how ocean acidification from the absorption of CO2 is affecting tiny plants known as phytoplankton.
Phytoplankton like these diatoms turn out to be sensitive to ocean acidification, according to new research. Photo: Scripps Institution/Nature


Phytoplankton are not only a key food source for global fisheries, they are also important to the removal of CO2, much like how trees absorb the greenhouse gas from the atmosphere.
In a paper published on Thursday in Nature, the team demonstrated how the microscopic plants require carbonate ions to acquire iron from the water to grow.
As CO2 levels rise, the oceans have less carbonate, affecting phytoplankton's ability to secure sufficient nutrient iron for growth. In fact, the concentration of sea surface carbonate ions are on course to drop by half by the end of this century.
“Ultimately our study reveals the possibility of a ‘feedback mechanism’ operating in parts of the ocean where iron already constrains the growth of phytoplankton,”said Jeff McQuaid, lead author of the study who made the discoveries as a PhD student at Scripps Oceanography.
“In these regions, high concentrations of atmospheric CO2 could decrease phytoplankton growth, restricting the ability of the ocean to absorb CO2 and thus leading to ever higher concentrations of CO2 accumulating in the atmosphere.”
Phytoplankton off New York. The micro-organisms help remove carbon dioxide from the ocean. Photo: NASA
Andrew E. Allen, a biologist at Scripps and JCVI and the paper's senior author, said that while the genetics of common animals such as rats or rabbits was well known, the same was not true of marine microbes that play important roles in the global food chain.
The researchers inserted a mutated copy of a gene into phytoplankton cells and tested how it responded to changing ocean chemistry.
“It was a complete game changer,” Professor Allen told Fairfax Media, noting interest in who acidification impacts on phytoplankton had been "a pretty intensive topic of research for the past 10-20 years” given the implication for the food web. Progress, though, had been limited until the new techniques emerged.
“With [synthetic biological] tools like this we can really study the function of a protein in detail to really enable some breakthroughs.”
Professor Allen discovered several iron-responsive genes in diatoms - a type of phytoplankton - in 2008 that had no known function.
DNA analysis of samples that were collected by Mr McQuaid during a trip in the same year to Antarctica revealed one of Professor Allen’s iron genes was not only present in every sample of seawater, but that every major phytoplankton group in the Southern Ocean seemed to have a copy.
The subsequent research centred on the more common of two methods of iron take-up by diatoms.
"In the Southern Ocean, where the temperature decreases the solubility of carbonate, we should already be in the zone where the models project which start to limit iron uptake," Professor Allen said. "Certainly by 2100...the uptake of iron by this [primary] mechanism could be reduced by 45 per cent.”
While the micro organisms had a secondary way to extract the iron they needed to grow, that method was "a lot more energetically expensive and less efficient", Professor Allen said.
"If you take away one kind of iron substrate, there could be ripples through the microbial food web."
Professor Allen credited the now-Dr McQuaid for pulling together a wide-range of scientific fields - tapping experts in molecular evolution, iron and carbonate chemistry, synthetic biology and diatom biology - to "weave a coherent, integrated story”.

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