Showing posts with label applied ecology. Show all posts
Showing posts with label applied ecology. Show all posts

Thursday, July 6, 2017

Solutions to managing invasive species by combining research with local knowledge


--> *This was originally published at the Applied Ecologist's Blog

While many hurdles hamper the successful application of ecological concepts and theories to developing solutions to environmental problems, one area of ecological concern that has been especially consequential and complicated to solve has been the control of invasive species. The non-native species that end up spreading in new regions with massive impacts on local ecosystems are difficult to predict beforehand, and eradicating invasive species is a nearly impossible task. Despite hundreds of millions of dollars spent on invasive species control, there are few success stories. Realistically, the best-case scenario is finding efficient management strategies that reduce the abundance and impact of invasive species to acceptable or tolerable levels.
Image: African lovegrass (www.southeastweeds.org.au)

Part of the problem is that researchers and research organisations, which are needed to develop management strategies, are usually stretched thin and unable to devote the time and resources needed to develop evidence-based solutions. A research project into the control of invasive species requires baseline data, an understanding of basic species ecology, and a list of candidate control measures. These starting points are not trivial to satisfy and often require years of basic research before we can assess possible control measures. One of the reasons often given for this limited success is that ecological systems are inherently idiosyncratic or unpredictable. However, this lack of predictability is virtually inseparable from a lack of system specific knowledge. This lack of fundamental understanding means that we may be asking the wrong questions or pursuing inefficient management solutions based on our assumptions about an ecosystem’s behaviour.

In many systems, there exists an underutilised resource -the experience of local landowners, farmers, and ranchers. A recent paper in the Journal of Applied Ecology titled Integrating local knowledge and research to refine the management of an invasive non-native grass in critically endangered grassy woodlands by Jennifer Firn, Emma Ladouceur, and Josh Dorrough represents a new approach to incorporating local knowledge for testing invasive species management options. This paper, to my mind, constitutes one of the best and most innovative attempts to integrate detailed local non-scientist knowledge with modern research methods.

The study by Firn and colleagues takes an original approach to addressing research and invasive species control shortcomings by working with Australian landowners who have intimate knowledge of the grasslands they work in and, more importantly, how they have changed over time. Firn’s research team interviewed these landowners and developed specific hypotheses based on landowner knowledge about African lovegrass (Eragrostis curvula) growth and spread in Australia, an invasive plant introduced from southern Africa. Firn and colleagues then scientifically tested these hypotheses, showing support for some landowner perspectives, and disproving others.
This research is crucial because it shows how research and management can be made more efficient by working with local landowners. It breaks down the walls that separate academic and professional applied management from local citizens and landowners who do not work in intellectual vacuums, but rather observe, contemplate and develop questions. The scientists provide the means for landowners to test their questions.

I firmly believe that this work will change the perspective of how researchers and scientific and environmental organisations carry out their research. It shows how powerful partnerships can be, and that knowledge and expertise sharing can maximise understanding and management solutions.
Ultimately, this work will not only directly benefit Australia’s environment by providing management options for controlling African lovegrass but will also provide a template for developing solutions to any environmental problem. It is evident that researchers working on other exotic species can emulate Firn and colleague’s work, but perhaps less clear, and what should repeatedly be broadcast, is that this method should be employed for managing other environmental changes including the effects of climate change and altered land use.

Tuesday, December 13, 2016

150 years of 'ecology'

The word ‘ecology’ was coined 150 years ago by Ernst Haeckel in his book Generelle Morphologie der Organismen published in 1866. Mike Begon gave a fascinating talk at the British Ecological Society meeting in Liverpool on what ecology as meant over these past 150 years and what it should mean in the future. The description of ecology that follows, is largely taken from Begon’s remarks.

Ernst Haeckel, 1860
Haeckel defined ecology as ‘the science of the relations of organism to its surrounding outside world (environment)’, which is in obvious contrast to the then burgeoning science of physiology, which was concerned with the world inside of an organism. Interestingly, the first 50 years of this new field of ecology was dominated by the study of plants. In America, Clements, while in the UK, Tansley, both saw ecology as the description of patterns of plant in relation to the outside world. In many ways, this conception of ecology was what Haeckel had envisioned.

Frederic Clements

However, by the 1960s, the domain of ecology began to grow rapidly. Ecologists like Odum used ‘ecology’ to mean the structure and function of ecosystems, while others focussed on the abundance and distribution of species. By this time ecology had grown to encapsulate all aspects of organismal patterns and functions in nature.

The post-60s period saw another expansion -namely the value of ecology. While Begon points out that text books, including his, focussed on the science of ecology in its pure form, many were ignoring the fact that ecology had/has important repercussions for how humanity will need to deal with the massive environmental impacts we’ve had on Earth’s natural systems. That is, the science of ecology can provide the foundation by which applied management solutions can be built. I personally believe that applied ecology has only just begun its ascension to being the most important element of ecological science (but I’m biassed -being the Executive Editor of the Journal of Applied Ecology). Just like how human physiology has become problem oriented, often focussed on human disease, ecology will too become more problem oriented and focus on our sick patients.


Begon went on to say what ecology should be in the near future. He juxtaposed the fact and truth based necessity of science to the post-truth Brexit/Trump era we now find ourselves in. If ecologists and scientists are to engage the public, and alter self-destructive behaviours, it cannot be with logic and evidence alone. He argued that we need to message like those post-truthers. Use metaphors, simple messages that are repeated, repeated, and repeated.

Wednesday, November 16, 2016

The value of ecology through metaphor

The romanticized view of an untouched, pristine ecosystem is unrealistic; we now live in a world where every major ecosystem has been impacted by human activities. From pollution and deforestation, to the introduction of non-native species, our activity has influenced natural systems around the globe. At the same time, ecologists have largely focused on ‘intact’ or ‘natural’ systems in order to uncover the fundamental operations of nature. Ecological theory abounds with explanations for ecological patterns and processes. However, given that the world is increasingly human dominated and urbanized, we need a better understanding of how biodiversity and ecosystem function can be sustained in the presence of human domination. If our ecological theories provide powerful insights into ecological systems, then human dominated landscapes are where they are desperately needed to solve problems.
From the Spectator

This demand to solve problems is not unique to ecology, other scientific disciplines measure their value in terms of direct contributions to human well-being. The most obvious is human biology. Human biology has transitioned from gross morphology, to physiology, to molecular mechanisms controlling cellular function, and all of these tools provide powerful insights into how humans are put together and how our bodies function. Yet, as much as these tools are used to understand how healthy people function, human biologists often stay focussed on how to cure sick people. That is, the proximate value ascribed to human biology research is in its ability to cure disease and improve peoples’ lives. 


In Ecology, our sick patients are heavily impacted and urbanized landscapes. By understanding how natural systems function can provide insights into strategies to improve degraded ecosystems. This value of ecological science manifests itself in shifts in funding and publishing. We now have synthesis centres that focus on the human-environment interaction (e.g., SESYNC). The journals that publish papers that provide applied solutions to ecological and environmental problems (e.g., Journal of Applied Ecology, Frontiers in Ecology and the Environment, etc.) have gained in prominence over the past decade. But more can be done.


We should keep the ‘sick patient’ metaphor in the back of our minds at all times and ask how our scientific endeavours can help improve the health of ecosystems. I was once a graduate student that pursued purely theoretical tests of how ecosystems are put together, and now I am the executive editor of an applied journal. I think that ecologists should feel like they can develop solutions to environmental problems, and that their underlying science gives them a unique perspective to improving the quality of life for our sick patients. 

Wednesday, April 13, 2016

Who should communicate the policy implications of ecological research?

Ecology is a science that tries to understand the world. How is the diversity of organisms distributed around the world? How do extreme climate events influence populations of animals and plants? How does the diversity of organisms in a landscape influence its function and the delivery of services to humanity? These are all questions routinely asked by ecologists and, importantly, are topics that most academic ecologists would believe are necessary for providing evidence for policy and management of habitats and natural resources. Yet policy makers, managers and practitioners seldom access ecology research. There is a research-policy divide that needs to be overcome.

Spanning the chasm between academic research and policy (from http://www.adventureherald.com/8-scary-suspension-bridges-you-do-want-to-cross/)
 
Many ecologists are reluctant to promote the policy implications of their research because they do not feel comfortable or connected enough to talk to non-academics. But if not them, then who is responsible to communicate the policy repercussions of their research?

The romanticized view of an untouched, pristine ecosystem no longer exists. We now live in a world where every major ecosystem has been impacted by human activities. From pollution and deforestation, to the introduction of non-native species, our activity has influenced every type of habitat. But this is where management and applied ecology have relevance. The study of human physiology has direct relevance for health science –that is, the value of this basic biological science is measured in its ability to help sick people, and not necessarily in its ability to better understand how healthy people function. So to does ecology need to be relevant for our ‘sick people’, that is, human-impacted landscapes. We have spent much of our collective effort studying intact, semi-natural systems, and this is necessary to understand the basic operations of nature. But now we are required to apply this understanding to improve ecological integrity and human wellbeing. We are surround by sick ecosystems and ecology is desperately needed to influence policy and management.

I just attended the joint symposium “Making a Difference in Conservation: Improvingthe Links Between Ecological Research, Policy and Practice”, put on by the British Ecological Society and the Cambridge Conservation Initiative. This meeting was attended by a nice mix of academic researchers and practitioners, and covered a broad range of ideas, issues and solutions to overcoming barriers to implementing evidence-based policy. Overcoming these barriers requires communication, and scientists need to be at the table. In arguing the case that scientists need to communicate the policy implications of their research below, I take ideas and information passed on in a number of excellent talks, including from: John Altringham, Malcolm Ausden, John Beddington, Ian Boyd, Fiona Fox, Georgina Mace, Andrew Miller, E. J. Milner-Gulland and Des Thompson, and my own workshop on communicating research to maximise policy impact.

A guy who probably doesn't know what he is talking about, talking about policy. Perhaps a bit outside my comfort zone. (photo by Martin Nunez)

The Hurdles

The hurdles to the uptake of research and evidence into policy decisions are complex and multifaceted. On the scientists’ side, the hurdles are mainly a lack of training, experience and comfort promoting the policy implications of their work. In graduate school, very few scientists-in-training take journalism and media courses, and so are not well versed in the ways to communicate in a broadly approachable way. Instead, we are taught to communicate in technically precise ways that can only be understood by similarly trained experts.

On the practitioner side, there are a number of pragmatic and systemic limitations to the uptake of evidence into policy and management decisions:

1.       Structural: There is a lack of resources and time to read and synthesize scientific research. A lack of access because of expensive subscription fees, is a pervasive problem for individuals and small organizations.
2.       Systemic: Big organizations and agencies are complex and communication of best practices or idea sharing might be lacking. Frequent staff turnover means that research understanding and institutional memory is lost.
3.       Relevance: Practitioners need research relevant to their problem and trolling the impossibly large literature is not an efficient way to find the necessary information.
4.       Timescale: Practitioners and policy makers work at a variety of speeds, dictated by priorities, contracts, etc., and looking for resources may not work within these timeframes.

These limitations and the lack of relevant research uptake result in policies and management strategies that are not adequately informed by research, which can waste money and may not produce in the desired results. We heard about the requirement to build bat crossings across new highways (to avoid car collisions), costing millions of dollars, but research has not supported their efficacy. 

Random bat picture to break up the flow (from http://www.bugsbirdsandbeasts.co.uk/go-batty)

Should scientists engage policy makers? 

I do think that scientists have a responsibility to communicate, and perhaps advocate, for evidence to be used in policy decision-making. There is a line between being seen as objective versus as an advocate, and scientists need to do what they are comfortable with, but remember:

  1. You are an expert on your research; you are uniquely position to comment on it.
  2. Related to the previous point, you may not want other, untrained, people to represent and communicate your work.
  3. You have an obligation to the public. You are likely paid by tax dollars and your research is funded by public grants. A part of the responsibility then is to not only do research but to ensure that it is communicated and if the people who ultimately pay you would benefit from learning about your findings, you owe it to them to communicate it.
  4. There are positive feedbacks for your career. Being seen as a scientist who engages and does relevant work will mean that you achieve a higher profile.


Citizens and policy-makers get the most out of their new information (which forms the basis for their opinions) from media news. If the only voices being heard are advocates and interest groups, then evidence will be lacking or misrepresented. Scientists’ voices are needed in the media, and here you can educate many concerned people. The former British Education minister, Estelle Morris, when speaking about the Fukushima reactor meltdown, said that she learned more about radiation from scientific experts in the media than she had during her education.

Of course it is important to remember that science is only a part of the solution, human needs, economics and social values are also important. But without scientists’ involvement, evidence will not be an important part of solutions to crises. 

How to communicate

Scientists are often driven by immediate career concerns and they need to publish high profile, impactful papers in peer-reviewed scientific journals. And this won’t change. But as Georgina Mace said in her presentation, overselling the implications of research in papers diminishes their value and confuses practitioners and policy makers. Policy implications contained within publications is one avenue to influence policy makers, but rather than tacking on broad policy recommendations, consider consulting them before writing the paper, or even better, include them in the planning stage of the study. One speaker commented that instead of asking for a letter of support for a grant proposal from a non-academic partner at the 11th hour, discuss the ideas with them at the outset.

How should scientists communicate their research?
  1. Discuss finings with local interest groups (e.g., park managers).
  2. Give a public lecture to community organizations (e.g., naturalist club).
  3. Talk to local politicians.
  4. Use social media –create a persona that acts as an information broker.
  5. Write opinion articles for magazines or newspaper editorials.
  6. Be accessible to journalists (e.g., get yourself listed in your university expert database).


The UK as a model

The UK provides one of the best examples of meaningful interactions between scientists and policy makers. Perhaps a better way to state it, is that there is a gradient of engaged individuals from pure scientist to local practitioner. There are robust organizations that span government agencies, NGOs, and universities that bring scientists and practitioners into contact with one another. They have Chief Scientific Officers and advisory groups at multiple levels of government. These groups develop the risk registry that estimates the likelihood and the potential repercussions of environmental and biological disasters or emergencies (e.g., influenza pandemic, severe drought, etc.). There is a well respected and effective Science Media Centre that organizes briefing sessions that bring scientists together with journalists on timely and important topics. These briefings result in influential news stories that sometimes challenge government policy or public sentiment (e.g., badger culls, links between vaccines and autism, etc.). This is a system to be emulated.

So, should scientists communicate their findings and engage policy makers, managers and the public. Absolutely. It may seem like you are entering uncharted territory, but believe me, your voice is desperately needed.

If you want advice, encouragement or more information, feel free to contact me.





Tuesday, January 27, 2015

50 years of applying theory to ecological problems: where are we now?

Fifty years ago, the seminal volume ‘The Genetics of Colonizing Species’ edited by Herbert G. Baker and G. Ledyard Stebbins was published, and it marked a new phase for the nascent sciences of ecology and evolutionary biology –namely applying theories and concepts to understanding applied issues. Despite the name, this book was not really about genetics, though there were several excellent genetics chapters, what it was really about was the collective flexing of the post-modern synthesis intellectual muscles. Let’s back up for a minute.

The modern synthesis, largely overlooked and forgotten by modern course syllabi, is the single most important event in ecology and evolution since the publication of Darwin’s Origin of the Species. Darwin’s concepts of evolution stand as dogma today, but after publishing his book, Darwin and others recognized that he lacked a crucial mechanism –how organismal characteristics were passed on from parent to offspring. He assumed that whatever the mechanisms, offspring varied in small ways from parents and that there was continuous variation across a population.

For more than 30 years, from about 1900-1930, evolution via natural selection was thought disproven. With the rediscovery of Mendel’s garden pea breeding experiments in 1900, many influential biologists of the day believed that genetic variation was discontinuous in ‘either-or’ states and that abrupt changes typified the appearance of new forms. Famously, this thinking lead to the belief that ‘hopeful monsters’ were produced with some becoming new species instantaneously. This model of speciation was referred to ‘saltationism’

Of course there were heretics, most notably the statisticians who worked with continuous variation (e.g., Karl Pearson, and Ronald Fisher) who refuted the claims made by saltationists in the 1920s. Some notable geneticists changed their position on saltationism because their experiments and observations provided evidence that natural selection was important (most notably T.H. Morgan). However, it wasn't until WWII that the war was won. A group of scientists working on disparate phenomena published a series of books from 1937-1950 that showed how genetics was completely compatible with Darwinian natural selection and could explain a wide variety of observations from populations to biogeography to paleontology. These ‘architects’ and their books were: Theodosius Dobzhansky (Genetics and the Origin of Species); Ernst Mayr (Systematics and the Origin of Species); E. B. Ford (Mendelism and Evolution); George Gaylord Simpson (Tempo and Mode in Evolution); and G. Ledyard Stebbins (Variation and Evolution in Plants). With this, they unified biology and thus the modern synthesis was born.
Now back to the edited volume. Which such a powerful theory, it made sense that there should be a theoretical underpinning to applied ecological problems. The book grew out of a symposium held in Asilomar, California Feb. 12-16, 1964[1], organized by C. H.Waddington, who originally saw an opportunity to bring together thinkers on population genetics. But the book became so much more. According to Baker and Stebbins:
“…the symposium … had as its object the bringing together of geneticists, ecologists, taxonomists and scientists working in some of the more applied phases of ecology –such as wildlife conservation, weed control, and biological control of insect pests.”

Thus the goal was really about modern science and the ability to inform ecological management. The invitees include a few of the ‘architects’ (Dobzhansky, Mayr, and Stebbins) and their academic or intellectual progeny, which includes many of the most important thinkers in ecology and evolution in the 1960s and 70s (Wilson, Lewontin, Sakai, Birch, Harper, etc.).

Given the importance of the Genetics of Colonizing Species in establishing the role that theory might play for applied ecology, it is important to reflect on two important questions: 1) How much have our basic theories advanced in the last 50 years; and perhaps more importantly, 2) has theory provided key insights to solving applied problems?

This book is the fodder for a graduate seminar course I am teaching, and these two questions are the focus of our comparing the chapters to modern papers. Over the next couple of months, students in this course will be contributing blog posts that examine the relationship between the classic chapters and modern work, and they will muse on these two questions. Hopefully by the end of this ongoing dialogue, we will have a better feeling of whether basic theory has advanced our ability to solve applied problems.