Hike with a Botanist

View of Iron Mountain from Cone Peak.

I don’t know what it is, but I love plants! You know, the ubiquitous, but easily overlooked green stuff. When plants arrived on the scene they literally changed the world! Nearly all life on the planet depends on plants for survival. And they are pretty, oh so pretty, What is not to love? 

Visions of wildflowers danced in my head as I drove out to meet with Linda Hardison, Botanist, and director of OregonFlora, at the trailhead for Iron Mountain and Cone Peak.  It was July 2nd—the perfect time of year to catch the wildflower show the area is known for.  Set aside as a Special Interest Area for botany, Iron Mountain and Cone Peak attract the attention of many adventurers looking for botanical inspiration. 

So I guess I shouldn’t have been surprised when I pulled into the parking lot at Tombstone Pass to find it rather full for a Thursday morning. Unfazed, with sunscreen, hat, and face mask in hand, I found Linda at the other end of the parking lot.  We quickly exchanged greetings, before hitting the trail.  

All set for a riotous romp filled with botanical delights, I was not disappointed.

Linda Hardison on the trail.

The Hike

  • Trailhead: Tombstone Pass Trailhead
  • Distance: 7+ miles
  • Elevation gain: approx. 1700 ft
  • Details: Amply parking and pit toilets at the trailhead. Trailhead is very accessible as it is right off Highway 20. You will need to cross the highway during the hike. Trails are well marked and maintained.

Plants Rule

Linda and I began our hike from the tombstone pass parking lot, heading down the trail toward Cone Peak. As we ducked down into the foliage and made our way along the trail that leads through some wet meadows, I immediately peppered Linda with questions: Why plants? Why study Botany? Why is botany important? 

O.K. so I was a bit excited. Linda was gracious with her reply.

“Well, just look around—it is just so beautiful,” she said. 

But in true scientist fashion, she elaborated, “Botany is at the core and foundation of everything. It’s what lets it all happen.” She went onto explain how flowers evolved this amazing ability to do photosynthesis—they capture sunlight and store it in organic molecules. These organic molecules are the basis of the entire food chain, feeding other living things, as well as enriching the soil for more plants to grow in. 

“The whole planet depends on plants,” she stated. From a humanistic standpoint, we need them to breathe, eat, and build with. They are so fundamental and they are everywhere. 

Plants are everywhere

This is the other amazing thing about plants! They are literally everywhere. “Plants have adapted to every condition on the planet,” explained Linda. Over millions of years, more and more species of plants have evolved and taken on different ecological niches, or roles, in the environment.  We now have entire communities of plants that live in forests; others in meadows; some grow in valleys, and others on mountains. Each plant with its own way of surviving in these different conditions. 

A Flora 

A whole planet to cover, there are a lot of different species of plants on Earth.  Too many for one blog post to focus on, but if we narrow it down to say— Oregon—the task goes from being impossible to overwhelmingly difficult  O.K. still too much for a blog post, but not too much for Linda and her Colleagues who are taking on just that within the OregonFlora program.

Linda shared some background on the project. The Oregon Flora Project was founded in 1994 by botanist Scott Sundberg with the goal of creating a new flora—basically a plant identification and information manual—for the state of Oregon. At the time the most up to date manual on Oregon plants was nearly 50 years old, so it seemed like an update was in order.  As Linda explained how plant populations change: “new plants are always being discovered; new species come in either as weeds or as climate changes and new habitats open up and they adapt to new places, and things go away, things get extirpated.”   

So with access to Oregon State University’s herbarium the project got underway. Currently, Volumes 1 is available and Volumes 2 & 3 are in the works.  OregonFlora also has a website chock full of botanical information (a massive overhaul is underway to make it more user friendly) and an application—Oregon Wildflowers App—that I personally love and use to identify plants while hiking. 

As for the plants themselves, OregonFlora has captured information on 4,762 different plants in Oregon. Talk about biodiversity!  

Ecoregions 

The diversity of plants in the state makes a lot of sense when you think about the diversity of ecosystems and habitats that exist in Oregon.  The state of Oregon is somewhat unusual in that it has many different ecoregions—large areas of the state with similar climate and vegetation. From the cool, wet Oregon Coast Range to the hot, dry Basin and Range—Oregon has been cut to shreds ecologically. 

OregonFlora uses the ecoregion concept as a frame of reference as well—recognizing 11 different ecosystems that largely parallel the EPA designated ecoregions in Oregon. Plant communities can be organized within this framework and then further subdivided further into habitat preferences from there. 

Linda told me that when she gives presentations about OregonFlora, she will put up a picture of open scrub and grasses and ask people where the picture was taken? “And people will say eastern Oregon,” said Linda. Then she will put another picture up and the audience is right again. “I think people really have a gestalt about this sort of stuff,” explained Linda. People recognize the combination of physical and biological attributes that make up a place. And OregonFlora is there to help them simply hone their awareness.

What’s in a name?

As the trail really started heading uphill, Linda brought up another botanical topic of importance—naming.  One of the big jobs of OregonFlora, and a big part of botany as a whole, is figuring out what to call a species. Naming is important because 1) they allow scientists to be precise when they are talking about plants, and 2) because they reflect the evolutionary relationship between plants. As simple as this sounds things can get a bit complicated. 

During the 18th century, Carl Linnaeus, often considered the father of taxonomy, first came up with the binomial, two name system that is, for the most part, used today. According to Linda, his system grouped organisms by morphological characteristics, especially reproductive features. At the time, these features were considered immutable because they were so important to the survival of a species. However, with the advent of DNA sequencing, we now have more complete information about how organisms are related.  We can see in the DNA evolutionary relationships that don’t necessarily match up with the optics.  

So names have changed. And scientists have had to adjust. “Botanists can take care of this,” said Linda by using synonyms. Botanists keep track of and acknowledge synonyms—old, out of date scientific names—as part of their records of each species. 

Linda pointed out some false Solomon’s seal. Once Smilacina racemosa it is now part of the maianthemum genus with the scientific name: Maianthemum racemosum

False Solomon’s seal (Maianthemum racemosum)

Not so Common

Then of course there are common names, like false Solomon’s seal.  OregonFlora also keeps track of common names.  Linda said they look for the most widespread names for each species in the region to include in the flora. Choosing regionally significant names of species is important as there can be great variability region to region.  For example, OregonFlora’s emblem is what most Oregonians call a fawn lily, but in other parts of the country, the same species is known as a dogtooth violet. Though these names don’t provide precise information about the plant, they do provide regional and cultural context to the botanical world.

Taxonomic Concept

But the division of plants doesn’t start and end with a name (or two or three).  As Linda puts it, “the isness of a plant” must be determined. The isness of a plant—its characteristic features and range—is what is known as a taxonomic concept. So considering our false Solomon’s seal the taxonomic concepts answer the questions- What is a false Solomon’s seal? It breaks it down and “puts a circle around it.” A name doesn’t mean a whole lot if it doesn’t have a specific plant associated with it. 

Taxonomic concepts might be species specific or subdivided further into varieties or subspecies. Linda said, “We try and get down to as small a bucket as we can.” We talked about the example of the species Pinus contorta.  The variety of this species that grows on the coast takes on a twisted, gnarled shape, but the variety that grows in montane environments is narrow and upright. 

Determining a taxonomical concept for a plant is challenging because there is natural variation in plants as well.  Genetic biodiversity that makes one member of a species different from another member of the same species can sometimes blur the lines and create some controversy or debate. Also, things are always in flux.  Whether it is through scientific work or natural processes, taxonomic concepts can and do change. 

Forest Habitat

By this point, Linda and I had hiked up out of the meadow and into the forest. Conifers dominated the overstory— Douglas-fir and hemlock primarily, but also some true fir and western red cedar. The understory was shaded, and the soil rich in organic matter and moisture captured by the trees and the fungal network below. Plants like vanilla leaf, wild rose, wild ginger, thimbleberry, bunchberry, and vine maple, took up residence in this protected understory. 

It is the combination of physical and biological features that create “the magic mix” for a habitat, explained Linda.  You can’t rely on physical features alone to determine what lives where.  As important as factors such as light, temperature, and moisture are, the other plants, animals, and microbes that live in the same community are just as (if not more) important.  That is why you can travel to places that share physical features, Linda explained, and find a completely different suite of organisms. 

Forest habitat from the trail.

It takes a Community

I asked Linda to elaborate on the importance of community connections. She was clear—we still have a lot to learn when it comes to relationships between species. We have an inkling that these connections are important, but “we don’t know what makes everything work together,” she said.

In terms of the forest, for example, we are just starting to learn about the importance of fungal communities in communication and the exchange of nutrients. Linda said that she knows a landscaper who will save the “duff layer” of an area before it is bulldozed for development so he can reuse the material later. 

Natural and wild places are just that important. “We don’t know what sort of glue some tiny little scrubby looking plant might serve in the big picture,” said Linda. “If we view things as a system, as a whole, I think there are much richer opportunities to learn and explore and benefit from than from looking at one isolated species.” 

Botany Rocks

Eventually, Linda and I stepped out of the trees and out onto a rocky outcrop to be greeted by a gorgeous wildflower display—the first of many. Bright yellow Oregon sunshine, deep purple larkspur, and bright blue gilia were all at peak bloom! We gawked at the beauty of the place—bright spots of color and fragrant smells overwhelmed our senses. 

First rocky outcrop we saw on the trail.

Adapt 

However, perhaps even more fascinating, is that these plants exist here at all. Living in a harsh environment with little moisture, very little soil, and a lot of snow and sun—these plants were not here for our benefit, but because they had adapted over generations of time to these conditions. 

Adaptations are characteristics that allow a species to survive and reproduce in their environment. Adaptations arise over multiple generations of time through the process of evolution by natural selection. Though it is impossible to observe this process on a hike, adaptations are readily observable. 

Linda and I speculated on some of the adaptations observable on our rocky outcrop. We noted how stonecrop and a species of claytonia both had fat fleshy leaves used to retain moisture. Cat’s ear lily uses a bulb for storing resources for the long winter. Blue gilia was prolific—adapted by living an annual lifestyle—producing a lot of seeds before dying off. Rough paintbrush, a hemiparasite, takes advantage of the company of others, stealing water and nutrients from their neighbors. Then there were the bright colors and fragrant smells of many of the flowers—all adaptations for attracting pollinators quickly during a short growing season.  

Blue gilia growing on the rocky outcrop along with larkspur and yellow monkey family.

Family Ties

As you can imagine, walking among the rocky outcrops the diversity of plants was captivating. We continued along the cone peak trail, stopping to admire, identify, and take photos along the way. 

At one point while discussing a species of buckwheat (Polygonaceae), Linda shared with me her secret to identifying plants. She said that one of the best ways to learn (for her anyway) is to look at the relationships—the family of plants. “It gives you the start on what something is,” she said. “If you learn the characteristics of a family, it opens the first door.” Then you can use a field guide or an app to narrow things down. 

The buckwheat family, for example, typically has lots of very small flowers and colored or no sepals. Asters (Asteraceae)—the largest family—tend to look like sunflowers with very open blooms that are attractive to pollinators. Oregon sunshine is a great example. Some relationships are surprising and a little more challenging. For example, Larkspur is in a subclass of the buttercup family (Ranunculaceae).  Characteristic of this subgroup are the fruits or “follicles”— capsules that open along a single side. In general, one way to recognize buttercups is to look at the fruit. 

Arrowleaf buckwheat (buckwheat family), Oregon sunshine (aster family), and purple larkspur (buttercup family).

Botanical Controversy 

One “family” of plants that I personally enjoy are the penstemons. I asked Linda what characteristics are common among penstemon.  She told me that they typically have “snapdragon looking flowers” and that the common name for the family actually used to be snapdragon (Scrophulariaceae). However, according to Linda, the “scroph” family is a classic example of “plant families gone amuk.”  As botanists have grown to better understand evolutionary relationships, the family has actually been split into five different plant families!  According to Linda, this change sparked a lot of frustration, as people had been trained (like herself) to identify these plants as “scrophs.” She admitted that she still often gets these plants mixed up. Botany is not without its challenges. 

Deadly Problem

Identifying plants is not only a lot of fun, but really important if you spend any amount of time outside. Plants can act as irritants and toxins.  Most people are aware of plants like poison oak and poison ivy, but there are many other plants that can cause problems. Giant hogweed, for example, can induce photosensitivity in people that touch it.  

On our hike, Linda and I ran across several stands of death camas. Death camas is lily-like in the false-hellebore family (Melanthiaceae)—characterized by parts in groups of three—but many people confuse it with real camas, also a lily, and an edible plant. The problem arises from the fact that they can grow in similar environments and are harvested as bulbs that can be hard to tell apart. Being attuned to the differences between these two plants is literally life or death. “Plant families gone amuck”

Stand of mostly death camas with larkspur and paintbrush.

Microhabitat

As we finally reached the sloping top of Cone Peak, Linda and I noticed some areas of land that looked a bit different from the rest of the bloom area. The mix of species was a bit different, with certain species more abundant, while others less abundant—more moss and grass especially. Even the physical characteristics looked different—more rocky and dry; the site also looked like it might have been more recently disturbed.  

Whatever the specific reasons, this was an excellent example of a microhabitat. Even within a defined habitat, there is small scale variability that can alter plant communities. According to Linda, understanding microhabitat is really critical for planting projects and restoration work. It is also something we still don’t know a lot about.

Honing our awareness for microhabitats is also a fun way to think about botany while on a trail, with the potential to contribute to a collective body of botanical knowledge. 

Unusual section of Cone Peak bloom— rocky microhabitat.

Drawing Connections

Speaking of fun ways to interact with plants, one of the goals of OregonFlora is to encourage people to engage with botany.  This is also one of my goals in writing this post.  There are, of course, a lot of ways to do so (some already mentioned in this post), but as we hiked from Cone Peak to the Iron Mountain trail junction, I asked Linda what she thought someone might do to develop a botanical eye. 

Linda’s advice was to first—“stop and look.” And second—draw! Drawing is a great way to pay attention and notice details that you might not notice from a glance or even a picture.  

Take some time to stop and sit down with a plant, suggested Linda. Pay attention to the sites and sounds. Look at what is covering that ground and what makes up the overstory.  “Understand this is a community: and who is a part of it, and who the big players are and who are the quiet voices,” said Linda. 

More blooms on Cone Peak.

Ethnobotany 

At one point, as we headed down the trail, Linda noticed a nondescript plant, a biscuitroot (Lomatium). She pointed out that indigenous people in Oregon often collected biscuitroot tubers as a food source.  The ethnobotanical aspect (or traditional use) of plants is another way people can relate to plants, Linda surmised. 

The Summit

Finally, we reached the trail junction for the iron mountain summit and we decided to make the ascent.  And after huffing and puffing our way by many more wildflowers, we reached the top and some amazing views of the Cascade Peaks. 

But the mountains were not the only thing in view.  Linda pointed out, as we looked out across the landscape, the diversity of the plant life that, though we couldn’t see the details of, blanketed all surfaces.  Old and new forests, open meadows, riparian corridors, and landslides—the view was awash in greenery.  

View from the summit.

As we made our way back down, more quickly than we went up, we continued to chat about plants and education, equity, and web design, among other topics. Our conversation shifted from topic to topic, almost as quickly as the plant communities changed as we moved down the mountainside—a dizzying array of botany.

So what is the takeaway? What did I learn from my hike with a botanist? Well to sum up: we are just a single species living in a world dominated by plants. So, as the saying goes, take time to stop and smell the roses.

Linda Hardison is a research assistant professor in the Department of Botany and Plant Pathology at Oregon State University and is the director of OregonFlora. She received undergraduate degrees in botany and marine biology from the University of Texas, and a Ph.D. in botany from the University of Washington. She currently serves on the board of the Native Plant Society of Oregon.

Resources

  • http://www.oregonflora.org
  • Meyers, S.C., T. Jaster, K.E. Mitchell & L.K. Hardison. 2015. Flora of Oregon. Volume 1: Pteridophytes, Gymnosperms, and Monocots. Botanical Research Institute of Texas, Fort Worth, TX.