DCMEX -- Deep Convective Microphysics EXperiment
Lead Research Organisation:
University of Leeds
Department Name: National Centre for Atmospheric Science
Abstract
The goal of the DCMEX project is to ultimately reduce the uncertainty in equilibrium climate sensi-
tivity by improving the representation of microphysical processes in global models. It is the anvils
produced by tropical systems in particular that contribute significantly to cloud feedbacks. The anvil
radiative properties, lifetimes and areal extent are the key parameters. DCMEX will determine the
extent to which these are influenced, or even controlled by the cloud microphysics including the
habits, concentrations and sizes of the ice particles that make up the anvils, which in turn depend
on the microphysical processes in the mixed-phase region of the cloud as well as those occurring in
the anvil itself.
There has been a rapid advancement in the sophistication of global climate models in recent
years. Yet some of the equations used to represent microphysics processes are based on a poorer
physical understanding than desired. Gettelman and Sherwood (2016), for example pointed out
that there is significant spread in determining cloud feedbacks across different global models due
to uncertainties in microphysical processes, such as the treatment of ice processes. Ceppi et al.
(2017) also concluded that accurately representing clouds and their radiative effects in global models
remains challenging partly due to the difficulty in representing the cloud microphysics, as well as the
interactions between microphysics and dynamics. The microphysical and radiative processes and dynamics that control the opacity and areal coverage of tropical anvil clouds are not well represented in global climate models.
DCMEX will make novel measurements of cloud microphysics in a real-world laboratory convective cloud system - both the mixed-phase region and anvil - as well as improve and test models
and then apply them globally to tropical deep convective systems. We propose to deploy the FAAM
aircraft along with two dual-polarisation, Doppler radars and airborne and ground-based aerosol
measurements to study the deep convective clouds that form over an isolated mountain range in
New Mexico. The focus will be on the formation of ice from ice nucleating particles (INPs) (primary
ice production) and by processes involving existing ice particles (secondary ice particle production),
such as collisions. These observations will be used to test and further refine the representation of
ice processes in climate models. Our approach recognises that in order to represent cloud feedbacks accurately a model needs to represent the individual processes within the system accurately.
Demonstrating that the model is able reproduce the observed evolution of these clouds is therefore
a necessary condition for the accurate prediction of cloud feedbacks.
The research in DCMEX will have a robust pathway from a novel field campaign to more accurate
estimates of climate sensitivity. This pathway is built with four integrated parts: new observations;
the use of these observations and process modelling to derive new parametrisations; the use of
existing in-situ data and satellite observations of anvils in tropical deep convection to validate the
model; and use of the knowledge gained to improve and test the representation of microphysics
in climate models. In particular, DCMEX will build on the experience of our groups in improving
microphysical representation. A seamless suite of Met Office models will be used for convection-
resolving simulations and global simulations with parametrised convection. Finally, simplified climate
change (imposed warmer environment) experiments will be carried out to understand the role of the
different microphysical processes on cloud feedbacks.
tivity by improving the representation of microphysical processes in global models. It is the anvils
produced by tropical systems in particular that contribute significantly to cloud feedbacks. The anvil
radiative properties, lifetimes and areal extent are the key parameters. DCMEX will determine the
extent to which these are influenced, or even controlled by the cloud microphysics including the
habits, concentrations and sizes of the ice particles that make up the anvils, which in turn depend
on the microphysical processes in the mixed-phase region of the cloud as well as those occurring in
the anvil itself.
There has been a rapid advancement in the sophistication of global climate models in recent
years. Yet some of the equations used to represent microphysics processes are based on a poorer
physical understanding than desired. Gettelman and Sherwood (2016), for example pointed out
that there is significant spread in determining cloud feedbacks across different global models due
to uncertainties in microphysical processes, such as the treatment of ice processes. Ceppi et al.
(2017) also concluded that accurately representing clouds and their radiative effects in global models
remains challenging partly due to the difficulty in representing the cloud microphysics, as well as the
interactions between microphysics and dynamics. The microphysical and radiative processes and dynamics that control the opacity and areal coverage of tropical anvil clouds are not well represented in global climate models.
DCMEX will make novel measurements of cloud microphysics in a real-world laboratory convective cloud system - both the mixed-phase region and anvil - as well as improve and test models
and then apply them globally to tropical deep convective systems. We propose to deploy the FAAM
aircraft along with two dual-polarisation, Doppler radars and airborne and ground-based aerosol
measurements to study the deep convective clouds that form over an isolated mountain range in
New Mexico. The focus will be on the formation of ice from ice nucleating particles (INPs) (primary
ice production) and by processes involving existing ice particles (secondary ice particle production),
such as collisions. These observations will be used to test and further refine the representation of
ice processes in climate models. Our approach recognises that in order to represent cloud feedbacks accurately a model needs to represent the individual processes within the system accurately.
Demonstrating that the model is able reproduce the observed evolution of these clouds is therefore
a necessary condition for the accurate prediction of cloud feedbacks.
The research in DCMEX will have a robust pathway from a novel field campaign to more accurate
estimates of climate sensitivity. This pathway is built with four integrated parts: new observations;
the use of these observations and process modelling to derive new parametrisations; the use of
existing in-situ data and satellite observations of anvils in tropical deep convection to validate the
model; and use of the knowledge gained to improve and test the representation of microphysics
in climate models. In particular, DCMEX will build on the experience of our groups in improving
microphysical representation. A seamless suite of Met Office models will be used for convection-
resolving simulations and global simulations with parametrised convection. Finally, simplified climate
change (imposed warmer environment) experiments will be carried out to understand the role of the
different microphysical processes on cloud feedbacks.
Planned Impact
DCMEX will seek to work with scientists in Leeds that are involved with
the Intergovernmental Panel on Climate Change (IPCC) for example those
working on CONSTRAIN. The IPCC which provides rigorous and balanced
scientific information to decision makers in governments throughout the
world. It will help to reduce the uncertainty in climate sensitivity,
and estimates of aerosol-radiative forcing by advancing our
understanding of cloud processes and cloud feedbacks. The IPCC has
acknowledged that cloud-climate feedbacks are now the greatest
uncertainty in the modelling of future climate, and our research will
lead to reduction in those uncertainties. Specifically, DCMEX will pave
the way to reducing the uncertainty in climate sensitivity by advancing
our understanding of cloud microphysical processes which are currently
poorly constrained, and making improvements to parametrisations in
global climate models. Improved planning for climate change will
deliver enormous economic benefits to society as a whole. The absence of
such plans could lead to losses of billions of pounds. Improved
planning for climate change will deliver enormous economic and societal
benefits and will greatly help with mitigation strategies.
Governments and businesses worldwide, and the general public will
benefit greatly from this research because of the greater accuracy
(reduced uncertainty) in climate model predictions that will result from
this research.
Advancing understanding and modelling of cloud processes, particularly
the ice process, is also very important for improving Numerical Weather
Prediction models. This will have the effect of improving forecasts of
heavy precipitation and other severe weather. We specifically target
deep convection, which is associated with heavy rainfall and hailstorms.
The field campaign will take place in New Mexico, but ice processes are
important for extreme rainfall throughout the tropics and mid-latitudes.
Social and economic benefits are likely to be significant as a result.
For example, improved Met Office forecasting of flash flooding will
benefit the insurance industry (who can take measures to avoid losses),
flood forecasting agencies (e.g. Environment Agency, Scottish
Environmental Protection Agency who can issue warnings) and ultimately,
the wider public affected by flooding episodes. This could even save
lives in extreme circumstances.
This proposal provides a unique opportunity to add urgently-needed
measurements of aerosol and cloud processes. The Global Energy and
Water Cycle Exchanges Project (GEWEX) Aerosols, Clouds, Precipitation
and Climate (ACPC) programme will benefit from the data and modelling in
DCMEX since the aerosols and convective cloud systems will be measured
with state-of-the-art new instruments and an excellent combination of
radars and aircraft.
There is a growing public awareness and sense of urgency about climate
change. The youth climate strikes and the change of language used by The
Guardian newspaper to ``climate emergency, crisis or breakdown'' are
some evidence of this urgency. DCMEX scientists will work with existing
networks and platforms at NCAS and the Universities of Leeds and
Manchester (e.g. The Climate Press podcast) to communicate the results
of the research to schools and the general public.
the Intergovernmental Panel on Climate Change (IPCC) for example those
working on CONSTRAIN. The IPCC which provides rigorous and balanced
scientific information to decision makers in governments throughout the
world. It will help to reduce the uncertainty in climate sensitivity,
and estimates of aerosol-radiative forcing by advancing our
understanding of cloud processes and cloud feedbacks. The IPCC has
acknowledged that cloud-climate feedbacks are now the greatest
uncertainty in the modelling of future climate, and our research will
lead to reduction in those uncertainties. Specifically, DCMEX will pave
the way to reducing the uncertainty in climate sensitivity by advancing
our understanding of cloud microphysical processes which are currently
poorly constrained, and making improvements to parametrisations in
global climate models. Improved planning for climate change will
deliver enormous economic benefits to society as a whole. The absence of
such plans could lead to losses of billions of pounds. Improved
planning for climate change will deliver enormous economic and societal
benefits and will greatly help with mitigation strategies.
Governments and businesses worldwide, and the general public will
benefit greatly from this research because of the greater accuracy
(reduced uncertainty) in climate model predictions that will result from
this research.
Advancing understanding and modelling of cloud processes, particularly
the ice process, is also very important for improving Numerical Weather
Prediction models. This will have the effect of improving forecasts of
heavy precipitation and other severe weather. We specifically target
deep convection, which is associated with heavy rainfall and hailstorms.
The field campaign will take place in New Mexico, but ice processes are
important for extreme rainfall throughout the tropics and mid-latitudes.
Social and economic benefits are likely to be significant as a result.
For example, improved Met Office forecasting of flash flooding will
benefit the insurance industry (who can take measures to avoid losses),
flood forecasting agencies (e.g. Environment Agency, Scottish
Environmental Protection Agency who can issue warnings) and ultimately,
the wider public affected by flooding episodes. This could even save
lives in extreme circumstances.
This proposal provides a unique opportunity to add urgently-needed
measurements of aerosol and cloud processes. The Global Energy and
Water Cycle Exchanges Project (GEWEX) Aerosols, Clouds, Precipitation
and Climate (ACPC) programme will benefit from the data and modelling in
DCMEX since the aerosols and convective cloud systems will be measured
with state-of-the-art new instruments and an excellent combination of
radars and aircraft.
There is a growing public awareness and sense of urgency about climate
change. The youth climate strikes and the change of language used by The
Guardian newspaper to ``climate emergency, crisis or breakdown'' are
some evidence of this urgency. DCMEX scientists will work with existing
networks and platforms at NCAS and the Universities of Leeds and
Manchester (e.g. The Climate Press podcast) to communicate the results
of the research to schools and the general public.
Organisations
Publications
Description | Ice-nucleating particles (INP), essential for initiating primary ice production, have only rarely been measured in the inflow air of convective clouds. They haven't been measured in the New Mexico clouds before. Measurements of INP were made from the FAAM BAe 146 aircraft during flights over and around the Magdalena Mountains. INP concentrations observed were high (0.1 - 1 L-1 at -10 °C) but consistent with previous observations of INP in dominantly continentally influenced air. INP were frequently measured that were active up to -5 °C. Vertically resolved sampling revealed a deep and consistently present coarse aerosol layer extending from 0.5km up to 3km above ground, within which we found that the INP were evenly distributed. Aerosol number and size-resolved compositional properties, derived using data from underwing optical probes and filter analysis with scanning electron microscopy with energy dispersive spectroscopy (SEM-EDX) respectively, were then related to the INP activity of our samples to infer composition and origin. Mineral dust could account for the INP activity seen at low temperatures but not at higher temperatures, which was more consistent with fertile soil dust. Throughout the campaign, there was a change in air mass origin from the northwest to the southeast and back again. However this shift did not significantly affect the INP population. When comparing our INP spectra to the parametrization of primary ice crystal number concentration by Cooper (1986), it was noted that overall, it predicts the range of our INP observations well but does not capture the observed curved shape of INP spectra at higher temperatures. A new parametrisation resulting from the observations was added to the Met Office microphysics module, CASIM for use with the UM. Simulations of cases across the campaign have been produced and are currently being analysed. |
Exploitation Route | Improvements to the Met Office microphysics module, CASIM, have been, and are being made as a result of the work being done as a result of this funding. |
Sectors | Environment |
Title | DCMEX: Collection of in-situ airborne observations, ground-based meteorological and aerosol measurements and cloud imagery for the Deep Convective Microphysics Experiment |
Description | A collection of measurements made for the Deep Convective Microphysics Experiment (DCMEX) project. This includes in-situ airborne observations by the FAAM BAE-146 aircraft, cloud images from 2 NCAS cameras deployed at 3 sites in the area during the course of the field campaign and meteorological and aerosol measurements made at two groundbased stations. DCMEX examined the formation and development of clouds over mountains and was based in the Magdalena Mountains, New Mexico area, between July and August 2022. |
Type Of Material | Database/Collection of data |
Year Produced | 2023 |
Provided To Others? | Yes |
Impact | Has enabled publication of data overview article |
URL | https://catalogue.ceda.ac.uk/uuid/b1211ad185e24b488d41dd98f957506c |
Title | Dataset for Airborne observations of ice-nucleating particles during the 2022 DCMEX campaign, New Mexico |
Description | Deep convective clouds play crucial roles in atmospheric processes, generating lightning, severe weather, and significant rainfall, while their extensive anvils reflect solar radiation. However, models face limitations due to a lack of understanding of microphysical processes in these clouds. Ice-nucleating particles (INP), essential for initiating primary ice production, have only rarely been measured in air directly relevant for convective clouds. This makes separating the roles of primary and secondary ice difficult to resolve. Here we report the abundance and likely composition of INP during the Deep Convective Microphysics Experiment (DCMEX) campaign in New Mexico, USA, using measurements made from the FAAM BAe 146 aircraft during flights over and around the Magdalena Mountains. INP were collected on filters during sampling circuits around the mountain range at varying altitudes and then analysed offline for immersion mode ice-nucleating activity using droplet freezing assays and composition using scanning electron microscopy. |
Type Of Material | Database/Collection of data |
Year Produced | 2024 |
Provided To Others? | Yes |
URL | https://archive.researchdata.leeds.ac.uk/1238/ |