“Constitution Gardens will become a biodiversity hotspot on the National Mall,” said Adam Greenspan, FASLA, design partner at PWP Landscape Architecture. “We will create a garden, based in nature, while respecting the historic design.”
Constitution Gardens in Washington, D.C. opened in 1976 to commemorate the bicentennial of the American revolution. Concepts outlined in the McMillan Plan and designs by Dan Kiley and SOM shaped the landscape.
But over the past forty years, the gardens fell into disrepair and became a pass-through site on the way to other more popular destinations on the mall.
Now, the second phase of a three-phase plan to revitalize the garden has been approved by the Commission of Fine Arts and National Capital Planning Commission. The design by PWP Landscape Architecture and Rogers Partners Architects will create a “new ecological landscape” designed for people and hundreds of plant and animal species.
Phase two, which is expected to begin later this year, will redesign the 6.75-acre lake at the heart of the landscape, and create 2.5 acres of new meadows and woodlands that will together function as a natural system.
“The current concrete-lined lake is ecologically dysfunctional,” Greenspan said. “We are rebuilding the lake as a healthy living system.”
PWP will deepen and widen the lake and replace the concrete bottom with clay. A diverse range of aquatic plants will help clean the water and ensure the lake becomes a habitat for fish, frogs, and birds.
PWP envisions such a healthy lake that fly-casting will be possible from a new lake ring, a circular pathway. The interior of the ring will also be a spot for model boating.
The landscape surrounding the lake will be designed to act as part of the water cleaning system.
New soils will be brought in to replace the highly compacted existing soils. Nearly half of the lawns, which don’t add any ecological value, will be replaced with native meadows and woodlands. In these new woods, 478 trees will be planted.
The trees and meadows will feature 124 species. “We are planting a highly diverse palette that will shift and change over time.”
With new soils, meadows, and trees, all the stormwater that hits the site will be captured and filtered, and then circulate into the lake. “The bioinfiltration system, above and below the surface, will leverage plants, soils, bacteria, and animals to clean the water before it enters the lake,” Greenspan said.
The system is expected to filter more than nine million gallons of water a day.
An upcoming phase three of the project will include a new pavilion with event spaces; expanded woodlands; and new connections to surrounding streets.
Greenspan argues that the new soil is critical to the success of the project. In 2011, they found half of the original trees on site had failed to thrive and been removed. And since another survey in 2014, another 30-40 percent have gone. “The site is currently inhospitable to plant life.”
“We need healthy soils to create a healthy tree canopy, which can then provide shade to cool the landscape.” The new trees will also shade the lake, chilling the water and adding to the site’s overall cooling effect in D.C.’s increasingly hot summers.
While there is an embodied carbon cost to trucking in acres of new soils, “this is not a place where we could use the very degraded, compacted soil, which is mostly rubble.”
There are trade-offs. The carbon emissions released from soil construction enables the increase in biodiversity and long-term carbon storage and climate resilience of the site.
Pamela Conrad, ASLA, at COP28 / Kotchakorn Voraakhom, International ASLA
New role advances research on nature-based solutions
By Lisa Hardaway
ASLA announced a two-year fellowship with Pamela Conrad, ASLA, PLA, LEED AP, founder of Climate Positive Design. As ASLA’s inaugural Biodiversity and Climate Action Fellow, Conrad will research landscape architecture strategies that are most effective in addressing the climate and biodiversity crisis, with a focus on underserved communities in the U.S. and worldwide.
“With Pamela’s expertise, we will be able to provide more in depth guidance and examples of successful nature-based solutions designed by landscape architects around the globe,” said Torey Carter-Conneen, CEO of ASLA. “To make the strongest case to decision-makers, it’s important we have the research to back up the solutions we know have a positive impact. Landscape architects play a vital role in addressing the twinned climate and biodiversity crises, because of their work with plants, land, water, and construction materials.”
“I am honored to participate in ASLA’s inaugural Biodiversity and Climate Action Fellowship. This builds upon our strong working relationship over the past several years. I am eager to advance more accessible nature-based guidance for all, particularly for underserved communities. It is my hope that this work elevates the awareness of the profession globally and scales-up our positive impacts around the world,” said Conrad.
Conrad is an internationally celebrated landscape architect. She founded Climate Positive Design to improve the carbon impacts of the exterior and natural environment projects while increasing social and ecological benefits. She is a faculty lecturer at Harvard Graduate School of Design, an Architecture 2030 Senior Fellow, the vice-chair of the IFLA Climate and Biodiversity Working Group, a member of the World Economic Forum Nature-Positive Cities Task Force, a 2023 Harvard Loeb Fellow, and was a Landscape Architecture Foundation Fellow for Innovation and Leadership. In addition, Conrad was principal at CMG Landscape Architecture in San Francisco, where her work included helping the Port of San Francisco plan for sea level rise along its downtown waterfront.
ASLA’s Climate Action Plan calls for all landscape architecture projects to accomplish the following goals by 2040:
Achieve zero embodied and operational emissions and increase carbon sequestration
Provide significant economic benefits in the form of measurable ecosystem services, health co-benefits, sequestration, and green jobs
Address climate injustices, empower communities, and increase equitable distribution of climate investments
Restore ecosystems and increase and protect biodiversity
Conrad will work in partnership with ASLA’s Senior Manager of Climate Action, a newly dedicated role for Jared Green, Hon. ASLA, a veteran of the profession with deep knowledge of nature-based solutions.
Conrad’s fellowship will build on the ASLA Fund’s research into landscape architecture solutions to extreme heat with Dr. Daniella Hirschfeld, ASLA, PhD, Assistant Professor of Climate Adaptation Planning in the Landscape Architecture and Environmental Planning Department at Utah State University; and landscape architecture strategies to reduce biodiversity loss with Dr. Sohyun Park, ASLA, PhD, Assistant Professor, Department of Plant Science and Landscape Architecture, University of Connecticut.
You have said the dangers of the biodiversity crisis are equal to or even greater than the climate crisis. Can you elaborate?
If we stop emitting carbon dioxide, climate change could be stopped or reversed. But if we lose species, they’re gone forever.
We’ve seen species extinction and the degradation of ecosystems proceed at a rapid pace. We’re losing species at a rate of about anywhere from 100 to 1,000 times faster than the background rate, based on previous extinctions. Addressing climate change will remove one threat to biodiversity, but it won’t stop its decline. If we fix climate change tomorrow, we still are dealing with a massive degradation of nature and biodiversity.
Nature is infinitely more complex than a molecule of carbon. We’re coming up with ways to deal with carbon. But nature is more complex, so we’re still learning a great deal.
When we lose ecosystems or genetic diversity, that impacts our ability to survive as a human species, not to mention all the other more-than-human species that inhabit the planet with us. The food we eat, the air we breathe, the water we drink, the medicines we use are all directly related to nature. If we lose nature, we’re going to severely impact all the things that keep us alive and thriving.
While we look to the sky trying to figure out what to do with climate change, nature is being pulled out right from under us.
Conserving and managing at least 30 percent of the world’s lands, inland waters, and coastal areas is something we’re directly involved in and we take to heart every day.
The targets include four overarching goals, including: the “integrity and connectivity and resilience of all ecosystems are maintained, enhanced, or restored, sustainably increasing the area of natural ecosystems by 2050.” This is where landscape architects can have the greatest impact. We’re all involved and can help make sure this goal is met.
The 23 targets can be put into four categories. One is on-the-ground action targets. The other is policy initiatives. The third is financing and capacity building. The fourth deals with inclusion and equity.
At Biohabitats, we’re really focused on the on-the-ground actions. That’s conserving habitat and species. It’s restoring ecosystems, managing invasive species, and adapting and mitigating to climate change. We deal with these on all our projects. But you can’t think of any of these global targets independently. They’re all connected to one another.
Our work also falls into the inclusion and equity batch of targets. We think about Indigenous peoples, communities of color, and underserved communities and make sure these communities not only participate in the work we do, but have the ability to make decisions, deciding what’s going to happen in their neighborhood, communities, and on their land with their consent.
How can landscape architects better design projects to achieve the 2030 biodiversity targets? What are the top three actions landscape architects can take to increase biodiversity in their work?
First, protect and conserve the biodiversity within your sphere of influence.
Second, restore biodiversity, which can take many forms. Look at how the site is connected to the rest of the landscape from a landscape ecology perspective. Seek to understand how nutrients cycle and flow through the site, how water interacts with the site, how species move across the site or inhabit the site, and how that’s all connected to the regional landscape. It’s really hard to increase biodiversity on a site if we don’t understand these connections and relationships.
Third, once you have an idea of what you’re going to protect and conserve, develop ideas and ways to restore and enhance biodiversity. This can take the form of many different strategies and measures.
Landscape architects have a tremendous influence and impact on the way biodiversity is protected, conserved, restored, and enhanced.
Biodiverse landscapes provide a range of ecosystem services, including carbon sequestration. But with growing climate impacts like wildfires, landscapes can also become major sources of emissions. Biohabitats analyzed the carbon storage capacity of a fire-prone landscape for the City of Boulder, Colorado. What did you learn?
We were commissioned by the City of Boulder to look at whether their annual carbon sequestration in their open spaces and mountain parks would help them offset the carbon they emit as a city. We inventoried the carbon stock, and annual flux of their landscape, and projected what the loss may be based on fire or another land disturbances, and what the landscape’s potential is in terms of sequestering carbon under a changing climate and with the application of nature-based solutions.
We looked at over 36,000 acres. We found these lands had a really large existing carbon stock. 2.8 million cubic tons of carbon were already being stored in those landscapes.
Map illustrates areas with the greatest carbon density based on soils and landcover. Biohabitats. City of Boulder Open Space and Mountain Parks. Sustainability Solutions Group / Biohabitats
The grasslands had the greatest existing carbon storage, mostly in their soils. Wetlands actually had a greater carbon density per acre, but they cover relatively small areas. While the forest and grasslands can store significant amount of carbon in the landscape, our modeling of fire scenarios found that they were also a potential source of carbon emissions due to the risk of loss under certain scenarios.
We found that nature-based solutions could help draw down carbon and reduce loss. For example, prescribed burning can be used to improve landscape resilience. Because when fire-evolved ecosystems aren’t burned, the fires burn with more intensity and typically burn the soil as well. With frequent fires, you get less intensity, and they produce less carbon emissions.
This fell in line with other studies around the world. It also emphasized why developing or tilling greenfields is destructive in terms of carbon emissions. Protecting and conserving wild lands and parks is really important in reducing carbon emissions.
To the untrained eye, some of your firm’s projects look natural, like nothing has been done. Your beautiful project at Teaneck Creek Park in Bergen County, New Jersey, restored 46 acres of freshwater wetlands. Big Marsh Park on the South Side of Chicago restored a dumping ground and treats wastewater, but looks pristine. Is that one of your measures of design success — for your work to read as nature?
A quick story: We worked on a stream and riparian restoration project in Columbia, Maryland, which sits between Baltimore and Washington, D.C. in the 1990s. A reporter contacted us and said “I want to go out and take some pictures of the site you restored.” We told them where it was, and they went out. We got a call the next day saying they couldn’t find it. They were standing exactly at the point where we did the restoration.
With a lot of our restoration work, we hope it blends back into the existing landscape. But it goes a little bit deeper than that. We think about how to restore ecological processes, like food webs, hydrologic or nutrient cycles, ecological succession or disturbance regimes like fire. That’s what we focus on, not necessarily what the landscape’s going to look like.
It’s really place dependent. Every place has these processes, but they operate at different levels, scales, complexities, and relationships. A long grass prairie, an eastern deciduous forest, or a Gulf Coast tidal wetland are different. We’re trying to first understand those processes and design to protect, restore, enhance them.
If we start doing that, then that manifests itself into what the landscape is going to look like; what the plant community is going to look like; how water flows through, over, under the site; how species interact with the landscape; and how the site evolves. We’re trying to mimic ecosystem processes within landscapes that are relatively stable and intact. Much like architects or landscape architects use precedent images, we use reference landscapes.
Sand seepage wetlands at Teaneck Creek Park provide stormwater attenuation and water quality filtration while enhancing local biodiversity. Biohabitats. Bergen County Dept. Of Parks. Teaneck Creek Conservancy. Rutgers’ Center for Urban Environmental Sustainability / David Ike PhotographyTeaneck Creek Park. Biohabitats. Bergen County Dept. Of Parks. Teaneck Creek Conservancy. Rutgers’ Center for Urban Environmental Sustainability / David Ike Photography
For us, there’s an inherent beauty in natural systems. We’re trying to create the building blocks that allow natural systems to regenerate. For a landscape to be sustainable, robust ecological processes need to be in place. Otherwise, the system is going to fall apart.
The Ford Calumet Environmental Center in Big Marsh Park, designed by Valerio Dewalt Train, is home to Chicago’s first decentralized wastewater treatment and disposal system. The system, designed by Biohabitats, includes constructed wetlands, which demonstrate environmental stewardship while serving and improving access to nature. Biohabitats. Chicago Park District Valero Dewalt Train Associates. DbHMS Engineering. Jacobs/Ryan Associates / Tom Harris
We also work in highly disturbed landscapes that are disconnected from natural processes — for example, brownfields or high-density urban areas. While our goal is to restore the full suite of ecosystem processes and functions, many times we are quite limited in what we can do.
Scientists are calling these novel ecosystems. It’s the idea that we can use these reference landscapes as an analog but knowing that we’ll never be able to replicate many of the ecological processes that sustain these landscapes. What can we restore that has a semblance of ecological integrity and provides value to the life of that landscape? That’s where we begin.
It goes back to our tagline: “We’re in the business of restoring the future, not the past.” We can’t go back to the past because there have been so many changes to our landscapes, ecosystems, and planetary systems. We need to look forward.
Your firm works with the Army Corps of Engineers, which has a large contingent of landscape architects. What do you think that the Corps needs to do to fully realize its vision of Engineering with Nature?
We’ve been working with the Corps of Engineers for almost 30 years. I will give a shout-out to Dr. Todd Bridges, who, with his cohort of researchers and other practitioners, developed the Engineering with Nature initiative while he was at the U.S Army Engineer Research and Development Center (ERDC). Todd is now with a team of researchers at the University of Georgia, working in collaboration with the Corps and others to advance the idea of nature-based solutions for infrastructure projects all over the world.
In 2022, the ERDC contributed to The White House roadmap for accelerating nature-based solutions. This roadmap lays out five recommendations that the Corps and all federal agencies need to do. For the Corps, this will require Congress to change Corps policies, reallocate funding, and shift priorities. It’s not that the Corps is necessarily trying to make things more difficult or put-up roadblocks. Literally, they can’t do many of the changes we want to see or do until Congress gives them authorization. It’s up to all of us to advocate to our representatives in Congress to make these changes happen.
For example, the Corps has specific guidelines on how they evaluate project alternatives, which give overwhelming preference to damage reduction and business loss reductions. These are worthy benefits, but for the most part they completely ignore ecological and social benefits. It’s hard for the Corps to justify the use of nature-based solutions if the benefit is not quantifiable.
But just this past February, the Corps released a final rule to change that policy. If this rule is adopted, the Corps will be able to develop project alternatives that maximize environmental and public benefits. This allows both quantitative and qualitative data to be used in determining the highest benefit to lowest cost ratio. This alone will accelerate the application of nature-based solutions and aesthetic and context sensitive design considerations in infrastructure projects throughout the country. This could be a game-changer.
Your firm also integrates nature into dense urban environments, like a green street in downtown D.C. How do these small projects provide opportunities to increase biodiversity?
We’ve been working with the Golden Triangle Business Improvement District in D.C. for several years. We’re designing and retrofitting bioretention facilities into the streetscape. Obviously, as landscape architects, we are excited to see bioretention as a stormwater quantity and quality management system being designed and installed all over the world.
The idea of bioretention was developed by Larry Coffman in Prince George’s County, Maryland, a suburb just outside of Washington, D.C. in the early 1990s. Biohabitats was fortunate enough to have worked with Larry on that research, the design specifications, and proof of concept for the very first bioretention facilities in the world. So, this is sort of the homecoming for us.
Stair-stepping bioretention cells provide opportunities to showcase native diversity in the Golden Triangle neighborhood of Washington, DC. Biohabitats. Golden Triangle Business Improvement District. DC Department of Energy & Environment. Triangle Contracting. TCG Property Care. Timmons Group Insight LLC / Biohabitats
There are many benefits. Bioretention systems improve water quality by removing pollutants through soil microbes and uptake by plants. They infiltrate stormwater into the ground and help replenish groundwater. They reduce runoff off from impervious surfaces, particularly when designed with trees. They help reduce the heat island effect. And they also provide micro-habitats for pollinator species and migratory song birds, among other species. Bioretention facilities are wonderful ways to benefit nature and biodiversity in urban areas.
Lastly, in 2023, Biohabitats transitioned ownership from being a privately-held company to a perpetual purpose trust, much like Patagonia did. How did you decide this was the best way to achieve your long-term goals for your team and the planet?
Yes, on Earth Day, 2023, Biohabitats sold all its shares to the Biohabitats Purpose Trust (BPT), which is a non-charitable trust with the explicit purpose of “restoring nature, protecting and conserving biodiversity and inspiring love for wild places.”
I began looking a different options for ownership transition about seven years ago. I looked at selling Biohabitats to our team members, another firm, or private equity. I also considered an employee stock ownership plan, a co-op, and a variety of hybrid business models. Eventually, I came across the concept of a perpetual purpose trust through a business group I belonged to. The idea of locking in our purpose and mission in perpetuity really appealed to me and our team.
With the BPT, Biohabitats’ purpose, mission, and values are locked in for the next 100 plus years and cannot be bought or sold. Under the BPT, Biohabitats operates as a for-profit company trading as C-corporation, with a Benefit Corporation overlay. We are also B-Corps certified, a JUST company, and 1% for the Planet Member. The profits Biohabitats earns are no longer extracted by shareholders, because the BPT is the only shareholder and doesn’t need profits. Instead, profits get reinvested back into our team members, stakeholders, and nature.
The BPT is governed by a board of trustees within the Trust Earth Stewardship Committee, which is responsible for making sure that Biohabitats is meeting its purpose and objectives. There are five seats on this stewardship committee, and we have designated and legally codified one seat for nature. Nature, represented by a nature guardian, has a seat at the table and more importantly, agency in making sure that Biohabitats is meeting its purpose and objectives. We believe it’s the first time in the U.S. that nature has been legally assigned as trustee. For the wild!
Lacasse outlined practical strategies landscape architects can apply to reduce the carbon footprint of parks, plazas, residential communities, and other landscapes.
A landscape’s footprint depends on how much concrete, steel, aluminum, and other carbon-intensive materials it incorporates. These materials create high amounts of embodied carbon in comparison with other materials, like wood, which store carbon.
“A highly active urban plaza will have lots of hardscape,” Lacasse said. But designers can still find ways to minimize hard surfaces and structures to reduce climate impacts.
One tool for figuring out how to cut these materials is Climate Positive Design’s Pathfinder. It shows landscape architects the carbon impacts of the materials they choose for a project.
To get there, Lacasse said landscape architects should cut unnecessary concrete surfaces and swap in decomposed granite, local stone or wood pavers, or recycled materials.
Conventional asphalt, which is commonly used in streets and trails, can be swapped for pervious asphalt, which is lower in carbon. Existing asphalt can also be cut and reused.
Reducing high-carbon materials overall provides benefits. “We can rethink our designs. Do you need a 10-foot-wide concrete or asphalt path, or can you make it 5-feet-wide and add decomposed granite to the edges?”
10-foot-wide path and a 5-foot-wide path alternative / LPA Design Studios
“Instead of a concrete seat wall, design a wood one. Instead of concrete retaining walls and terraces, slope the grade,” she said.
Reducing materials with high embodied carbon is one step for reducing emissions from landscape architecture projects. The other side is significantly increasing the amount of carbon stored in a landscape. If the amount of carbon sequestered is more than the amount emitted by its construction or operations, it’s climate positive — a net carbon sink.
Biodiverse landscapes, with layers of trees and understory plants, store more carbon. But maximizing carbon storage in a landscape is complex. “We look at the growth speed and life span of trees and plants, the planting strategy, how to weave in biodiversity,” Lacasse said.
Biodiverse landscapes store more carbon / GGLO
Trees, plants, and soils all store carbon but at different rates. “Evergreen trees have a faster carbon absorption rate. Deciduous trees have larger canopies and denser wood so they store more carbon, but their absorption rate is slower.”
Carbon storage in evergreen and deciduous trees / GGLO
Large trees store more carbon than smaller trees, so it’s important to keep existing trees whenever possible.
Carbon storage by tree age / GGLO
For a new two-acre community in Seattle, with community gathering places, playground, and a creek, GGLO first created a design using conventional concrete, asphalt, and metal play equipment (see images at top).
Using the Pathfinder tool, they found the site would take 92 years to become climate positive. That is how long it would take for the carbon stored in the trees, plants, and soils to be greater than the carbon emitted through the site’s materials and construction.
But with some changes to the design — including recycled asphalt and concrete; bamboo decking; and wood seatwalls, play structures, and surfaces — it could take 32 years to reach climate positive, a decrease of 60 years.
“We can’t manage carbon without measuring it. These tools can make designers feel empowered,” he said.
From his work with the tools, he found that “the decarbonization potential is higher with hardscapes. Reducing the use of these materials is better than pumping up planting. You can’t plant the heck out of a project to offset embodied carbon. Reduce first and sequester second.”
And Mariana Ricker, ASLA, an associate with SWA, explained how landscape architecture firms can weave carbon considerations into their internal design workflow. “It is just another layer in the process.”
To make that workflow clearer, SWA developed its own decarbonization guide. “We use it to advocate to clients, empower our designers, and prioritize. Not all projects have the same carbon potential.”
She urged landscape architects to carefully consider the materials they select for projects. “It’s important to be as low carbon as possible upfront.”
“When a material has been produced, those embodied carbon emissions are in the atmosphere. We have a limited time span with the climate crisis. Reducing emissions must be our priority. Sequestration happens later, over time.”
Protected bike lane in Buenos Aires, Argentina, Buenos Aires / FotografiaBasica, istockphoto.com
Transportation accounts for a third of global greenhouse gas emissions. Of those emissions, 90 percent is from road vehicles. And approximately half of those emissions are from passenger cars.
Infrastructure that gets people out of cars and provides a safe, accessible way to bike and walk is a key climate solution. But it’s still not high on the global climate agenda.
At Transforming Transportation in Washington, D.C., government and non-profit leaders explained how they are trying to elevate active transportation in climate discussions.
The Netherlands, one of the world’s biking superpowers, seeks to promote cycling and walking on a global level. At COP28 in Dubai, they launched the ACTIVE Program, creating a global financial fund to increase investment in bike and pedestrian infrastructure.
Kees van der Berg, vice minister of mobility and transport at the Dutch Ministry of Infrastructure and Water Management, said the program aims “to train 10,000 experts worldwide in biking and walking infrastructure in ten years.”
The Netherlands and other major donors and financial institutions are also trying to further demonstrate the economic benefits of bike and pedestrian infrastructure that landscape architects design.
“Biking is a cost-effective way to reduce greenhouse gas emissions. Active mobility programs make perfect economic sense if you look at their climate, health, and financial benefits,” said Nicholas Peltier, transport global director at the World Bank.
He pointed to research from the Institute for Transportation and Development Policy (ITDP). Their recent report found large-scale bike infrastructure, spanning hundreds of miles in cities, creates significant returns on investment. Looking at five leading cities — Tianjin, China: Buenos Aires, Argentina; Lima, Peru; Addis Ababa, Ethiopia; and Dar es Salaam, Tanzania — ITDP found returns range from 50 to 100 percent.
Building safe, accessible bike infrastructure also spurs on more bike use, said Rogier van der Berg, with the World Resources Institute (WRI).
Sometimes, in addition to providing the infrastructure, cycling can be boosted with public awareness campaigns. In Turkey, “riding a bicycle had a stigma — that you were poor. We worked with local non-profits to change that,” van der Berg said.
According to Filip Boelaert with the government of Belgium, making continuous investments in bike infrastructure over the long-term is important.
More than a decade ago, the Flanders region of Belgium invested €100 million in their bike infrastructure. Now, that is up to €380 million this year. All that investment has increased bike use and led to the growth of e-bikes for longer journeys. The bike system also complements their growing number of pedestrian-only zones.
Peltier argued that bike infrastructure supports local economies. In many cities, bikes are used to make last-mile deliveries, supporting businesses.
Bike infrastructure can also be packaged as carbon offsets, given they are proven to take cars off the road and reduce transportation emissions. They can be a greater part of carbon finance.
Cyclists in Bogota, Colombia / holgs, istockphoto.com
ITDP is scaling up this work worldwide through a cycling campaign it launched at COP27, with the goal of 25 million more people having access to nearby protected bike lanes by 2025. 34 major global cities have signed on, said Heather Thompson, CEO of ITDP.
“It has been proven over and over. We need designated bike lanes.” They are critical to increasing bike use among younger and older riders of all genders and abilities.
Protected bike lane, Germany / IGphotography, istockphoto.com
And Chiri Babu Maharjan, Mayor of Lalitpur Metropolitan City in Nepal, argued that growing a culture of biking may be just as important.
The Kathandu Valley once had a thriving cycling culture but that was diminished by the growth of motorbike riders in the 1980s. During his tenure, Mayor Maharjan has put in 37 miles (60 kilometers) of bike lanes and recently issued the city’s first tender for nearly 5 miles (8 kilometers) of protected bike lanes.
Biking has spread beyond wealthy European countries to cities across the developing world. But to address the climate crisis, the shift needs to happen more rapidly and more funding is needed.
