Learn techniques for using leaf-level gas-exchange instruments for survey style measurements and discuss selecting and configuring the chamber environment as well as general measurement best practices.

Measurements of leaf-level gas exchange (carbon assimilation, apparent transpiration, stomatal conductance) and chlorophyll a fluorescence are fundamental to many areas of plant research. Techniques for making these measurements are well established and have been packed into off the shelf instrument systems. Successful use of these systems for collection of high-quality data, however, requires both an understanding of the underlying biological processes and the techniques used to measure them. Learn the basic principles behind these measurements with a focus on underlying assumptions and best practices.

Measurements of photosynthetic response to CO₂ give insight into the limitations and capacities of photochemistry. See a demonstration of techniques for measuring CO₂ response using both steady-state and non-steady-state approaches. Discuss considerations for developing a protocol and configuring an instrument for these measurements.

Learn about fitting photosynthesis models to leaf-level light and CO₂ response curve data using R statistical data analysis software.

Discuss using your plant photosynthesis system to get the best results with other users and LI-COR experts. Share your successes and learn from common pitfalls.

Self care for your research. Learn the basics of how to maintain your LI-6800 Plant Photosynthesis System, including with the Aquatic Chamber.

What do you wish you could measure with a plant photosynthesis system? What features would you add to the LI-6800 if you had the chance? What would make your plant physiology research easier? We want your advice! Help design the research tools of the future.

Description coming soon.

Future-proof your research. Protect your project with a service agreement or maintenance plan. Learn more from our service team.

Trace gas transport (flux) at the soil-atmosphere interface is an important process linked to a number of biological and physical properties of an ecosystem. This workshop will provide an introduction to the theory and application of closed-transient chambers to the measurement these fluxes. Topics will include diffusive transport theory, fitting methods for flux calculation and considerations for deploying chamber systems.

Learn about the theory and application of chamber-based measurements of soil gas fluxes

SoilFluxPro^® is a freely available software for post processing and quality control of chamber-based trace gas flux measurements. See a demonstration of SoilFluxPro and discuss its curving fitting approaches for flux estimates, its advanced guidance tools selecting fit windows, and its hidden scripting console.

Learn about the theory and implementation of a new, automated soil-respired CO₂ isotope measurement solution

Discuss getting the best results from your chamber-based soil gas flux system with other users and LI-COR experts. Share your successes and learn from common pitfalls.

What do you wish you could measure with a long term or survey soil gas flux measurement system? What features would you add to SoilFluxPro if you had the chance? What would make your soil health research easier? We want your advice! Help design the research tools of the future.

Details to come

Combining soil gas flux and eddy covariance data provides a comprehensive picture of CO₂ behavior and movement. That information is used to make informed decisions on leak detection, monitoring storage efficiency, assesing enviromental impact, model calibration and validation and regulatory compliance and reporting.

Soil gas flux and eddy covariance data can significantly enhance the management of agricultural systems, improve productivity, and address environmental impacts. Measurements of soil health, crop productivity, and greenhouse gas emissions provide crucial information for precision agriculture, adaptive farm management and enviromental compliance.

Discuss using an adapted flux system to measure gas fluxes from discrete sampels of soils, fruits, or small animals, in non-actuated, user-designed chambers.

Self care for your research. Learn the basics of how to maintain your gas analyzers and eddy covariance systems.

Future-proof your research. Protect your project with a service agreement or maintenance plan. Learn more from our service team.

An introduction to methodological aspects of the eddy covariance technique: theory, basic assumptions, key principles, fetch and flux footprint considerations, experimental design, and implementation.

Discuss theoretical or practical questions you may have about the EddyPro^® eddy covariance flux computation software.

Discuss getting the best results from your eddy covariance system with other users and LI-COR experts. Share your successes and learn from common pitfalls.

Discuss getting the best results from your Water with other users and LI-COR experts. Share your successes and learn from common pitfalls.

What do you wish you could measure with an eddy covariance system? How do you want to use the Water Node? What would make your ecosystem gas exchange research easier? We want your advice! Help design the research tools of the future.

Combining soil gas flux and eddy covariance data provides a comprehensive picture of CO₂ behavior and movement. That information is used to make informed decisions on leak detection, monitoring storage efficiency, assesing enviromental impact, model calibration and validation and regulatory compliance and reporting.

Soil gas flux and eddy covariance data can significantly enhance the management of agricultural systems, improve productivity, and address environmental impacts. Measurements of soil health, crop productivity, and greenhouse gas emissions provide crucial information for precision agriculture, adaptive farm management and enviromental compliance.

Future-proof your research. Protect your project with a service agreement or maintenance plan. Learn more from our service team.

A water and energy balance monitoring project that started in Nebraska, expanded across the Midwest, and added coverage in the upper Colorado River basin has plans to grow even more.

Find out how what tools the project group is using, see their data, and learn how you could scale your ecosystem flux measurements.

The cloud-connected and IoE-enabled Water Node measures fluxes of water at a fraction of the cost and power requirements of a traditional eddy covariance system, yet with similar accuracy. See live data from a network of 18 IoE-enabled Water Nodes in one field and discuss future possibilities of combining data from globally networked sensors placed in crop fields, forests, grasslands, wetlands–any landscape–all sharing data to a single Cloud.

Self care for your research. Learn the basics of how to maintain your LI-710 Evapotranspiration Sensor or IoE Module.

LI-COR Cloud and HOBOlink provide remote access to your data from a LI-COR Water Node or your HOBO Data Loggers. See a demonstration of how you can view, share, and manage your data in real time from any location.

Measurements of carbon in water provide valuable insights into carbon fluxes, cycles, and exchanges as well as ecosystem production, anthropogenic emissions, and the global carbon budget. There are four parameters that can characterize the inorganic carbon system in water, all of which can be measured using LI-COR’s aquatic carbon instruments. Learn the basic principles behind these measurements and get hands-on experience with the instruments.

Self care for your research. Learn the basics of how to maintain your aquatic carbon systems from Apollo SciTech, which are now part of LI-COR

Future-proof your research. Protect your project with a service agreement or maintenance plan. Learn more from our service team.

Self care for your research. Learn the basics of how to maintain your LI-6800 Plant Photosynthesis System, including with the Aquatic Chamber.

Description coming soon.

Discuss getting the best results from your Water with other users and LI-COR experts. Share your successes and learn from common pitfalls.

Learn techniques for using leaf-level gas-exchange instruments for survey style measurements and discuss selecting and configuring the chamber environment as well as general measurement best practices.

Measurements of leaf-level gas exchange (carbon assimilation, apparent transpiration, stomatal conductance) and chlorophyll a fluorescence are fundamental to many areas of plant research. Techniques for making these measurements are well established and have been packed into off the shelf instrument systems. Successful use of these systems for collection of high-quality data, however, requires both an understanding of the underlying biological processes and the techniques used to measure them. Learn the basic principles behind these measurements with a focus on underlying assumptions and best practices.

Measurements of photosynthetic response to CO₂ give insight into the limitations and capacities of photochemistry. See a demonstration of techniques for measuring CO₂ response using both steady-state and non-steady-state approaches. Discuss considerations for developing a protocol and configuring an instrument for these measurements.

Learn about fitting photosynthesis models to leaf-level light and CO₂ response curve data using R statistical data analysis software.

Discuss using your plant photosynthesis system to get the best results with other users and LI-COR experts. Share your successes and learn from common pitfalls.

What do you wish you could measure with a plant photosynthesis system? What features would you add to the LI-6800 if you had the chance? What would make your plant physiology research easier? We want your advice! Help design the research tools of the future.

Description coming soon.

Trace gas transport (flux) at the soil-atmosphere interface is an important process linked to a number of biological and physical properties of an ecosystem. This workshop will provide an introduction to the theory and application of closed-transient chambers to the measurement these fluxes. Topics will include diffusive transport theory, fitting methods for flux calculation and considerations for deploying chamber systems.

Learn about the theory and application of chamber-based measurements of soil gas fluxes

SoilFluxPro^® is a freely available software for post processing and quality control of chamber-based trace gas flux measurements. See a demonstration of SoilFluxPro and discuss its curving fitting approaches for flux estimates, its advanced guidance tools selecting fit windows, and its hidden scripting console.

Learn about the theory and implementation of a new, automated soil-respired CO₂ isotope measurement solution

Discuss getting the best results from your chamber-based soil gas flux system with other users and LI-COR experts. Share your successes and learn from common pitfalls.

What do you wish you could measure with a long term or survey soil gas flux measurement system? What features would you add to SoilFluxPro if you had the chance? What would make your soil health research easier? We want your advice! Help design the research tools of the future.

Details to come

Combining soil gas flux and eddy covariance data provides a comprehensive picture of CO₂ behavior and movement. That information is used to make informed decisions on leak detection, monitoring storage efficiency, assesing enviromental impact, model calibration and validation and regulatory compliance and reporting.

Soil gas flux and eddy covariance data can significantly enhance the management of agricultural systems, improve productivity, and address environmental impacts. Measurements of soil health, crop productivity, and greenhouse gas emissions provide crucial information for precision agriculture, adaptive farm management and enviromental compliance.

Discuss using an adapted flux system to measure gas fluxes from discrete sampels of soils, fruits, or small animals, in non-actuated, user-designed chambers.

Self care for your research. Learn the basics of how to maintain your gas analyzers and eddy covariance systems.

An introduction to methodological aspects of the eddy covariance technique: theory, basic assumptions, key principles, fetch and flux footprint considerations, experimental design, and implementation.

Discuss theoretical or practical questions you may have about the EddyPro^® eddy covariance flux computation software.

Discuss getting the best results from your eddy covariance system with other users and LI-COR experts. Share your successes and learn from common pitfalls.

What do you wish you could measure with an eddy covariance system? How do you want to use the Water Node? What would make your ecosystem gas exchange research easier? We want your advice! Help design the research tools of the future.

A water and energy balance monitoring project that started in Nebraska, expanded across the Midwest, and added coverage in the upper Colorado River basin has plans to grow even more.

Find out how what tools the project group is using, see their data, and learn how you could scale your ecosystem flux measurements.