K-12 Activities: Monitoring Biological Diversity

K-12 Activities: Monitoring Biological Diversity

K-12 Activity Ideas:

Monitoring Biological Diversity

by Roxine Hameister

Developing a biodiversity monitoring project at your school can help students develop many skills in an integrated manner. Here are some simple ideas that you can use to get your students started.

Children and teachers are being pulled in many directions. Children want to “learn by doing/’ but because of societal fears for children’s safety, they are very often not allowed to play outdoors and learn at will. Teachers are encouraged to meet the unique learning styles of all students but the classroom reality often means books and pictures rather than hands-on experiences. In addition, children are under considerable pressure to be thinking about their futures and what further, post secondary, education they might be considering.

Sometimes children just like science. Many are of the “naturalist intelligence” and enjoy learning how to classify their world. Activities that meet all these requirements are within schools’ meagre budgets and are indeed possible. These projects are equally possible for the teacher with little science or biology background knowledge. The science skills are readily picked up; being systematic about collecting and recording the data is the main skill needed. The curriculum integration that is possible from these projects range from field studies to computer skills, to art and literature; the entire curriculum is covered in these activities. (more…)

Perspectives: Educating as if Survival Matters

Perspectives: Educating as if Survival Matters

Educating as if Survival Matters

Nancy M Trautmann Michael P Gilmore
BioScience, Volume 68, Issue 5, 1 May 2018, Pages 324–326, https://doi.org/10.1093/biosci/biy026

Published:
22 March 2018

ver the past 40 years, environmental educators through­out the world have been aiming to motivate and empower students to work toward a sustainable future, but we are far from having achieved this goal. Urgency is evident in the warning issued by more than 15,000 scientists from 184 countries: “to prevent widespread misery and catastrophic biodiversity loss, humanity must practice a more environmentally sustainable alternative to business as usual… Soon it will be too late to shift course away from our failing trajectory, and time is running out. We must recognize, in our day-to-day lives and in our governing institutions, that Earth with all its life is our only home” (Ripple et al. 2017).

In this tumultuous era of eco­catastrophes, we need every child to grow up caring deeply about how to live sustainably on our planet. We need some to become leaders and all to become environmentally minded citizens and informed voters. Going beyond buying greener products and aiming for energy efficiency, we must find ways to balance human well-being, economic prosperity, and environmental quality. These three overlapping goals form the “triple bottom line,” aiming to protect the natural environment while ensuring economic vitality and the health of human communities. This is the basis for sustainable development, defined by the United Nations as “development that meets the needs of the present without compromising the ability of future generations to meet their own needs” (WCED 1987). Strong economies of course are vital, but they cannot endure at the expense of vibrant human societies and a healthy environment.

Within the formal K–12 setting, a primary hurdle in teaching for sustainability is the need to meaningfully address environmental issues within the constraints of established courses and curricular mandates. In the United States, for example, the Next Generation Science Standards designate science learning outcomes for grades K–12 (NGSS 2013). These standards misrepresent sustainability challenges by portraying them as affecting all humans equally, overlooking the substantial environmental justice issues evident within the United States and throughout the world. Another oversight is that these standards portray environmental issues as solvable through the application of science and technology, neglecting the potential roles of other sources of knowledge (Feinstein and Kirchgasler 2015).

One might argue that K–12 students are too young to tackle looming environmental issues. However, they are proving up to the challenge, such as through project-based learning in which they explore issues and pose potential solutions. This may involve designing and conducting scientific investigations, with the possibility of participating in citizen science. Case-study research into teen involvement in community-based citizen science both in and out of school settings revealed that the participants developed various degrees of environmental science agency. Reaching beyond understanding of environmental science and inquiry practices, this term’s definition also includes confidence in one’s ability to take positive stewardship actions (Ballard et al. 2017). The study concluded that the development of environmental science agency depended on involving teens in projects that included these three factors: investigating complex social–ecological systems with human dimensions, ensuring rigorous data collection, and disseminating scientific findings to authentic external audiences. Educators interested in undertaking such endeavors can make use of free resources, including an ever-growing compendium of lesson plans for use with citizen-science projects (SciStarter 2018) and a downloadable curriculum that leads students through the processes of designing and conducting their own investigations, especially those inspired by outdoor observations and participation in citizen science (Fee 2015).

We need to provide opportunities for students to investigate environmental issues, collect and analyze data, and understand the role of science in making informed decisions. But sustainability challenges will not be resolved through scientific approaches alone. Students also need opportunities to connect deeply with people from drastically different cultures and think deeply about their own lifestyles, goals, and assumptions. As faculty members of the Educator Academy in the Amazon Rainforest, we have had the privilege of accompanying groups of US teachers through 10-day expeditions in the Peruvian Amazon. Last summer, we asked Sebastián Ríos Ochoa, leader of a small indigenous group living deep in the rainforest, for his view of sustainability. Sebastián responded that he and his community are one with the forest—it is their mother, providing life and wholeness. Reflecting on the changes occurring at an accelerating rate even in remote rainforest communities, Sebastián went on to state that his greatest wish is for his descendants to forever have the opportunity to continue living at one with their natural surroundings (Sebastián Ríos Ochoa, Maijuna Community Leader, Sucusari, Peru, personal communication, 18 July 2017). After decades of struggle during which their rainforest resources were devastated by outside loggers and hunters (Gilmore 2010), this indigenous group has regained control over their ancestral lands and the power to enact community-based conservation practices. Their efforts provide compelling examples of how people (no matter how few in number and how marginalized) can effect positive change.

In collaboration with leaders of Sebastián’s remote Peruvian community and a nongovernmental organization with a long history of working in the area, US educators are creating educational resources designed to instill this same sense of responsibility in children growing up without such direct connections to nature. Rather than developing a sense of entitlement to ecologically unsustainable ways of life, we need children to build close relationships with the natural world, empathy for people with different ways of life, and a sense of responsibility to build a better tomorrow. Although the Amazon rainforest is a common topic in K–12 and undergraduate curricula, typically it is addressed through textbook readings. Instead, we are working to engage students in grappling with complex real-world issues related to resource use, human rights, and conservation needs. This is accomplished through exploration of questions such as the following: (a) How do indigenous cultures view, interact with, and perceive their role in the natural world, and what can we learn from them? (b) How do our lives influence the sustainability of the rainforest and the livelihoods of the people who live there? (c) Why is the Amazon important to us, no matter where we live? (d) How does this relate to the triple-bottom-line goal of balancing social well-being, economic prosperity, and environmental protection?

Investigating the Amazon’s impacts on global weather patterns, water cycling, carbon sequestration, and biodiversity leads students to see that the triple bottom line transcends cultures and speaks to our global need for a sustainable future for humans and the environment throughout the world. Tracing the origin of popular products such as cocoa and palm oil, they investigate ways to participate in conservation initiatives aiming for ecological sustainability both at home and in the Amazon.

Another way to address global issues is to have students calculate the ecological footprint attributable to their lifestyles, leading into consideration of humankind vastly overshooting Earth’s ability to regenerate the resources and services on which our lives depend. In 2017, August 2 was determined to be the date on which humanity had overshot Earth’s regenerative capacity for the year because of unsustainable levels of fishing, deforestation, and carbon dioxide emissions (Earth Overshoot Day 2017). The fact that this occurs earlier each year is a stark reminder of our ever-diminishing ability to sustain current lifestyles. And as is continually illustrated in news of climate disasters, human societies with small ecological footprints can be tragically vulnerable to such calamities (e.g., Kristof 2018).

Engaged in such activities, students in affluent settings may end up deriving solutions that shake the very tenet of the neoliberal capitalistic societies in which they live. To what extent should students be encouraged to challenge the injustices and entitlements on which world economies currently are based, such as by seeking ways to transform the incentive structures under which business and government decisions currently are made? Should they be asked to envision ways of overturning the unsustainable ways in which modern societies deplete resources, emit carbon dioxide, and destroy the habitats needed to support diverse forms of life on Earth?

Anyone who gives serious consideration to the environmental degradation and social-injustice issues in today’s world faces the risk of sinking into depression at the thought of a hopeless future. What can we possibly accomplish that will not simply be too little, too late? Reflecting on this inherent tension, Jon Foley (2016) stated, “If you’re awake and alive in the twenty-first century, with even an ounce of empathy, your heart and mind are going to be torn asunder. I’m sorry about that, but it’s unavoidable — unless you simply shut down and turn your back on the world. For me, the only solution is found in the space between awe and anguish, and between joy and despair. There, in the tension between two worlds, lies the place we just might find ourselves and our life’s work.”

Education for sustainability must build on this creative tension, capturing students’ attention while inspiring them to become forces for positive change.

Acknowledgments

Collaboration with the Maijuna is made possible through work of the OnePlanet nonprofit organization (https://www.oneplanet-ngo.org) and Amazon Rainforest Workshops (http://amazonworkshops.com).

Funding statement

Nancy Trautmann was supported through a fellowship with the Rachel Carson Center for Environment and Society in Munich, Germany, to develop curricular resources that highlight the Maijuna to inspire U.S. youth to care about conservation issues at home and abroad.

References cited

Ballard HL, Dixon CGH, Harris EM. 2017.

Youth-focused citizen science: Examining the role of environmental science learning and agency for conservation. Biological Conservation 208: 65–75.

 

Earth Overshoot Day. 2017. Earth Overshoot Day 2017 fell on August 2. Earth Overshoot Day. (1 December 2017; www.overshootday.org)

 

FeeJM. 2015. BirdSleuth: Investigating Evidence. Cornell Lab of Ornithology . (15 January 2018; http://www.birdsleuth.org/investigation/)

 

FeinsteinNW, KirchgaslerKL. 2015.

Sustainability in science education? How the Next Generation Science Standards approach sustainability, and why it matters. Science Education 99: 121–144.

 

Foley J.2016. The space between two worlds. Macroscope . (28 October 2016; https://themacroscope.org/the-space-between-two-worlds-bc75ecc8af57)

 

Gilmore MP. 2010. The Maijuna: Past, present, and future . 226–233 in Gilmore MP, Vriesendorp C,Alverson WS, del CampoÁ, von MayR, WongCL, OchoaSR, eds. Perú: Maijuna. The Field Museum.

 

KristofN.2018. Swallowed by the sea. New York Times. (23 January 2018 ; www.nytimes.com/2018/01/19/opinion/sunday/climate-change-bangladesh.html)

 

[NGSS] Next Generation Science Standards. 2013. Next Generation Science Standards: For States, By States. NGSS. (10 October 2017; www.nextgenscience.org)

 

Ripple WJ et al.  2017. World scientists’ warning to humanity: A second notice. BioScience

67: 1026–1028.

 

SciStarter. 2018. SciStarter for Educators. SciStarter . (12 February 2018; https://scistarter.com/educators)

 

[WCED] World Commission on Environment and Development. 1987. Our Common Future . Oxford University Press.

 

© The Author(s) 2018. Published by Oxford University Press on behalf of the American Institute of Biological Sciences.

This is an Open Access article distributed under the terms of the Creative Commons Attribution Non-Commercial License (http://creativecommons.org/licenses/by-nc/4.0/), which permits non-commercial re-use, distribution, and reproduction in any medium, provided the original work is properly cited. For commercial re-use, please contact journals.permissions@oup.com

 

Blog: Teacher Preparation

Blog: Teacher Preparation


Know and Do What We Teach: How many times are we assigned to teach a subject we know little about?

by Jim Martin
CLEARING Special Contributor

t a riparian ecology training for teachers a few years ago, I met two who epitomize a perennial problem in education in America. One of the teachers was in her third year of teaching, said she had no background in science, was never trained for teaching it, but was assigned to teach all of the 6th grade science in her middle school. The other was a teacher who had been a fisheries biologist for several years, and was now teaching high school science. Two teachers, each of whom is assumed will deliver equally effective, student-empowering curricula in their schools. Who are assumed to be teaching at the same level of experience and expertise. How do we rationalize this? How do we deal with it?

Many teachers who lack confidence in teaching the content they are assigned forces them to simply use and parrot the instructions in teachers’ editions of their assigned curricular materials. If we are simply in the schools to prepare our students for the standards tests they will take, adhering to the status quo may be able to make the attempt; although, to date, this effort has produced no nation-wide positive result. But, if we are in schools to involve and invest our students in authentic and challenging concept-based curriculum, and to deliver our curricula in a way which empowers them as persons, then we all need to comprehend the concepts we teach at a level which makes us comfortable in determining our own ways to deliver our curricula. The only way to do that is to know and do what we teach.

As long as we are able to build a learning environment which involves and invests our students in their learnings and empowers them as persons, their brains will do the work. While there are many reasons posited for the poor performance of US students compared with their global peers, assumptions about student capacity based on demographics ought not to matter, not be a reason for poor performance; the brain is an autonomous learning machine. If we allow it.

Why should I want more than a good set of published curricular materials?

All teachers of empowered students that I’ve observed have a content background strong enough to allow them to design their own curricular deliveries. And their students, regardless of demographics, respond to this in a positive, participating way. I’ve also observed teachers with little or no background in the curricular content and/or grade level they are assigned to teach become exceptional teachers when they receive competent mentoring in their classrooms while they are teaching. Just as with their students, these teachers’ brains became autonomous learning machines when they were allowed to. Our expectations re teachers’ preparation for the content they are assigned to teach is a strong indicator that many of us do not allow that. They are assigned to teach what they are assigned to teach. Beyond that, most receive precious little support in the way of developing professional competence in their assigned content area.

Would we accept a world in which only about half of automobile mechanics have training to repair the motors they work on? Where half of dentists have the training to perform a root canal on their root canal patients? How about only half of surgeons with training for the surgeries they perform? Only half of lawyers with training for the cases they proceed with in the court? Half the baristas with no training for the coffees they produce in the coffee shops where they work? We have, and assume, the right to people who have had effective training for the work they perform. Except for teachers. It’s almost as if there is an assumption that teachers can “just do it.” In fact, I’ve heard this claim. More than once.

So, why are we so complacent about having teachers in classrooms who may be only marginally trained in the content they deliver? Jaime Escalante taught calculus to students at Garfield High School in Los Angeles, where 85 percent of the students were eligible for free or reduced-fee meals, and faculty morale was low (Scientific American, Aug 2011, p. 14: Stand and Deliver). His unpopular, to some, attitude toward his students’ brains’ capacity for learning was displayed in a banner in his classroom which declared, “Calculus does not have to be made easy – It is easy already”. In spite of opposition from the school administration and some faculty to his teaching, more of his students took the AP calculus exam than at all but three other public schools in the nation. Two thirds of his students passed the exam. He possessed a background in calculus which allowed him to develop and execute a very clear demonstration that the brain is an autonomous learning machine when we allow it. And proved it.

In a recent article, Climate confusion among U.S. teachers: Teachers’ knowledge and values can hinder climate education, published in the 12 February 2016 issue of Science magazine, the authors report that fewer than 25% of teachers have the training they need to teach the basics of global warming. This, in spite of the fact that climate change may be the most important challenge that today’s students and their children will face. Why aren’t schools allowed to provide the training their teachers need to become more effective teachers of climate change in their classrooms? A large fraction of the business world does just that. Especially when there is a demonstrated authentic need for it.

What do I need in addition to good curricular materials to better prepare my students for their future?

A suggestion: I submit that we need to work together to develop an effective method to ensure that teachers have access to the training and support they need to teach inquiry-based science in their classrooms. Every day. We don’t think of students as the people who will set our nation’s place among the other nations in the world, but they are. We need more than a small fraction of K-12 students who excel in school. My experience tells me that nearly all students have the capacity to either excel, or do very well in school. Dysfunctional families can certainly hold their children back, and schools have very little influence over what happens at home. But, they ought to have influence over what happens at school. That’s where their power lies.

Schools, can, and do, produce environments in which all of their students can excel, or at the least, do very well. For instance, one school I’ve known for a long time does just that. The Jane Goodall Environmental Middle School (JGEMS), a public charter school in Salem, OR, does that consistently every year. Entering students are selected via a lottery which covers Salem’s demographic spectrum. While the faculty don’t focus on the standards, each year 100% of their students pass the standards exams, 90% or more at the two highest levels. Oddly enough, all of their teachers have strong backgrounds in the content they teach.

In many of these cases, teachers have engaged in summer workshops and institutes which deliver hands-on experience in doing science inquiries they have conceived, designed, and executed in natural environments, and using those experiences to develop in-depth content knowledge of the subject of their inquiries. This is a context in which regional environmental educators and experienced teachers can collaborate to plan and execute workshops and institutes which can provide the training and support to produce classrooms which are facilitated by teachers who are experienced in science inquiry and have deep knowledge of the content they teach. And which deliver students who are involved and invested in their educations; and empowered as persons. A strong content and process background gives teachers the confidence it takes to deliver a student-centered, active-learning based curriculum. Something we all need to learn to do. Well.

How can you help?

jimphoto3This is a regular feature by CLEARING “master teacher” Jim Martin that explores how environmental educators can help classroom teachers get away from the pressure to teach to the standardized tests, and how teachers can gain the confidence to go into the world outside of their classrooms for a substantial piece of their curricula. See the other installments here, or search Categories for “Jim Martin.”

Jim Martin on Inquiry

Jim Martin on Inquiry

Is active learning an effective vehicle to train science inquiry mentors?

Walking along with you is far better than telling you “I’ll show you the way.”

ow should we prepare mentors of teachers who wish to learn how to engage their students in authentic science inquiry, to provide what they will need for the work they will do? Should we get them together and show them what to do? Or, engage them in active learning focused on mentoring, and respond to what emerges? I know from my various experiences in being trained that listening to a speaker, then watching from a distance as the speaker demonstrates an activity, does next to nothing for me. When I arrive to do the work I was trained for, I’m not sure where to start. There, on site, bright smiling face, but a little uncertain just what to do. When my training has me actually doing the work, I arrive on site ready to go; looking forward to doing the work. So, I think I’ll describe mentor training via, mostly, active learning.

What is mentor training via active learning like?

Since classroom teachers will probably find doing a first field trip on their own a bit daunting, we’d start the teacher/environmental educator mentors-in-training doing just that. They’ll do a training, more or less on their own. First, we’d group them in pairs, then have them move through three or four stations representing those that students would move through on their first field trip. Participants’ first job at this training will be to decide how to do the work at each of the stations, say, “Streamside Vegetation.” As they go, these mentors-in-training will share what they know about the station they are visiting, and how they would assist an inexperienced teacher to become comfortable doing that station.

At each station, there would be a poster board, Post-Its, and a felt pen. The board would have the name of the station on it, and the rest of the space for questions and comments. For this training, the questions and comments would relate to the work of mentoring inexperienced teachers as they go to a natural site to do the work at this station for the first time. As they work out the way they think the station would be best done, they will make comments on the Post-Its and place them on the board. As the concept clarifies itself, they might wish to move the Post-Its around to reflect this.

After they organize the Post-Its on the boards as they wish, they will decide on outcomes for that particular station, what the students who visit it will take away from their experiences. Then, they will decide how the station will be introduced to students. Hopefully, they will have clarified the purpose of and function of the station, and they can decide on a rationale, a mission statement of sorts, for that station. A training done this way, not a talking head, telling them about it, but an active way of discovering it for themselves. All of this will go to the board on Post-Its, or, if they are sure of what they’ve done, they would use the felt pen to mark off a heading and space for the Post-Its that go under that heading.

Then, they will organize themselves to do the work of the station, and do it. While working, they would engage in an interactive dialog as they move along; clarifying, suggesting, and making recommendations which emerge from their experiences at that station. When they’re finished, they may wish to modify or add to the Post-Its on the board. After completing this station, they will rotate to the next one, where they will repeat the process. As they go, they will add Post-Its of their own, rearrange them, and add a heading if they think it should be a permanent part of the board. They continue until they’ve completed the work at all stations. (This exercise was first introduced to me by Rebecca Martin, when she used it in a Salmon Watch teacher training. I call it a concept-induction exercise. Some call it an ideation exercise. It’s very effective. I’ve even used it to focus a meeting to plan a performance center in Vancouver, WA, where I live.)

What might mentors-in-training take away from this active learning exercise?

At the end, after all groups have visited all stations, the entire group will do a walk through the stations, pointing out curricular elements embedded in the environment, listing equipment that would be needed or helpful in doing the work, noting safety measures for particular parts of each station, sharing what they’ve learned, discussing the work to understand it better and suggest modifications. As part of this, they will review each updated poster board (which remained on station), and nail down their recommendations, etc. At the end, they will suggest next steps, which might be no change needed, or some further changes.

When this has been done, the mentors should be able to have moved inexperienced teachers to a place where they can, with time, become teachers who confidently move their students, via active learning in a natural environment, toward the knowledge, skills, and understandings they will need to respond to the effects of climate change effectively. The purpose of all these words.

jimphoto3This is a regular feature by CLEARING “master teacher” Jim Martin that explores how environmental educators can help classroom teachers get away from the pressure to teach to the standardized tests, and how teachers can gain the confidence to go into the world outside of their classrooms for a substantial piece of their curricula. See the other installments here, or search Categories for “Jim Martin.”

Jim Martin on Science Inquiry

Jim Martin on Science Inquiry

Can We Learn What Science Inquiry Does For Us? What To Teach; And How?

 

by Jim Martin

n a previous blog, a student, Maria, noticed a salmon fry darting toward a rock covered with periphyton, a thin colony of algae which supports microbes and invertebrates living in it. Her eye lit up as she became aware of it; a wonderful learning moment, the kind which lights up our brain.

How do you learn to recognize when Maria’s eye has noticed something, and made a conceptual connection with it? What experiences ought you have to recognize that moment and use it effectively? Then to follow up? How did we get here in the first place? We’re exploring the use of inquiries outside the classroom to discover how to use active learning effectively. And, while doing that, to discover and use the curricular content embedded in the world outside the classroom. How do we help teachers become comfortable with this?

Does what we teach reside solely in our curricular materials? 

We do inquiries; do we ever ask what inquiries do for us? One thing that student-directed inquiries do is to use the way our brain learns best, which should be driving our deliveries. When we begin a new learning, it will more than likely possess latent connections to previous conceptual learnings stored in associative memory in our brain. If we can organize a student’s environment so that this might happen, then we have set up an environment where conceptual learning will occur. Our brain is an autonomous learning machine when it encounters something interesting in the world about. We set this in motion when we organize a student’s environment so that a question will more than likely emerge from it. When this becomes part of the foundation our teaching is based upon, conceptual learnings become a normal product of our classrooms.

Some students, like Maria, will rather quickly note a connection between what they observe at the moment, and what they already know. These students, engaging what Lev Vygotsky described as a zone of proximal development, will provide, by what they say and do, the pieces of the puzzle for those who have not yet attained the new concept; not yet seen the connection between what they observe, and what they already know. Yet, whose brains already hold all of the relevant pieces. This capacity to see and make connections is something I’ve observed that all students will develop as long as they are in an environment where active learning is routinely engaged. Since self-directed inquiries stimulate our brain to engage in critical thinking and conceptual learnings, that is precisely what inquiries do for us. Build autonomous, thinking brains.

Does conceptual learning only occur when students engage curricular materials in our classrooms?

How do we get there, the place where autonomous, thinking brains develop? You have to know the things students will encounter as they learn, then direct them to those pieces which have the capacity to engage human interest. In the previous blog, we discussed the idea of a teacher in-service workshop in which teachers, environmental educators, and a regional environmental education center might be used to help classroom teachers become comfortable with science inquiry in a natural environment. In this pilot workshop, we posited starting with a science inquiry training in which teachers would engage concrete entities in a natural area. Those who I have worked with in workshops like this have always experienced the way that simply engaging teachers in particulars of the place they are in stimulates questions which are easily turned into effective inquiries.

Noticing something which catches your interest has a way of stimulating you to want to know more about it. Everything could end right there, and you might continue on your way. If, as you move along, you encounter another of the thing which caught your interest, you will notice it, and may even raise a question about it. This is the way your brain works when it is engaged in conceptual learning. We need to learn to use it routinely in our teaching. It leads to long-term conceptual understandings. Not items to recall on a test, but conceptual information which seems just common sense.

If you were a participant in the in-service workshop I mentioned above, and you encountered something interesting which raised a question in your mind, there would be teacher-mentors and environmental educators there to help you locate resources, etc., but not to tell you what to think and do to answer it. Your brain, not theirs, is the one that’s learning. (Likewise in our own classrooms; the students, not we, need to do the learning!) Then, there would be a follow-up on questions and/or insights entrained by the science inquiry process. (My own students would review and research more information than I could teach via a conventional deliveries.) The important thing is that much of what you find and process in your brain will remain as conceptual associative memory, available on demand. Even when, in your classroom in May, you ask students to recall what they learned when they did such and such an inquiry in October. It does work.

Maria went on to learn about the salmon fry and periphyton colonies she met while she was on site at the stream. Most of what she learned came from her observations in the real world, researching information about them on the web, and reading in the texts in her classroom. More learning than a teacher can deliver by teaching the whole class one piece at a time. The trick is to organize the work so that each student or group contributes a nice piece of the overall learning. Sharing brings it all together. Enough teachers, and schools, have successfully adopted active learning deliveries that we ought to be encouraging it in our schools, our districts, and our state departments of education.

Many classroom teachers don’t have a strong background in the science they teach. We, the classroom teachers, need to develop a systemic way to build a strong content background in the concepts that we teach. Formidable hurdle, but it can be done. Since I first started tracking it in the early 1970s, about half of U.S. teachers have had little or no college-level preparation for the content they teach. We’re assigned to teach it anyway because there’s no one else to do it; we’re coaches who need a full-time salary, our principal assigns us to teach it, etc. How would our tech sector do if they applied the same staffing model? For now, we are the ones who have to take up the slack. We need to work together to build our capacity to effectively engage our students in the excitement and comprehension of science in the real world. We may not solve the problem, but I know from experience that we can make a dent in it. We’ll take that up as we go along.

jimphoto3This is a regular feature by CLEARING “master teacher” Jim Martin that explores how environmental educators can help classroom teachers get away from the pressure to teach to the standardized tests, and how teachers can gain the confidence to go into the world outside of their classrooms for a substantial piece of their curricula. See the other installments here, or search Categories for “Jim Martin.”