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Yusuf Hamied Department of Chemistry

 

Professor Rod Jones

Professor of Atmospheric Science

Observational studies of atmospheric structure and photochemistry: from climate change to air pollution and human health

In our group we use a wide range of measurement and modelling techniques to study the chemical composition and physical structure of the earth’s atmosphere.

The atmosphere controls much of the complex environment in which we live. Ozone in the stratosphere protects us from harmful shortwave solar radiation, while changes in CO2 and other greenhouse gases are influencing the world’s changing climate. In the troposphere, chemical processes act to remove many unwanted species, while at the same time contributing to poor air quality, impacting the health of many, and leading to millions of premature deaths, particularly in the developing world. 

 

Low cost sensors for monitoring urban pollution

We develop low cost air quality sensors which allow us to probe urban pollution in unprecedented detail.  You can find out more by watching our short video above. 

 NO and NO2 levels in Cambridge on one afternoon, illustrating how complex urban air pollution can be.

As part of our research we are demonstrating how these low cost air quality sensor networks can be used to address important scientific and political questions. Studies include low cost sensor network deployments at Heathrow airport, in Beijing and in Delhi. 

Results from a recent sensor network deployment at Heathrow Airport, used to both quantify airport emissions and provide a prediction of the likely impact of an airport expansion.

Air quality and human health 

We use portable air quality sensors to test the linkages between exposure to pollution and health impacts. These units allow us to develop activity models which we can use to predict air pollution dose far more accurately than before.  They are now used for studies of Chronic Obsructive Pulmonary Disease (COPD) in London, and wider health impacts (Beijing and elsewhere).

A portable air quality sensor used by the group, which includes GPS and accelerometers, with illustration of measurements.

Other projects

Other projects within the group range from using cavity ringdown spectroscopy and its variants for making ultrasensitive (sub-ppt level) airborne and ground based measurements of radical species (using the FAAM aircraft), balloon borne measurements of GHGs, volcanic emissions and many more.

Selected Presentations

AAMG Presentation 2016

Further information

If you are interested in joining us as a graduate student or postdoctoral researcher, please contact me at rlj1001@cam.ac.uk.  

Publications

Accuracy of temperatures from UKMO analyses of 1994/95 in the Arctic winter stratosphere
S Pullen, RL Jones
– Geophysical Research Letters
(1997)
24,
845
(doi: 10.1029/97GL00754)
A novel broad-band UV-visible laser ranging spectrometer for the measurement of tropospheric constituent profiles from the ground
AM South, IM Povey, AT DeRoodenbeke, RA Freshwater, RL Jones
– PROCEEDINGS OF EUROTRAC SYMPOSIUM '96 - TRANSPORT AND TRANSFORMATION OF POLLUTANTS IN THE TROPOSPHERE, VOL 2
(1997)
643
(link to publication)
An intercomparison of ground‐based UV‐visible sensors of ozone and NO2
G Vaughan, HK Roscoe, LM Bartlett, FM OConnor, A Sarkissian, M VanRoozendael, JC Lambert, PC Simon, K Karlsen, BAK Hoiskar, DJ Fish, RL Jones, RA Freshwater, JP Pommereau, F Goutail, SB Andersen, DG Drew, PA Hughes, D Moore, J Mellqvist, E Hegels, T Klupfel, F Erle, K Pfeilsticker, U Platt
– Journal of Geophysical Research
(1997)
102,
1411
(doi: 10.1029/96jd00515)
UV‐visible absorption cross sections of gaseous Br2O and HOBr
OV Rattigan, DJ Lary, RL Jones, RA Cox
– Journal of Geophysical Research
(1996)
101,
23021
(doi: 10.1029/96JD02017)
Measurement of atmospheric NO3 1. Improved removal of water vapour absorption features in the analysis for NO3
SR Aliwell, RL Jones
– Geophysical Research Letters
(1996)
23,
2585
(doi: 10.1029/96GL02472)
Measurement of atmospheric NO3 2. Diurnal variation of stratospheric NO3 at midlatitude
SR Aliwell, RL Jones
– Geophysical Research Letters
(1996)
23,
2589
(doi: 10.1029/96gl02473)
A Novel Flash Photolysis/UV Absorption System Employing Charge-Coupled Device (CCD) Detection:  A Study of the BrO + BrO Reaction at 298 K
DM Rowley, MH Harwood, RA Freshwater, RL Jones
– The Journal of Physical Chemistry
(1996)
100,
3020
(doi: 10.1021/jp951825b)
Interpolation errors in UV-visible spectroscopy for stratospheric sensing: Implications for sensitivity, spectral resolution, and spectral range
HK Roscoe, DJ Fish, RL Jones
– Appl Opt
(1996)
35,
427
(doi: 10.1364/AO.35.000427)
Two-dimensional modelling of some CFC replacement compounds
O Wild, OV Rattigan, RL Jones, JA Pyle, RA Cox
– Journal of Atmospheric Chemistry
(1996)
25,
167
(doi: 10.1007/BF00053790)
Br 2 -sensitised decomposition of ozone: kinetics of the reaction BrO + O 3 → products
OV RATTIGAN, RA COX, RL JONES
– Physical Chemistry Chemical Physics
(1995)
91,
4189
(doi: 10.1039/ft9959104189)
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Research Group

Research Interest Group

Telephone number

01223 336466

Email address

rlj1001@cam.ac.uk

College

Queens' College

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    About the University

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