Behind the Scenes at TpT Flock

5 Takeaways from the TpT Flock Regional Conference

I was lucky enough to go to the Teachers Pay Teachers Conference, or Northeast Regional Meet Up called TPT Flock last weekend. It was an inspirational event with many educators who are really changing the face of education and having a huge impact on students, not only in their classroom, but on so many other classrooms in the US and around the world. 

Many of my biggest takeaways apply not only to TPT but also to the classroom of a regular teacher outside of the classroom. I wanted to share some of those takeaways with you.

Details matter, but everything doesn’t have to be perfect

Of course we don't want to make materials for our classroom, or to share professionally, that are full of errors or look messy. However, I think often we try too hard to make something perfect. As we use it it will grow and develop. It's more important sometimes to get something of good quality out (either to our students, or our colleagues) and start using it than it is to keep it on our computer, or in our heads, until it's a hundred percent perfect. Details do matter, but “strive for progress, not perfection.” - Unknown

Don’t try to do it all

This is the biggest thing that I felt like I kept hearing all day: don't try to do it all! This also applies to your classroom! Everybody has their strengths. Maybe you're really good at games and making class fun, or having a sense of humor. Maybe you're really good at connecting with students, or have really innovative and fast ways to grade and assess. Perhaps you are good at building in teachable moments or differentiation, or reading strategies. Maybe you are really good at read alouds and doing demonstrations. There are countless pieces of being a good teacher. No one is good at all of them! Focus on your strengths and build on those! Focus on one thing at a time that you want to learn and improve on, but realize that you do not have to do it all. If you spread yourself too thin you probably won't be successful. Instead, maybe take one unit to try something new, or try one new method at a time.

Collaborate, and reach out for Support

Teaching is often a solitary endeavor, even though we are constantly around people. No one is really in our classroom with us, and we may or may not be in the situation where we plan as a team and really collaborate with other teachers. In my teaching experience there are many times when we're really working alone in our classroom with our students. This is why it's so important to reach out. It could be within your school to to your administrator, to other teachers in your school, or to Facebook groups or discussion boards. Realize that you're not alone! You have things to offer to other people and they may be able to offer you simple solutions in an area that you're struggling

Learning happens when you connect with other people, and with what you already know

Sometimes we think that we're going to learn a bunch of new information on our own by going to a training, reading a book, or seeing something online. In reality there are many times that the best learning happens when we build on what we already know and discuss it with other people! We may see someone doing something just a little bit different than what we're doing, or add on one new twist that makes a big difference. As educators we know that students need a foundation for what they are learning and that they learn best when building on what they know. We often forget this ourselves. It applies to us too! Take what you're doing, talk about it with other people and go just one step further than what you are doing. You might be amazed at the results.

Remember your why

Remember why you became a teacher, and began this journey. Teaching can be a rocky road, and often a draining job. You may have to deal with difficult parents or behavior problems. Think about why you got into this and what were your goals. Maybe you wanted to help students understand the world around them, get them excited about science, help them see that they can be successful or help them grow as young adults. I'm sure you have your own reasons. Take a couple minutes and think about what those reasons are. There have been several times throughout my career when I got to the point where I didn't think that I was wanted to teach anymore. Just as I thought I couldn't take it anymore a something really positive happened. A student had a breakthrough learning moment or came to thank me for something or some other small action happened during the day that made me remember why I come to work every day.

I was lucky enough to go to the conference and meet up with some fantastic teachers from many different states and even Canada I felt honored to be part of that group. However we work with many great educators everyday and we need to remember that and be thankful for each other and for our students.

Looking to Make Weathering and Erosion more Student-Centered

Making Weathering and Erosion More Student-Centered

Weathering and erosion is one of my favorite topics to teach! I get excited every year when that unit comes up. Why? Because it's something that is reallys so visual, and easy to make hands-on. It's happening all the time, all around us, but many kids aren’t aware.

Introduction

I start off with some very quick stations where students look at some pictures, and small examples of weathering, and real life examples similar to weathering (a rusty nail, a tree root that grows and splits a rock, calcium chloride tablets that are put in a jar and shaken to see how they break down, and chalk is put in vinegar to see how it changes and breaks down. At each station they are asked to make some observations, and answer a simple question or two about what happened.

We then re-group and discuss the changes that we saw. We come up with a common definition of weathering. Then we break it down further -- two of these stations that we saw are chemical weathering, and two are physical. What do they have in common? How can we define those? 

Physical and Chemical Weathering

Then we go into weathering in more detail. This is a great place to do lots of shorter labs (such as this weathering lab pack), and practice experimental design skills, and some other basic science skills like graphing changes, writing conclusions, etc.

I do a lab on chemical weathering where students design how to test the effect of acid on weathering rate, using coffee, vinegar, water, and chalk. They have to get their procedures approved before the proceed, but they will need to come up with a way to measure their changes, and write their procedures and conclusions.

This is a great chance to practice skills such as observation, measuring, and even writing procedures.

For physical weathering we do several small stations on the factors that affect physical weathering (particle size, time, composition). Then they do a summary on these factors, where they have to apply it to a real life situation, and write about it (practice writing and using evidence).

Erosion

Then we move into erosion. This is a great place to integrate high interest activities, because we start off erosion with video clips of avalanches, rivers flooding their banks, etc. Again, we look at what all these have in common to define erosion, and how it is different than weathering. This is memorable for students, and helps them make a connection!

I then structure the erosion part of the unit very similarly. We do a lab on factors that affect stream erosion, and they get to test out things like slope, water velocity, amount of water, collect their data etc. We may do this as a whole group lab, and study stream development.

We also do stations on other types of erosion. I use a big block of ice to simulate a glacier. You can see some great photos and feedback from @teaching_science_irl below. Students at that station compress the ice into a bin of sediments, drag it across, and make observations. Then they draw parallels to the features that are seen on earth with real glaciers and glacial erosion. Similarly, some mixed sediments and a piece of cardboard can simulate erosion by gravity. A hair dryer, or even a straw that students blow on, and some fine sediments can simulate erosion by wind. This allows them to start to see the features, and draw some conclusions. When this is coupled with additional resources, students can really connect!

Here is a picture of wind erosion as students examine which size particles travel farther, and the patterns that they make.

Benefits of Teaching this Way

For us weathering and erosion are a real life topic, but for many students who have never travelled and seen these features it can be very abstract. These hands-on activities help to make it more real, and then allow them to make the leap to test questions and other real-life situations

These hands-on activities help make these concepts more real-life, and keep kids engaged. Once they have the foundation and background knowledge, on the topic, they are then much better able to take it the next step and apply to other real life situations or test questions. 

Wrapping Up

Then we do some review and summary. I usually do this on paper, but some of these review activities could be integrated within the unit as stations or activities to break up each section if you are looking for a change from the hands-on. I have this activity where students look at different pictures of weathering, erosion, or deposition, and have to identify which it is. After that, they then have to identify what type of weathering, or what the agent of erosion was.

I also have the students do an activity where they create a concept map of pictures and terms of weathering, erosion, and deposition. This can also, of course, be done with just one of these topics. This is a great way for students to think through the processes, and also for you to really better understand their thinking.

This is also a good time to have students practice with vocabulary, through either Quizlet, matching terms and definitions, or doing any number of other vocabulary activities.

Sometimes, depending upon the group, I like to have a summative assessment where they are given a situation (an erosional feature, or photos of Cleopatra’s Needle, or cemetery photos and having them explain what they see, in terms of weathering and erosion.

What can you add?  How do you teach like to teach Weathering and Erosion?  

If you are looking for all of my resources together, click here to check them out. 

How to grade differentiated assignments

Whenever there is discussion of differentiation, or creating and using differentiated assignments, one of the biggest struggles that comes to my mind, and I think for many other teachers, is how to grade those assignments fairly (and hopefully without creating excessive work for the teacher).

It can be overwhelming to think about how to grade all these different assignments or how to make sure that students are fairly evaluated when they're given different assignments here are a few ideas:

First of all, keep in mind that in some cases differentiation is simply another way to learn the content, or practice with the content, and that it does not need to be graded separately. It is a different way to arrive at the same goal and only feedback or formative assessment may need to be given.

If you do decide to grade the differentiated assignment, here are a few suggestions:

1. You could create a checklist and then simply add or subtract a few items on that list from the differentiated assignment.
2. Create a rubric so that whichever format of an assignment students are doing they need to meet the same general criteria but they might meet it in different ways.  The rubric should be focused on the content and the goals of the assignment, not the format.  Here is an example of that. Along with rubrics, here is a more in-depth discussion of something called the “slide rubric” which allows students to show growth, and to show more differences between levels on the rubric. It would take a bit of work to set up, but be easy to score when finished. 
3. The differentiation may be scaffolding that is provided within the assignment, in order to reach the same goal. So, it may not be visible in the final grading.  The final assignment that is turned in may be the same, but it may have some scaffolding built in. 
4. If it's a small assignment, you might want to consider giving a check, or a completion grade for partially complete, incomplete, or not done scale, given whatever their assignment directions were.
5. Assessment could also focus on progress monitoring, such as showing growth, depending upon the needs of your classroom.  I think elementary classrooms do a much better job at this than secondary.  We have a lot to learn from them!! 

As you are thinking about this, remember that 

Grading should ultimately reflect the standards so you're grading should come back to what are the key points that students need to know did they demonstrate their understanding?? Maybe they demonstrated them in different ways but if they sufficiently demonstrated that they know the material that should be the focus of their grading. In other words, the grading is tied to the content of the project, not the format of the project. This is discussed further in this webpage (a very thorough look at differentiation, with a discussion of grading).

If you are using technology, Google Classroom has great options for differentiation as well, that you should be aware of! This article doesn’t specifically address grading, although it touches on it, but it is a great description of using Google Classroom to differentiate, and may give you some great ideas!

As far as a more theoretical perspective, here is a great slideshow from Carol Tomlinson (Differentiation Guru) on grading. She outlines 6 principles on grading that absolutely apply to grading differentiated work as well, and help put things in perspective.

How have you differentiated and graded those differentiated assignments in your classroom? I would love if you would share your experience and your ideas with us either in the comments here, or in our Facebook group.

Help Your Students Struggling with Vocabulary

My Students Know the Content -- Why Do They Test So Poorly?

You may have been taught and prepared to teach your students the content. You have spent time doing that, and you think they understand. Then you give them standardized test questions and they bomb, they shut down, or they keep calling you over very confused. How can this be? You thought you taught them this information?

Sometimes it's not the content words that students are struggling with, but instead it's the non-content vocabulary or the Tier 2 vocabulary. In other words, they know the content but they don't understand the questions or they don't understand the reading passage. If they don't really understand what they are being asked, they can't begin to answer the question.

So many of our students don't have the background knowledge and vocabulary, they may be ELL students or they may just not have a lot of academic vocabulary.

So what can we do about this? 

We need to teach our students this vocabulary! And to successfully teach vocabulary students need practice with those words in several different ways. Of course, this seem like an overwhelming task try to bring our students up to grade level with their vocabulary during science class or another content class but it doesn't have to be as difficult as it sounds. I have written about this before, but I was asked for more specifics on how I implement that strategies and vocabulary that I use.

Here is what I have done

Here is what I did to work on tackling that problem and I'm hoping it will help you too. I went through our last couple years of State exams as well as a few other resources and I compiled a list of Tier 2 vocabulary words. I also asked my students, as we did practice questions throughout the year, what words they didn't know or were confusing and added to the list. I also shared resources with a few other teachers. At that point I had a very good list of words.

I use those first for warm ups. Here are the basic steps that I follow:

• I took a word a day, usually, and I gave them a sentence or a picture to infer, or comparison to another word. 
• Then I had them try to conceptualize and infer what they thought the definition of the word was. 

I would usually project these on the board, and have students record their answers. This could, of course, be done in a Google Form, slide, on paper, or many other formats that fit with your classroom routines. This did two things at once: (1) they got to practice the skill of inferencing and using context clues to figure out the meaning of a word that they didn't know, (2) they also started to get familiar with some of these words.

I would usually do one word a day so five words a week and then after the end of the week or at the end of 2 weeks we would have a little quiz on those words. Sometimes it would just be a matching quiz, sometimes question that had one of those or a reading passage that had one of those words so they could see it in context.

After awhile, it was amazing, students started to learn some of the words but more importantly they started to gain confidence. When we do test questions where they would run across those words I would start to hear things like “Oh, I know this word!” “This is a word we just did last week.” They were not longer foreign, but were familiar instead. Even if they didn’t remember all the definitions, the vocabulary had lost its power to be scary!

What's the Next Step

It's so important that these are integrated in throughout the year and the students practice using them so that it's not an isolated thing. To facilitate this, when we did stations for other topics (I do a lot of stations in my classroom) I usually throw in one extra station to focus on those vocabulary words. It might be the same thing as what is on the board, as a review, but a few task cards printed out. It could be matching up words and definitions either on paper or on Quizlet. Sometimes the station would focus on vocabulary more subtly because it would ask them to write a test question using some of those words (maybe with a word bank or sentence stems). It's so important that they see these over and over again so that they lose their fear and mystery.

Where Can I Find Out More

More strategies are outlined in this great article 8 Steps to Tier 2 Academic Vocabulary in Your Students and here Enriching Academic Vocabulary: Strategies for Teaching Tier Two Words to E.L.L. Students.

This is something that you could easily implement on your own but if you would like to make it easy, my complete set of over 200 words (more than enough to use one every day) they're available here

Here are a few of the pieces of feedback I have gotten on this resource.  I hope it can be helpful to you as well!

I also wrote more about this strategy in these other posts, here, here, here, here, and here.

How do the New NGSS Standards really affect me?

As Next Generation Science Standards come out, and start to be utilized in more states, and more classrooms, you may be wondering how this affects your science classroom.

I participated in this very basic short training for NGSS, and had some discussion in this facebook group. Through that reflection I thought I had a beginning understanding of NGSS, at least how it is set up, and had some thoughts about how it would affect my classroom. I was waiting to see how the assessments worked, but felt that I had a pretty good start. 

 

Now, however, I am working on designing curriculum for a new course that that will be aligned to NGSS, and I found myself again confused and thinking through some of the issues surrounding it.

I wanted to write a post where I share with you a few of the main points that I am taking away, and hopefully open up some further discussion.

A little background on NGSS

Make sure you check out the NGSS website. It is pretty easy to navigate, and has sections on Understanding the NGSS. Two of the most useful handouts, in my opinion, were

• How to Read the NGSS
• NGSS Cheat Sheet (from the training, not the NGSS Website) 
• and The NGSS Fact Sheet (especially page 2) 

As you may have noticed right away, each standard is broken down into performance expectations (what students need to know or be able to do to demonstrate competence), framework dimensions, and then correlations to common core.

The NGSS draws from three dimensions. These are as follows:

• Disciplinary core ideas: our traditional content - subject matter
• Science and engineering practices: what may previously have been called science skills such as using models, planning and carrying out investigations, analyzing and interpreting data, etc.
• Cross-Cutting concepts: concepts and themes the cross many different science areas - such as patterns, cause and effect, stability and change, etc. 

These dimensions remain constant across grades P-12, but obviously go into greater depth at higher grade levels.

The NGSS are also correlated to Common Core, so they support math and literacy integrated into the science classroom.

These changes were made with a few larger shifts in mind. The shifts are:

• from isolation to integration
• from science inquiry to science and engineering practices
• from discrete science ideas to science and engineering crosscutting concepts

As we look at using NGSS in the classroom, it is not a complete departure from what we have been doing. These standards emphasize greater depth, problems solving, writing, engineering design and problem solving, and more progression through the grades. This is in line with teaching science as inquiry, using the 5 E’s, phenomena-based teaching, and many other good science teaching practices, but often takes it a step farther. As part of NGSS, these science and engineering practices and cross-cutting practices need to be taught more explicitly than we are used to doing. We may think that we are already teaching them, but in NGSS they get more emphasis as skills and content in their own right.

Here are a few of the ‘takeaways’ from our PD circle in the Facebook Group

Engineering design:

The biggest takeaways for me from this module were the embedded skills, and the process itself - collaboration, optimization, and revision, grit. I think it is important to explicitly teach these skills. A lot of projects, or even experimental design lend themselves well to this if we spend more time on the design process rather than giving students a step by step method, but teach them modeling and design skills. It’s not so hard to do, but a different perspective.

Cross-cutting concepts

I learned that it is important to “draw the concepts into the foreground”. We can (usually) easily recognize patterns or cause and effect but students really struggle with those relationships. Starting to use the terms with young children is exciting because much like a foreign language it will be easier to become more fluent in science and get to a deeper understanding of science content in middle and high school.

I do think it requires a re working of lesson activities and instructional formats. I know most of my stuff mainly reflects disciplinary core ideas. I have to work in the practices and concepts more and make more integrated performance assessments.

Focus on a few at a time and be intentional! Looking at the planning sheet our district made, it matches completely with this idea. So manageable! Also, I agree that we need to pull them into the foreground, like the depth and complexity icons.

Science and Engineering Practices

I learned that science is really a much more round about discipline, which is so different than what I’ve always learned and taught. I realized how much more integrated science should be, and that I should be talking about it like that in class. Doing science in class was completing rigid labs to achieve a desired outcome. I started off teaching that way, but have loosened up over the years to encourage students to create their own investigations. BTW, I much prefer the term investigation to experiment. It can include so much more.

I need to be much more intentional in pointing out the practices not only when we do them, but whenever the opportunities arise. I liked identifying them in the video and article.

The students need to talk, and they need to experience by learning.

Science is messy, and it is so good for the students to see this. It is hard to let go of control and fear that the students will not learn what they need to learn. It may take longer and be louder, but it is good for them! They might be wrong sometimes, but over a few practices, can correct misconceptions.

How to match up the standards to your curriculum

When trying to match up the standards to my curriculum I got a bit overwhelmed at first because of the different dimensions. After looking at some other resources, and talking to some colleagues, here are the conclusions that I came to:

The part I am correlating my curriculum to is the performance expectations at the top. There are much fewer of these than there were in our previous state standards, but they are broad and more comprehensive, so as you teach them, you are covering more content.

These performance expectations also lend themselves well to developing projects that would demonstrate competency in these areas.

One, or just a few performance expectations might cover an entire unit.

However, as you are teaching these, you want to keep the other dimensions in mind.

For example. When you teach the core disciplinary ideas, make sure that you are including some problem solving, engineering design, and cross-cutting science concepts. Also make those cross cutting concepts really clear and explicit

Where do I find examples of NGSS in practice?

As you are looking for NGSS aligned lessons and further resources, I put together a few websites that I found while searching:

• NSTA has an NGSS Hub that can be searched by grade level and core idea
• The Next Generation Science Website itself has some sample classroom performance assessment tasks. There is not a big library here, but growing, and they give good examples of how the different dimensions are integrated.
• If you prefer videos and examples, rather than lesson plans per se, The Teaching Channel has a “Deep Dive Guide to NGSS” and quite a few videos where you can see it in practice. 
• One of my favorites - since NGSS is focused on finding phenomena, and students acting as scientists to explain, I love this database of phenomena that can be searched by standard! 
• Lastly, although it may be a bit overwhelming, this concept map is a wealth of information on everything NGSS related! As I get further into NGSS, I definitely plan to explore it much farther!! 

I know some of you are way ahead of me in how your states are implementing NGSS. If you have insights or examples I’d love if you’d share them either here or in the facebook group.

Free, Engaging NGSS Aligned High Tech Resource For You

Free, Engaging NGSS Aligned High Tech Resource For You

If you are looking for a new and different, technology-rich activity to introduce students to a career in science, increase literacy in science, and practice using claim-evidence-reasoning (CER), I want to share a resource with you.

**Disclosure: This is a sponsored post, but all opinions are genuine and are my own.** #sponsored

I was asked to write a sponsored review of the UL Xplorlabs Fire Forensics Module, and I am very pleased to share it with you! I also asked my sixth grade son to go through it and give his feedback.

Xplorlabs has made two modules that are free, STEM-focused, and NGSS aligned. They have supplementary hands-on investigations that could be used in the classroom, and tie to both safety and real-world problems. I looked specifically at the Fire Forensics Module and found it very engaging, and found it to provide a fun, interactive online environment for students to learn from real scientists.

What is included in the Fire Forensics Module?

The Fire Forensics Module is an interactive web-based lesson that teaches about fire, but also teaches about building an evidence-based claim as students go through the process of being a ‘fire investigator in training.’ It is “designed to provide students with the understanding of fire, fire dynamics, and fire behavior so that they can read a fire scene and build a claim for the fire’s location of origin and cause.” It includes videos, embedded practice quizzes, a model where the students and instructors analyze the fire together, and then a culminating activity where the students analyze the fire themselves, from evidence, and then submit their analysis along with claim, evidence, and reasoning to their teacher or print it out.

The module is very well scaffolded, with short (1-3 minute) videos from current fire investigators, education on the fire itself, and on the tools used for investigation. There are interactive activities and self-checks, and also supplements hands-on activities that can be used (but it works fine without it as well).

The content covered focuses on the basic science of fire, and the fire investigation process itself, but they also use this as a lens through which to teach and practice claim, evidence, reasoning, and the scientific method. Depending upon the extension activities chosen, you could also use this to practice graphing.

As students work through this module, they are first introduced to the job of fire investigators and why it is important. They enter the ‘investigator’s academy’ and learn some background about how fire is defined, how fire develops, and how it behaves. They will then go through a ‘model’ fire in the lab, and then investigate a case and build a claim, based on evidence and reasoning.

What’s great about it?

I really liked this module, and would not hesitate to use it with students. The videos are short, engaging, and fast-paced. The website is very professional and easy to navigate, while still being kid friendly. There are self-checks built in and interactives to keep students on track. If students miss formative assessment questions they are given explanations, and then try the questions again before moving on. I really like that it integrates the career piece. This can be so important for students to just see what else is ‘out there’ and available to them as a career.

The whole module builds on itself seamlessly, and integrates supplemental activities if you choose. However, you could easily use only part of the module, and could include or omit as many of the extension activities as you choose. If, however, you do choose to include the extensions, they come with great teacher instructions, including materials list, roles, etc.

The whole module culminates with students solving a ‘case,’ establishing their claims, using evidence and reasoning to support it.

Feedback from my own middle schooler

This activity is geared towards middle school. I have taught middle school, but at the moment I’m teaching high school. I do, however, have a 6th grade son, so I asked him to go through at least some of the module and give me his feedback. He completed the first four sections during some free time. He liked it so much that he wants to go back and finish it, or check out the other module that they offer on his own! But he really liked the short videos, and the interactive charts in section 2 where you could modify the components needed for the fire and see how the fire changed (visually). He said he learned that the amount of heat, oxygen, and fuel changes how big the fire is, which he didn't know before. He thought all three had to be present, but didn’t know that the fire would change if there were different amounts.



He found the website easy to follow and thought the directions were very clear. He said he learned a lot, but the most interesting takeaway was that he had no idea there was such a job as a fire investigator. He said he could see his teachers doing this in science class, or even on a day where there is a sub because the students would be able to go through independently.

When would I use it?

As a teacher myself, I thought a lot about when I would use this activity. Some activities I’ve seen in the past are ‘fun,’ but really don’t fit with any curriculum. I think this one does, however. If you were teaching a forensics course, it is a natural fit, as well as a unit about careers. However, I think it would fit as a way to practice CER and using evidence. Because of the extension activities, it would be a good way to extend a unit on heat transfer, or even experimental design. Of course, it could also be a great activity to use with a sub, before or after the break, or any time you need to fill time. The module could take anywhere from two class periods to a week or more, depending upon how many of the extensions you use. There is one hands-on activity built into the module in Section 3 (Live Burns) after the video, at the top under the link 

There are also additional activities on their main website, under Xtensions.

Things to consider?

This activity is great, but there are two caveats to keep in mind, as a classroom teacher, and they are pretty simple:

If YouTube is blocked at your school, you may run into problems. The videos are beautifully embedded, and look like part of the website, but they are coming from YouTube and won’t work if YouTube is blocked. You may need to download these videos and show them together, or download and give students a separate link, but that will disrupt the flow of the activity.

The student’s responses on the final culminating activity, where they submit their claim, will get printed or emailed to the teacher, but the rest of the activity is self-guided. This would be fine for most students, and it is very straightforward, but depending on your student’s needs you may want to make some type of guided notes to go with it, so that students have a reference point when they get the culminating activity, and also have accountability.

What to do next?

So where to go from here? Try it out! Go here and check it out! If you do use it, I’d love to hear what you think either in the comments below, in my Facebook Group, or anywhere else on social media or email.