Monarch Conservation Science Partnership
The Challenge
Over the last two decades, the Eastern migratory population of monarch butterflies has declined by about 80%, leading many scientists to consider how to best conserve and rebuild monarch populations. Conservation efforts can be challenging to design and execute because of the multi-generational migration of monarchs that spans North America. Conservationists must consider many challenges while trying to reach their conservation goals, including:
• Coordination across the range of the monarch between Canada, the United States, and Mexico
• A lack of national-level monitoring and gaps in current data regarding monarch butterflies and their habitats
• Many factors that influence population decline like herbicides, insecticides, climate change, and land loss
The Monarch Conservation Science Partnership was formed to address these challenges.
Who We Are
The Monarch Conservation Science Partnership (MCSP) is a group of scientists, managers, and conservation organizations from across North America who perform science that will help meet the challenges of monarch conservation. Led by USGS, members come from federal agencies, non-profit organizations, and academic institutions across the United States, Mexico, and Canada. Meetings of the MCSP have been hosted by the USGS John Wesley Powell Center for Analysis and Synthesis in Ft. Collins, Colorado. Principal Investigators include Darius Semmens and Jay Diffendorfer with the Geosciences and Environmental Change Science Center (GECSC) and Wayne Thogmartin with the Upper Midwest Environmental Sciences Center (UMESC).
The Approach
To address conservation challenges, MCSP has followed the Strategic Habitat Conservation framework to help identify target population sizes, create conservation plans, and monitor the state of monarch butterflies in North America. The framework works in four steps:
- Biological planning
- Conservation design
- Conservation delivery
- Outcome Based monitoring
1. Biological Planning: How many monarchs do we need?
Researchers with MCSP first identified how many monarchs are needed in the population to avoid extinction. Semmens et al. (2016) used extinction modeling to determine the population size at which monarchs would avoid extinction. This population target serves as the goal for conservation and has implications for how much habitat is required to restore a population at that size.
For more, see, Semmens et al. 2016.
2. Conservation design: How can we increase population size?
Achieving the target population could involve two different approaches – decreasing monarch deaths or increasing fecundity (the number of new monarchs each female produces). With no clear path for decreasing monarch deaths, conservation design focuses on increasing female lifespans by increasing nectar availability and creating more breeding opportunities by increasing milkweed. MCSP-led studies determined that:
- Conservation efforts need to occur across the entire monarch range, not just in particular areas
- Within the North Central region of the U.S., milkweed must be planted in all land uses, including agricultural and marginal cropland areas, to reach a goal of restoring ≥1.3 billion stems of milkweed
For more, see, Oberhauser et al. 2016 and Thogmartin et al. 2017.
3. Conservation Delivery: How to transform the land?
Executing the plan across multiple land uses requires the help of many organizations, working groups, and associations. Important efforts informed by the conservation design principles of the MCSP include:
- The Midwest Association of Fish and Wildlife Agencies (MFWA): thirteen states and three Canadian provinces who work to deliver the Mid-America Monarch Conservation Strategy
- Rights-of-Way as Habitat Working Group: partners from many transportation and energy industries working on the Monarch Candidate Conservation Agreement with Assurances (CCAA) which encourages brush removal, mowing, and seeding strategies that support monarch habitat
4. Monitoring
Numerous monitoring programs across North America continue to track information about monarchs. The Integrated Monarch Monitoring Program (IMMP) is one such program established by USGS and the U.S. Fish and Wildlife Service. The national program collects milkweed, nectar plant, and monarch use data from many land-use types to help understand monarch ecology and conservation efforts.
For more, see, Cariveau et al. 2019, Pleasants et al. 2017, Weiser et al. 2019, and Weiser et al. 2020.
Tools for Decision Making
- Monarch Conservation Science Partnership Map Viewer and Tools
- Desktop Monarch Conservation Planning Tools
- Storymap
- Monarch PowerTrendTool
Further Reading
Diffendorfer, J. E., L. Ries, J. B. Loomis, K. Oberhauser, L. López-Hoffman, B. Semmens, B. Butterfield, D. Semmens, K. Bagstad, J. Goldstein, R. Wiederholt, J. Dubovsky, B. Mattsson, and W. E. Thogmartin. 2014. National valuation of monarch butterflies indicates an untapped potential for incentive-based conservation. Conservation Letters 7:253‒262. https://doi.org/10.1111/conl.12065
Semmens, B. X., D. J. Semmens, W. E. Thogmartin, R. Wiederholt, L. López-Hoffman, J. E. Diffendorfer, J. Pleasants, K. Oberhauser, and O. Taylor. 2016. Quasi-extinction risk and population targets for the Eastern, migratory population of monarch butterflies (Danaus plexippus). Scientific Reports 6:23265. https://doi.org/10.1038/srep23265
Oberhauser, K., R. Wiederholt, J. Diffendorfer, D. Semmens, L. Ries, W. E. Thogmartin, L. López-Hoffman, and B. Semmens. 2017. A trans-national monarch butterfly population model and implications for regional conservation priorities. Ecological Entomology 42:51–60. https://doi.org/10.1111/een.12351
Thogmartin, W. E., J. E. Diffendorfer, L. López-Hoffman, K. Oberhauser, J. Pleasants, B. X. Semmens, D. Semmens, O. R. Taylor, and R. Wiederholt. 2017. Density estimates of monarch butterflies overwintering in central Mexico. PeerJ 5:e3221. https://doi.org/10.7717/peerj.3221
Thogmartin, W. E., L. López-Hoffman, J. Rohweder, J. Diffendorfer, R. Drum, D. Semmens, S. Black, I. Caldwell, D. Cotter, P. Drobney, L. L. Jackson, M. Gale, D. Helmers, S. Hilburger, E. Howard, K. Oberhauser, J. Pleasants, B. Semmens, O. Taylor, P. Ward, J. Weltzin, and R. Wiederholt. 2017. Restoring monarch butterfly habitat in the Midwestern U.S.: “All Hands on Deck”. Environmental Research Letters 12:074005. https://doi.org/10.1088/1748-9326/aa7637
Thogmartin, W. E., R. Wiederholt, K. Oberhauser, R. G. Drum, J. E. Diffendorfer, S. Altizer, O. R. Taylor, J. Pleasants, D. Semmens, B. X. Semmens, R. Erickson, K. Libby, and L. López-Hoffman. 2017. Monarch butterfly population decline in North America: identifying the threatening processes. Royal Society Open Science 4:170760. https://doi.org/10.1098/rsos.170760
Pleasants, J. M., M. P. Zalucki, K. S. Oberhauser, L. P. Brower, O. R. Taylor, and W. E. Thogmartin. 2017. Interpreting surveys to estimate the size of the monarch butterfly population: pitfalls and prospects. PLoS ONE 12(7): e0181245. https://doi.org/10.1371/journal.pone.0181245
Semmens, D. J., J. E. Diffendorfer, K. J. Bagstad, R. Wiederholt, K. Oberhauser, L. Ries, B. X. Semmens, J. Goldstein, J. Loomis, W. E. Thogmartin, B. J. Mattsson, and L. López-Hoffman. 2018. Quantifying ecosystem service flows at multiple scales across the range of a long-distance migratory species. Ecosystem Services 31:255–264. https://doi.org/10.1016/j.ecoser.2017.12.002
Cariveau, A. B., H. L. Holt, J. P. Ward, L. Lukens, K. Kasten, J. Thieme, W. Caldwell, K. Tuerk, K. Baum, P. Drobney, R. G. Drum, R. Grundel, K. Hamilton, C. Hoang, K. E. Kinkead, J. McIntyre, W. E. Thogmartin, T. Turner, E. L. Weiser, and K. Oberhauser. 2019. The Integrated Monarch Monitoring Program: from design to implementation. Frontiers in Ecology and Evolutions 7:167. https://doi.org/10.3389/fevo.2019.00167
Weiser, E. L., J. E. Diffendorfer, R. Grundel, L. López-Hoffman, S. Pecoraro, D. Semmens, and W. E. Thogmartin. 2019. Balancing sampling intensity against spatial coverage for a community-science monitoring program. Journal of Applied Ecology 56:2252–2263. https://doi.org/10.1111/1365-2664.13491
Sample, C., J. Bieri, B. Allen, Y. Dementieva, A. Carson, C. Higgins, S. Piatt, S. Qiu, S. Stafford, B. J. Mattsson, D. Semmens, W. E. Thogmartin, and J. E. Diffendorfer. 2019. Quantifying source and sink habitats and pathways in spatially structured populations: a generalized modelling approach. Ecological Modelling 407:108715 https://doi.org/10.1016/j.ecolmodel.2019.06.003
Semmens, D. and Z. Ancona. 2019. Monarch habitat as a component of multifunctional landscape restoration using continuous riparian buffers. Frontiers in Environmental Science 7:126. https://doi.org/10.3389/fenvs.2019.00126
Taylor, Jr., O.R., J. P. Lovett, D. L. Gibo, E. L. Weiser, W. E. Thogmartin, D. J. Semmens, J. E. Diffendorfer, J. M. Pleasants, S. D. Pecoraro, and R. Grundel. 2020. Is the timing, pace and success of the monarch migration associated with sun angle? Frontiers in Ecology and Evolution 7:442. https://doi.org/10.3389/fevo.2020.00043
Weiser, E. L., J. E. Diffendorfer, L. López-Hoffman, D. Semmens, and W. E. Thogmartin. 2020. Challenges for leveraging citizen science to support statistically robust monitoring programs. Biological Conservation 242: 108411. https://doi.org/10.1016/j.biocon.2020.108411
Thogmartin, W. E., J. A. Szymanski, and E. L. Weiser. 2020. Evidence for a growing population of eastern migratory monarch butterflies is currently insufficient. Frontiers in Ecology and Evolution 8:43. https://doi.org/10.3389/fevo.2020.00043
Diffendorfer, J. E., W. E. Thogmartin, and R. G. Drum (eds.). 2020. North American Monarch Butterfly Ecology and Conservation. Frontiers Media SA, Lausanne, Switzerland. 10.3389/978-2-88966-118-3
Zylstra, E. R., W. E. Thogmartin, M. I. Ramírez, and E. F. Zipkin. 2020. Summary of available data from the monarch overwintering colonies in central Mexico, 1976–1991: U.S. Geological Survey Open-File Report 2020–1150, 10 p.
Below are other science projects associated with this project.
Monarch Conservation Planning Tools
Below are publications associated with this project.
Summary of available data from the monarch overwintering colonies in central Mexico, 1976–1991
Evidence for a growing population of eastern migratory monarch butterflies is currently insufficient
Challenges for leveraging citizen science to support statistically robust monitoring programs
Is the timing, pace and success of the monarch migration associated with sun angle?
Quantifying source and sink habitats and pathways in spatially structured populations: A generalized modelling approach
Monarch habitat as a component of multifunctional landscape restoration using continuous riparian buffers
Balancing sampling intensity against spatial coverage for a community science monitoring programme
The integrated monarch monitoring program: From design to implementation
Quantifying ecosystem service flows at multiple scales across the range of a long-distance migratory species
Monarch butterfly population decline in North America: identifying the threatening processes
Restoring monarch butterfly habitat in the Midwestern US: 'All hands on deck'
Interpreting surveys to estimate the size of the monarch butterfly population: Pitfalls and prospects
TrendPowerTool: A web lookup tool for estimating the statistical power of a monitoring program to detect population trends
A simulation-based power analysis can be used to estimate the sample sizes needed for a successful monitoring program, but requires technical expertise and sometimes extensive computing resources. We developed a web-based lookup app, called TrendPowerTool.
Below are news stories associated with this project.
Billions More Milkweeds Needed to Restore Monarchs
As many as 1.8 billion additional stems of milkweed plants may be needed in North America to return imperiled monarch butterflies to a sustainable population size, according to a recently published U.S. Geological Survey study.
The Challenge
Over the last two decades, the Eastern migratory population of monarch butterflies has declined by about 80%, leading many scientists to consider how to best conserve and rebuild monarch populations. Conservation efforts can be challenging to design and execute because of the multi-generational migration of monarchs that spans North America. Conservationists must consider many challenges while trying to reach their conservation goals, including:
• Coordination across the range of the monarch between Canada, the United States, and Mexico
• A lack of national-level monitoring and gaps in current data regarding monarch butterflies and their habitats
• Many factors that influence population decline like herbicides, insecticides, climate change, and land loss
The Monarch Conservation Science Partnership was formed to address these challenges.
Who We Are
The Monarch Conservation Science Partnership (MCSP) is a group of scientists, managers, and conservation organizations from across North America who perform science that will help meet the challenges of monarch conservation. Led by USGS, members come from federal agencies, non-profit organizations, and academic institutions across the United States, Mexico, and Canada. Meetings of the MCSP have been hosted by the USGS John Wesley Powell Center for Analysis and Synthesis in Ft. Collins, Colorado. Principal Investigators include Darius Semmens and Jay Diffendorfer with the Geosciences and Environmental Change Science Center (GECSC) and Wayne Thogmartin with the Upper Midwest Environmental Sciences Center (UMESC).
The Approach
To address conservation challenges, MCSP has followed the Strategic Habitat Conservation framework to help identify target population sizes, create conservation plans, and monitor the state of monarch butterflies in North America. The framework works in four steps:
- Biological planning
- Conservation design
- Conservation delivery
- Outcome Based monitoring
1. Biological Planning: How many monarchs do we need?
Researchers with MCSP first identified how many monarchs are needed in the population to avoid extinction. Semmens et al. (2016) used extinction modeling to determine the population size at which monarchs would avoid extinction. This population target serves as the goal for conservation and has implications for how much habitat is required to restore a population at that size.
For more, see, Semmens et al. 2016.
2. Conservation design: How can we increase population size?
Achieving the target population could involve two different approaches – decreasing monarch deaths or increasing fecundity (the number of new monarchs each female produces). With no clear path for decreasing monarch deaths, conservation design focuses on increasing female lifespans by increasing nectar availability and creating more breeding opportunities by increasing milkweed. MCSP-led studies determined that:
- Conservation efforts need to occur across the entire monarch range, not just in particular areas
- Within the North Central region of the U.S., milkweed must be planted in all land uses, including agricultural and marginal cropland areas, to reach a goal of restoring ≥1.3 billion stems of milkweed
For more, see, Oberhauser et al. 2016 and Thogmartin et al. 2017.
3. Conservation Delivery: How to transform the land?
Executing the plan across multiple land uses requires the help of many organizations, working groups, and associations. Important efforts informed by the conservation design principles of the MCSP include:
- The Midwest Association of Fish and Wildlife Agencies (MFWA): thirteen states and three Canadian provinces who work to deliver the Mid-America Monarch Conservation Strategy
- Rights-of-Way as Habitat Working Group: partners from many transportation and energy industries working on the Monarch Candidate Conservation Agreement with Assurances (CCAA) which encourages brush removal, mowing, and seeding strategies that support monarch habitat
4. Monitoring
Numerous monitoring programs across North America continue to track information about monarchs. The Integrated Monarch Monitoring Program (IMMP) is one such program established by USGS and the U.S. Fish and Wildlife Service. The national program collects milkweed, nectar plant, and monarch use data from many land-use types to help understand monarch ecology and conservation efforts.
For more, see, Cariveau et al. 2019, Pleasants et al. 2017, Weiser et al. 2019, and Weiser et al. 2020.
Tools for Decision Making
- Monarch Conservation Science Partnership Map Viewer and Tools
- Desktop Monarch Conservation Planning Tools
- Storymap
- Monarch PowerTrendTool
Further Reading
Diffendorfer, J. E., L. Ries, J. B. Loomis, K. Oberhauser, L. López-Hoffman, B. Semmens, B. Butterfield, D. Semmens, K. Bagstad, J. Goldstein, R. Wiederholt, J. Dubovsky, B. Mattsson, and W. E. Thogmartin. 2014. National valuation of monarch butterflies indicates an untapped potential for incentive-based conservation. Conservation Letters 7:253‒262. https://doi.org/10.1111/conl.12065
Semmens, B. X., D. J. Semmens, W. E. Thogmartin, R. Wiederholt, L. López-Hoffman, J. E. Diffendorfer, J. Pleasants, K. Oberhauser, and O. Taylor. 2016. Quasi-extinction risk and population targets for the Eastern, migratory population of monarch butterflies (Danaus plexippus). Scientific Reports 6:23265. https://doi.org/10.1038/srep23265
Oberhauser, K., R. Wiederholt, J. Diffendorfer, D. Semmens, L. Ries, W. E. Thogmartin, L. López-Hoffman, and B. Semmens. 2017. A trans-national monarch butterfly population model and implications for regional conservation priorities. Ecological Entomology 42:51–60. https://doi.org/10.1111/een.12351
Thogmartin, W. E., J. E. Diffendorfer, L. López-Hoffman, K. Oberhauser, J. Pleasants, B. X. Semmens, D. Semmens, O. R. Taylor, and R. Wiederholt. 2017. Density estimates of monarch butterflies overwintering in central Mexico. PeerJ 5:e3221. https://doi.org/10.7717/peerj.3221
Thogmartin, W. E., L. López-Hoffman, J. Rohweder, J. Diffendorfer, R. Drum, D. Semmens, S. Black, I. Caldwell, D. Cotter, P. Drobney, L. L. Jackson, M. Gale, D. Helmers, S. Hilburger, E. Howard, K. Oberhauser, J. Pleasants, B. Semmens, O. Taylor, P. Ward, J. Weltzin, and R. Wiederholt. 2017. Restoring monarch butterfly habitat in the Midwestern U.S.: “All Hands on Deck”. Environmental Research Letters 12:074005. https://doi.org/10.1088/1748-9326/aa7637
Thogmartin, W. E., R. Wiederholt, K. Oberhauser, R. G. Drum, J. E. Diffendorfer, S. Altizer, O. R. Taylor, J. Pleasants, D. Semmens, B. X. Semmens, R. Erickson, K. Libby, and L. López-Hoffman. 2017. Monarch butterfly population decline in North America: identifying the threatening processes. Royal Society Open Science 4:170760. https://doi.org/10.1098/rsos.170760
Pleasants, J. M., M. P. Zalucki, K. S. Oberhauser, L. P. Brower, O. R. Taylor, and W. E. Thogmartin. 2017. Interpreting surveys to estimate the size of the monarch butterfly population: pitfalls and prospects. PLoS ONE 12(7): e0181245. https://doi.org/10.1371/journal.pone.0181245
Semmens, D. J., J. E. Diffendorfer, K. J. Bagstad, R. Wiederholt, K. Oberhauser, L. Ries, B. X. Semmens, J. Goldstein, J. Loomis, W. E. Thogmartin, B. J. Mattsson, and L. López-Hoffman. 2018. Quantifying ecosystem service flows at multiple scales across the range of a long-distance migratory species. Ecosystem Services 31:255–264. https://doi.org/10.1016/j.ecoser.2017.12.002
Cariveau, A. B., H. L. Holt, J. P. Ward, L. Lukens, K. Kasten, J. Thieme, W. Caldwell, K. Tuerk, K. Baum, P. Drobney, R. G. Drum, R. Grundel, K. Hamilton, C. Hoang, K. E. Kinkead, J. McIntyre, W. E. Thogmartin, T. Turner, E. L. Weiser, and K. Oberhauser. 2019. The Integrated Monarch Monitoring Program: from design to implementation. Frontiers in Ecology and Evolutions 7:167. https://doi.org/10.3389/fevo.2019.00167
Weiser, E. L., J. E. Diffendorfer, R. Grundel, L. López-Hoffman, S. Pecoraro, D. Semmens, and W. E. Thogmartin. 2019. Balancing sampling intensity against spatial coverage for a community-science monitoring program. Journal of Applied Ecology 56:2252–2263. https://doi.org/10.1111/1365-2664.13491
Sample, C., J. Bieri, B. Allen, Y. Dementieva, A. Carson, C. Higgins, S. Piatt, S. Qiu, S. Stafford, B. J. Mattsson, D. Semmens, W. E. Thogmartin, and J. E. Diffendorfer. 2019. Quantifying source and sink habitats and pathways in spatially structured populations: a generalized modelling approach. Ecological Modelling 407:108715 https://doi.org/10.1016/j.ecolmodel.2019.06.003
Semmens, D. and Z. Ancona. 2019. Monarch habitat as a component of multifunctional landscape restoration using continuous riparian buffers. Frontiers in Environmental Science 7:126. https://doi.org/10.3389/fenvs.2019.00126
Taylor, Jr., O.R., J. P. Lovett, D. L. Gibo, E. L. Weiser, W. E. Thogmartin, D. J. Semmens, J. E. Diffendorfer, J. M. Pleasants, S. D. Pecoraro, and R. Grundel. 2020. Is the timing, pace and success of the monarch migration associated with sun angle? Frontiers in Ecology and Evolution 7:442. https://doi.org/10.3389/fevo.2020.00043
Weiser, E. L., J. E. Diffendorfer, L. López-Hoffman, D. Semmens, and W. E. Thogmartin. 2020. Challenges for leveraging citizen science to support statistically robust monitoring programs. Biological Conservation 242: 108411. https://doi.org/10.1016/j.biocon.2020.108411
Thogmartin, W. E., J. A. Szymanski, and E. L. Weiser. 2020. Evidence for a growing population of eastern migratory monarch butterflies is currently insufficient. Frontiers in Ecology and Evolution 8:43. https://doi.org/10.3389/fevo.2020.00043
Diffendorfer, J. E., W. E. Thogmartin, and R. G. Drum (eds.). 2020. North American Monarch Butterfly Ecology and Conservation. Frontiers Media SA, Lausanne, Switzerland. 10.3389/978-2-88966-118-3
Zylstra, E. R., W. E. Thogmartin, M. I. Ramírez, and E. F. Zipkin. 2020. Summary of available data from the monarch overwintering colonies in central Mexico, 1976–1991: U.S. Geological Survey Open-File Report 2020–1150, 10 p.
Below are other science projects associated with this project.
Monarch Conservation Planning Tools
Below are publications associated with this project.
Summary of available data from the monarch overwintering colonies in central Mexico, 1976–1991
Evidence for a growing population of eastern migratory monarch butterflies is currently insufficient
Challenges for leveraging citizen science to support statistically robust monitoring programs
Is the timing, pace and success of the monarch migration associated with sun angle?
Quantifying source and sink habitats and pathways in spatially structured populations: A generalized modelling approach
Monarch habitat as a component of multifunctional landscape restoration using continuous riparian buffers
Balancing sampling intensity against spatial coverage for a community science monitoring programme
The integrated monarch monitoring program: From design to implementation
Quantifying ecosystem service flows at multiple scales across the range of a long-distance migratory species
Monarch butterfly population decline in North America: identifying the threatening processes
Restoring monarch butterfly habitat in the Midwestern US: 'All hands on deck'
Interpreting surveys to estimate the size of the monarch butterfly population: Pitfalls and prospects
TrendPowerTool: A web lookup tool for estimating the statistical power of a monitoring program to detect population trends
A simulation-based power analysis can be used to estimate the sample sizes needed for a successful monitoring program, but requires technical expertise and sometimes extensive computing resources. We developed a web-based lookup app, called TrendPowerTool.
Below are news stories associated with this project.
Billions More Milkweeds Needed to Restore Monarchs
As many as 1.8 billion additional stems of milkweed plants may be needed in North America to return imperiled monarch butterflies to a sustainable population size, according to a recently published U.S. Geological Survey study.