Clouds Over Storm Lifecycles
Displaying Cloud Data for Easy Interpretation
By Jose A. Alburquerque
Clouds are one of the most important temperature regulators of the
earth. It is known, for example, that low thick clouds cool the earth.
If these low thick clouds increase due to climate change, the warming
problem could essentially be undone. On the other hand, if they decrease,
the problem will worsen. The study of clouds, however, is difficult when
the data pertaining to clouds is not easily accessible for interpretation.
The purpose of this research project is to facilitate the visualization and
manipulation of cloud data to allow its easy interpretation. This is
accomplished through a series of mini-applications (or applets) which
access the raw data and then display the data using a color scheme.
They also allow the user to select areas of the data set for a more indepth
study of that area. The applets are written in the Java programming
language and embeded in Hypertext Markup Language (HTML) documents
(or Web pages) to allow Internet usage. The applets are developed by
means of a Java Integrated Development Environment (IDE) which makes
the development of Java programs faster and easier. The results are
reliable, error-free applets that provide insight into many cloud
intricacies allowing cloud research to proceed smoothly.
The Role of Clouds In Midlatitude Storms
By Andrew Audry
Clouds can either heat or cool the earth. High thin clouds trap
radiation generating a warming effect. Low thick clouds reflect solar
radiation creating a cooling effect. Mid-Latitude storms generate large
amounts of clouds. NASA scientists simulate storms in their Global Climate
Model (GCM). However, they're not sure how storm factors such as sea
level pressure and wind speed contribute to different types of clouds.
By studying the production of different clouds in actual storms from
April 1988 we formed hypotheses which may help improve the GCM. To study
storms we used an application that displays International Satellite Cloud
Climatology Project (ISCCP) satellite data; optical thickness, cloud top
pressure, and weather station data; such as sea level pressure and surface
tempurature. We compared cloud optical thickness and cloud top pressure to find
the location of certain clouds; we also identified the sea level pressure
to classify the storms by strength. To develop a storm factor, we used
sea level pressure and wind strength, which determine the strength of
a storm and compared that data to the percentage of rain clouds in storms.
Our analysis found that the thinnest mid-altitude clouds reside around
warm fronts. From our comparison of the storm factor and the percent of
deep convective rain clouds we found that, similar to hurricanes, as
mid-latitude storms get stronger more rain clouds are formed. By
comparing the storm factors and the percentage of deep convective clouds
we found that if stronger storms occur in the future they will produce
more rain clouds.
Is There a Relationship between Cloud Properties and Storm Strength in Tropical Storms?
By Juan Clavijo
Hurricanes are one of the most destructive tools of nature. Humans
can also use them as tools, to study how physical characteristics of
the storms are related to the properties of the clouds produced by those
storms. Clouds are known to have effects on the Earth's global temperature.
Low thick clouds block solar radiation and have little effect on infrared
radiation due to the small temperature difference between the cloud and
the surface. This produces a cooling effect. High thin clouds cause
warming effects. Tropical storms (hurricanes) follow the idea of a
perfect storm, with a low sea level pressure, a compact size, and a
cyclonic behavior. They are easily isolated for analysis. By better
understanding how the strength of tropical storms interact with their
cloud properties similar questions for larger, more complex storm systems like
mid-latitude storms, the major cloud producers, may be found. I
investigated ten tropical storms in order to examine the relationship
between the storm properties and the properties of the clouds produced
by the storms. I used satellite data for the cloud properties and
ground based data for the storm properties. I compared two cloud
properties: cloud optical thickness and cloud top pressure (height), to four
storm properties: maximum wind speed, minimum sea level atmospheric pressure,
tracks and the storm's life cycle in order to discover any correlations
between these properties. My analysis showed that in the first and
second stage of the tropical storms as the strength increases the amount
of deep convective (high thick) clouds also increases. I saw the opposite
effect in the third stages of these storms. I also observed that storms
dying out over land had a greater amount of deep convective clouds than
storms that died over water. During the lifecycle of these storms the
amount of deep convective clouds increased from the first to the second
stage and decreased during the third stage. In the future if more
strong storms occur they will result in a greater amount of thick clouds
which can lead to global cooling. These findings may also prove useful
in the analysis of more complex systems like mid-latitude storms.
The Significance of Clouds Produced by Mid-latitude Storms
By Sharika De La Oz
Clouds will have an effect on future global climate change. High,
thin clouds act as a warming blanket by letting most of the sunlight
through and trapping heat from the surface. Low thick clouds let only
a small amount of sunlight through and therefore have a cooling effect.
Scientists use computer models to predict how clouds might affect climate
change, but are unsure of how clouds are formed in real storms.
Mid-latitude storms are the major producers of clouds. We need to
investigate the cloud types made by these storms and how these clouds
are formed before being able to suggest improvements to the NASA/GISS
computer climate model. We used weather station data to identify storms
based on low sea-level atmospheric pressure and to locate where the
cold and warm fronts were for each storm. We used satellite-imaging
data to classify cloud types. Finally we attempted to relate these
cloud types to the general characteristics of storms. Our most
significant findings were that generally the thickest clouds of a storm
form along or near the cold front. The thinner clouds tend to form
along or near the warm front of a storm. We also observed that the
amount of rain clouds in a mid-latitude storm increases with the strength
of the storm and it was a high correlation. Our results will enable
us to compare the computer climate model's storms to real world storms
and determine if the model produces similar storm cloud distribution.
Our results already show a similarity between hurricanes and mid-latitude
storms, in that more rain clouds are produced with stronger storms.
Do Stronger Storms Occur Under Conditions Similar To Global Warming?
By Christopher Petersen and Jericco Tolentino
Several computer programs that simulate planetary climate conditions
predict that if global warming occurs there will be a decrease in the
overall number of storms that occur. This will be accompanied by an
increase in the occurrence of the strongest storms. Will this happen in
the real world? We hypothesize that by comparing years in the real
world during which conditions resemble those under global warming with
years that are more normal, we can approximate the changes that the
earth may experience under global warming. We defined a storm's strength
in terms of the minimum sea level atmospheric pressure that occurs during
that storm. We examined the sea level pressure for the entire globe
from 1979-1996 and determined the distribution of storm strengths for
each month. We then examined the surface temperatures to select five
winters that exhibited characteristics most similar to those under
global warming and five winters that were more similar to normal
conditions. We compared the total storm distribution in both categories
to highlight the changes in storm intensities that may occur during
global warming. Unlike the predictions made by the models, we observed
that more storms overall were produced during warming conditions, due
mainly to an increase in the number of weaker storms. There was however,
an increase in the number of strongest storms during the years with
warming conditions as predicted by the model. Our results are
inconclusive. This may be due to the fact that there were no
significant climate changes during this time period. We may need to
examine changes over a longer time period, or reexamine our definition
of a storm before being able to determine the validity of our
hypothesis.
Jose Alburquerque is a student at the
City College of New York; Sharika De La Oz, Juan Clavijo, and Andrew
Audry are students at A. Philip Randolph High School; Christopher
Petersen is a teacher at A. Philip Randolph High School; and Jericco
Tolentino is a student at Brown University.
(August 1998)
1998 Abstracts :
Forcings and Chaos ||
Oceans ||
Radiation ||
Clouds
Impacts ||
Methane ||
Aerosol Emissions ||
Pollen ||
