ReefCycle: Bioconcrete Reef Structures

What makes your solution innovative?

Our proposal introduces two critical concepts for the production of bio-concrete: the use of enzymes to bond sand particles to form bioconcrete and the use of artificial sand made from crushed waste, reusing materials available in large quantities, such as non-recyclable glass and oyster shells. The production is intrinsically energy efficient as it doesn’t require heat and mechanical energy for the grinding process. Thus, it is a technology that can be propagated quickly to places worldwide that need solutions today. 

Critical to solving the challenge of decarbonizing cement production is scaling low-emission, low-cost, and accessible technology. Our technology is unique in its shared characteristics with standard cement: it is cheap, non-expert, and durable. Anyone, anywhere can produce it; it does not require a factory or global supply chain to scale; and it promotes a natural process that sequesters carbon and bypasses the petroleum economy. This is critical for democratizing green cement production so that it can be adapted rapidly at scale. 

Our solution is innovative in the following ways: 

1. Uses plant-based enzymes to bond sand particles to form rigid structures.

2. We can use artificial sand made of ground non-recyclable glass, oyster shells, and others that can be ground to small particulates. 

3. Our production process is eco-friendly and energy-efficient. It operates without high temperatures, and materials can be ground using renewable energy sources such as wind or water mills. 

4. The production can use molds made from various materials, including locally found banana leaves, wood, bamboo, etc. 

5. The technology can be propagated quickly to many locations as local material can be resourced for production. 

6. Reefcycle is biocompatible, producing no harm to the environment. 

Looking towards the future, ReefCycle’s innovation is disruptive at a local level, catalyzing broader positive impacts in the space of blue economy solutions and green manufacturing. For green economy solutions to scale, low-impact materials are required to grow durable structures for coastal adaptation and restoration. Green manufacturing modalities must shift from global supply chains to local and circular production, particularly in low-resource, high-climate-impact locations. ReefCycle models net-zero emissions for material production, which can be scaled industrially while upcycling waste through a resource-efficient supply chain or modeled locally without the need for industrial processes. 

Through accessible bio-circular economic solutions like ours, commodities can be sourced from available and renewable resources outside of global supply chains, linking mitigation, adaptation, and sustainable development. Here are broader applications we see for our solutions within the resiliency space and its impacts on the market: 

• The use of biocementation to bind together local fibers, like hemp fiber, to form lightweight blocks could increase demand for and adoption of sustainable building materials . 

• The injection of bioconcrete into existing and fractured infrastructure to improve strength could enable sustainable infrastructure maintenance. 

• Immobilization of contaminated soils and bioremediation by bioconcrete may contribute to local environmental remediation and municipal or industrial clean up of contaminated sites.

• The use of contaminated wastewater in growing bioconcrete to clean contaminated water. 

Describe in simple terms how and why you expect your solution to have an impact on the problem.

The long-term objective of our program is to build climate resilience and adaptation through the production of coastline restoration structures from regenerative bioconcrete. We aim to do this by working with community-oriented nonprofits to provide tools and services to support “frontline communities,” populations in coastal regions most impacted by climate change, in sourcing and producing bioconcrete to support a bio-circular economic model, bypassing the industrial supply chain. With this knowledge, support, and equipment, frontline communities can fabricate durable materials in situ from renewable and upcycled resources: creating carbon-capture bioconcretes that can be used to prevent, prepare for, and recover from natural disasters. Such applications include the construction of reef restoration modules to promote nature-as-infrastructure, which are monitored by volunteers to collect key metrics relating to biodiversity and water quality, which indicate the extent and success of marine restoration and climate resilience efforts. 

The activities of this program will transfer low-emissions technology to frontline communities to promote climate adaptive practices: resulting in the creation of local, informal, and circular production, infrastructure, and economies due to the decentralization of climate technology and resource generation. By engaging communities in the design, planning, and implementation of artificial reef structures, the program promotes adaptive city planning that restores and strengthens marine ecosystems and communities through the broader blue economy while mitigating emissions associated with materials production and global supply chains. Engagement with ReefCycle’s bioconcrete process could lead to wider adoption of bioconcrete and other bio-circular-local solutions towards the built environment, marine conservation, and adaptive coastlines and infrastructure.

Critical to achieving these goals is establishing key partnerships with nonprofit organizations and educational institutions in frontline communities to ensure community-informed technology transfer and design. Achieving these goals will relieve the impact that frontline communities feel from rising sea levels: promoting economic growth, reducing impacts from sea level rise, and, globally, reducing emissions associated with materials and resource generation. The democratization of this technology may ultimately change people's knowledge, attitudes, and behaviors towards climate adaptation and resilience planning. 

To align our program's outcomes with our long-term objectives, we have identified "build bio-circular-local climate resilience in frontline populations" as a final outcome. The following visual representation outlines the inputs, activities, outputs, outcomes, and overarching goal of our program:

1. Establish key relationships with community-led nonprofit partners.

2. Engage frontline communities in local-circular-biomanufacturing of durable materials through community involvement, tech transfer, and training programs.

3. Democratize low-emissions technology for the informal and community-informed production of resilient infrastructure.

4. Promote accessible, affordable, waste-derived, fossil-free, and carbon-sequestering bioconcrete production.

5. Support organizations and populations engaged in the fabrication and implementation of artificial reef structures and other climate adaptive coastal restoration modules.

These objectives and goals are a result of the following, which we will continue to implement through our program: 

1. Ethnogoraphy, stakeholder interviews, co-design workshops, systems mapping

2. Impact Evaluation  

3. Research and expert advice from nonprofit partnerships

By following these steps, we aim to build climate resilience and adaptation while simultaneously contributing to economic growth, environmental sustainability, and community empowerment within frontline populations.

What are your impact goals for your solution and how are you measuring your progress towards them?

Increase Coastal Resilience and Reduce Property Damage:

• Goal: Restore natural infrastructure to increase wave energy dissipation, leading to a 20% reduction in coastal erosion and property damage over a five year period.

• Indicator: Measure the reduction in coastal erosion rates and property damage over the specified time frame, within system boundaries. 

Mitigate Storm Surge Impact and Coastal Flooding:

• Goal: Deploy bioconcrete structures to attenuate storm surges, resulting in a 15% reduction in coastal flooding incidents within three years.

• Indicator: Monitor the decrease in coastal flooding incidents over the specified time frame and system boundary. 

Enhance Habitat Creation and Biodiversity:

• Goal: Increase marine species richness by 20% by 2030 through habitat creation and biodiversity enhancement efforts.

• Indicator: Monitor changes in marine species richness over the specified time frame.

Engage and Empower Students and Volunteers:

• Goal: Engage 1,000 students and volunteers annually in hands-on restoration activities and provide training in restoration, marine ecology, and bioconcrete technology to 500 individuals annually through nonprofit and academic partnerships, fostering environmental stewardship and leadership development within four years.

• Indicator: Track and engage the number of participants engaged annually and assess their skill development and leadership roles within their communities.

Empower Women and Strengthen Community Ownership:

• Goal: Empower 20 women from frontline communities as leaders in climate resilience and technology adoption within three years, fostering a sense of community ownership and pride among 300 frontline community members involved in reef module fabrication and implementation.

• Indicator: Monitor the progress of women empowerment initiatives and community engagement activities.

Diversify and Strengthen Partnerships:

• Goal: Strengthen efforts to protect and safeguard coastal frontline communities' cultural and natural heritage by diversifying partnerships related to preservation, protection, and conservation, establishing key partnerships with five community-oriented nonprofits worldwide in the next three years.

• Indicator: Assess the diversity and effectiveness of partnerships established and their impact on heritage preservation and community development.

Contribute to Economic Development and Empowerment:

• Goal: Contribute to economic development in frontline communities through increased sustainable practices, tourism, and local production, benefiting 500 community members through employment and generating $1 million in local revenue from reef module sourcing, fabrication, and installation within five years.

• Indicator: Measure the increase in employment opportunities, revenue generation, and economic empowerment within the targeted communities.

Support Sustainable Infrastructure Development:

• Goal: Facilitate sustainable infrastructure development in developing countries through financial and technological support, establishing joint grant funding with partnership nonprofits.

• Indicator: Track the implementation of joint grant funding and assess its impact on sustainable infrastructure development in targeted regions.

Reduce Carbon Emissions and Promote Climate Migitation:

• Goal: Reduce carbon emissions associated with the blue economy and climate resiliency by 20% by 2030.

• Indicator: Monitor carbon emission reductions as compared to cement and assess progress towards the 20% reduction target by 2030.

Describe the core technology that powers your solution.

While the employment of our provisional technology is modern, it is ancient in the natural world. Our employment utilizes biomimicry’s bio-assisted design principles to harness technology in nature to promote accessible and adaptable innovation. We do this in two ways: first, we use enzymes from plants to catalyze the growth of hard materials which can be grown around waste to form a weather-resistant and hard composite material similar to cement. Secondly, we employ this technology towards growing low-emission natural infrastructure, regenerating local ecosystems and reducing coastal natural hazards. These two processes are adaptive, responding to local resources and the needs of specific communities and ecosystems. 

As we’ve had a chance to discuss our core technology(biocementation), which we use to grow minerals into waste-derived composites, we’ll take this opportunity to discuss the application of bioconcrete as artificial reef structures, which contribute to building coastal resilience by restoring nature's defense system. Modular reef structures play a critical role in restoring key, self-regulating mechanisms, including: 

1. Wave Energy Dissipation: Reefs act as natural barriers that break and absorb wave energy during storms and high tides. They are a buffer, reducing the intensity of waves reaching the shoreline. Wave energy dissipation protect coastal areas from erosion, reducing the risk of flooding and property damage. 

2. Storm Surge Mitigation: Reefs have the ability to attenuate storm surge impacts. By absorbing and slowing down the movement of water, reefs reduce the height and force of storm surges, lowering the risk of coastal flooding and the associated damages. 

3.  Erosion Control: Reefs provide stabilization to shorelines; reducing erosion. They trap and promote the deposition of new sediment, which helps build up and maintain beaches and coastal landforms; strengthening the resilience of coastal areas against natural hazards and sea level rise. Bioconcrete can also be utalized to stack along coastlines; reducing erosion by stabilizing sandy soil.

4. Water Quality Improvement: In the case of oyster reefs, oysters are filter feeders: they extract particles and pollutants from the water as they feed. By restoring oyster populations, water quality is improved as they help filter excess nutrients, sediments, and contaminants. In fact, one oyster can filter up to 50 gallons of water a day! Cleaner water reduces the impacts of algal blooms, enhances habitat quality for marine life, and contributes to overall ecosystem health. In New York City, this service aids in recovery after storms due to our out-dated sewage overflow system, which releases polluted urban runoff and raw sewage into our waterways. 

5. Habitat Creation and Biodiversity Enhancement: Reefs provide essential habitat for numerous marine species. By restoring these reefs, we enhance biodiversity and create a thriving ecosystem. A diverse and healthy ecosystem is more resilient to disturbances and can better withstand and recover from the impacts of natural disasters. 

Through the use of nature to grow structures, and their implementation restoring ecological functions, our solution sits between modern and ancestral technologies: thus, facilitating nature to solve a new and man-made problem. 

Which of the following categories best describes your solution?

A new technology

How do you know that this technology works?

The leading application for biocementation in the field is through the established microbial method known as Microbially induced carbonate precipitation (MICP), which  mimics the natural cementation process that occurs in various geological settings by using the bicarbonate minerals resulting from various bacterial metabolic pathways as cementing agents. This bio-technique can be used to manufacture so-called “bio-bricks,” which rival regular bricks in strength and durability. 

https://www.frontiersin.org/articles/10.3389/fmats.2023.1155643/full

A study by Maiia Smirnova found that bioconcrete produced microbially can achieve compressive strength comparable to traditional concrete. These studies produced homogeneously cemented specimens with strengths up to 50MPa- potentially meeting requirements for prefabricated structural elements. 

https://www-nature-com.ezproxy.canberra.edu.au/articles/s44296-023-00004-6

Studies show that biocementation can sequester up to 84% CO2, making it a carbon sequestration solution:

https://pubmed-ncbi-nlm-nih-gov.ezproxy.canberra.edu.au/27524723/

The enzymatic process that our technology employs to produce calcification is known as Enzyme induced carbonate precipitation (EICP), which is an emerging solution compared to the more researched topic of MICP, being researched in the field of soil stabilization. According to research by Fuzhou Univiersity, the method of EICP has advantages over the commonly used microbially induced carbonate precipitation (MICP) process as it does not involve issues related to bio-safety. This is due to the environmental concerns related to the microbes that remain in the soil after MICP and the release of ammonia through the MICP process. In comparison, EICP seems to be better than MICP. It has also risen in popularity as it can be produced in situ. 

https://www.icevirtuallibrary.com/doi/abs/10.1680/jgeen.16.00138

https://www.mdpi.com/2073-4352/11/4/370

https://ascelibrary-org.ezproxy.canberra.edu.au/doi/abs/10.1061/(ASCE)MT.1943-5533.0001604

 A life cycle assessment (LCA) study was conducted to compare the use of traditional soil stabilization using Portland cement (PC) with bio-cementation via EICP over a range of environmental impacts. The LCA results revealed that EICP soil treatment has nearly 90% less abiotic depletion potential and 3% less global warming potential compared to PC in soil stabilization. https://www-nature-com.ezproxy.canberra.edu.au/articles/s41598-022-09723-7

The following study found that EICP can achieve unprecedented efficiency compared with the results of MICP. https://www-sciencedirect-com.ezproxy.canberra.edu.au/science/article/pii/S2949929123000074

Biocementation is proven to remediate contaminated soils and to treat wastewater. https://www.mdpi.com/2073-4352/11/4/370

Alongside these academic sources, we have conducted numerous lab experiments to produce bioconcrete from EICP, which we are in the process of testing with XRD and through our testing program with Billion Oyster Project, wherein, we’ve installed bioconcrete reef structures in the New York Harbor. Attached are photos of the retrieved bioconcrete modules after the first year of the study. These results indicate durability and biocompatibility in marine environments. 

https://static1.squarespace.com/static/63123c9eae50ba59f57ed765/t/65e5fe12ceab590f3daa36ad/1709571609414/ReefRocket_FieldWork2023.pdf

Please select the technologies currently used in your solution:

• Biomimicry
• Biotechnology / Bioengineering
• Manufacturing Technology
• Materials Science

If your solution has a website or an app, provide the links here:

ReefCycle.earth

How many people work on your solution team?

Full-Time Staff (1)

Mary Lempres - Full Time

Part-Time Staff (2)

Ahmed Miftah PhD- Part Time 

Helio Takai PhD- Part Time 

Partners (2)

Jennifer Zhu PhD - Full Time at Billion Oyster Project 

Jenn is our primary partnership contact, responsible for Marine Habitat Resources and our testing program with Billion Oyster Project 

Ben LoGuidice - Full Time at Billion Oyster Project 

Ben is the Oyster Production Program Manger at Billion Oyster Project and responsible for monitoring ReefCycle’s bioconcrete reef modules and samples during our testing program. 

How long have you been working on your solution?

2016 - Ahmed Miftah has been researching the topic of enzymatic biocementation and its applications in clean technology since 2016.

2021 - Mary Lempres began researching the design applications for biocementation through ethnographic and co-design research with community members along the New York Harbor as the topic of her Master’s of Industrial Design thesis. 

2022- The duo combined their efforts towards the application of enzymatic bioconcrete for reef restoration, establishing a partnership with the Billion Oyster Project. 

2023 - Helio Takai joined our team. 

2024 - ReefCycle LLC was formed 

Tell us about how you ensure that your team is diverse, minimizes barriers to opportunity for staff, and provides a welcoming and inclusive environment for all team members.

Our team is diverse, and we are committed to representing diverse, inclusive, and equitable perspectives, which are critical in addressing climate change and transferring technology sustainability, equally, and inclusively. Our COO, Helio Takai, is experienced in inclusive hiring in the academic setting and brings this knowledge with him to our team. 

The UN estimates that  80% of people displaced by climate change are women. At the same time, only 7% of US climate tech venture capital funding went to female founders in 2023, according to GreenBiz. As a female-founded team, with a diverse team representing perspectives across different continents and sectors, our goal is to continue to grow into a more diverse team.

What is your business model?

ReefCycle's in its early stages of development, with a prototype currently being tested with our restoration partners. We seek funding to bring the prototype to a stage where it can be piloted, to detail and develop our product and cost structure, establish key partnerships in the supply chain, and conduct further customer discovery. 

Our solution, while designed with and for communities along the New York Harbor, has applications in every coastal city, harbor, and population in the world, specifically in developing and low-resource contexts. It provides organizations, from municipal to local, with low-emissions technology that is utilized to slow erosion, improve water quality, and reduce impacts from coastal natural hazards. 

Key Customers and Beneficiaries: 

Our key partners are governments, nonprofit groups, and educational institutions engaged in coastal restoration, blue economy, and coastal climate resilience (“The restoration economy”). We work with them to implement bioconcrete as a green alternative to conventional, polluting materials. 

Our customers are the vendors currently supporting such organizations, who supply materials and hardware for coastal restoration equipment. These vendors are responsible for the production, deployment, and installation of artificial reef structures. 

Our technology enables reef restoration vendors to utilize carbon-neutral technology and employ healthy materials in restoration that doesn’t damage or pollute marine ecosystems. In turn, the implementation of bioconcrete reef structures promote natural infrastructure, improving the lives of frontline communities and ecosystems. The advantages of our technology could be applied towards additional remediation efforts by organizations and governments to benefit frontline communities, including the use of bioconcrete for contamination clean up in soil and marine environments. 

Flow of Products/Services: 

ReefCycle → Restoration Materials & Deployment Vendors → Governments & Nonprofits → Frontline Communities 

Products and Services: 

1. Low-Cost Consumable Product: We provide a dehydrated powder, which is simply hydrated and applied as a liquid treatment over crushed waste aggregate, forming bioconcrete. 

2. Modular Hardware: We sell hardware that can be used manually or through a clean-energy system to automate and streamline the production of bioconcrete and crushing of waste material for local manufacturing. 

3. Custom Models: We design custom molds based on specs defined by nonprofits/organizations and frontline communities/marine specialists.

4. Licensing: ReefCycl(ing) technology is licensed to vendors with tech transfer fee

5. Education: We work with nonprofits to procure joint-funding for education and community-driven knowledge transfer. 

These products and services can be adopted by our beneficiaries and customers at different scales from DIY to local manufacturing. By selling these products and services to intermediary vendors, we are not responsible for the implementation of bioconcrete structures, rather, we engage in direct design development with communities through partnerships and license our low-emissions production process to intermediaries who, in turn, sell their services to organizations and municipalities. Our expenses, which are built in to the lincensing model, will entail product development, community-led design, testing, and research. 

Due to the customized approach we take to delivering products and services, ReefCycle can be expanded to other applications, including soil remediation, building materials, and other forms of coastal restoration modules. 

Do you primarily provide products or services directly to individuals, to other organizations, or to the government?

What is your plan for becoming financially sustainable, and what evidence can you provide that this plan has been successful so far?

We will bring money to fund our work through the following revenue streams: 

1. Direct Sales - We will sell our B2B consumable bioconcrete powder and fabrication equipment directly to third party vendors and nonprofit organizations. 

2. Licensing and Design - We will license our technology to third party vendors as well as organziations equipt to fabricate and deploy restoration modules. This licensing model will include trainings, technology transfer, and testing for new waste-streams or additional biological services (like bioremediation). Baked into this service, we will also charge a one-time fee for the design and development of custom modular molds based on regional policies, ecosystems, risks, and the extent/type of community involvement employed by nonprofit partners. 

3. Grants - With our nonprofit partners, we will pursue joint partnership grants to support design development and research towards new applications, impact assessment, impact monitoring, and third party vendor financing. We will also explore early-stage funding from foundations in piloting ReefCycle. 

Thus far, we have receive $30,000 in grant funding from CAAA, AON, and IDEO as a early-stage winner of the 2023 OpenIDEO Climate Resiliency Challenge, which was judged by the Environmental Defence Fund, Network for Good, and Guidewire. In addition to this, we’ve connected with a number of nonprofit and community-led organizations, as well as reef restoration vendors, interested in utalizing ReefCycle to solve a range of challenges. Our partners, Billion Oyster Project, have committed to piloting our solution after the completion of our testing program.