Spring is the Time to
Begin a Science Project
Forrest M. Mims III
Recently an active member of the Society
for Amateur Scientists (SAS) wrote to ask about how
best to pursue a particular kind of research to a point
that would result in a paper in a scholarly journal
of science. Even more recently, a paper by another SAS
member was published in a distinguished journal. A news
story about this will appear in a forthcoming issue.
Developments like these are the best
possible news in the world of citizen science. Many
similar stories about the accomplishments and discoveries
of diligent citizen scientists have appeared in The
Citizen Scientist.
If you are not already engaged in
a regular science activity or project, I invite you
to consider beginning one in 2005. You have many choices,
ranging from astronomy to zoology. One strong candidate
is to collect a time series of data about anything that
interests you. There are countless parameters just waiting
to be measured by an alert and disciplined citizen scientists.
Many parameters like weather, haze, traffic noise, sunlight,
cloudiness and pedestrian numbers can be measured every
day. Others can be observed occasionally, including
contrails, severe weather events and plant growth. Still
others can be observed only a few times a year, including
bud burst, acorn size and abundance, tree girth and
so forth. Many observations like these can be accomplished
with only minimal instrumentation or even none at all.
A time series of observations of parameters
like these can lead to completely unexpected discoveries
and even scientific papers. I learned this first hand
soon after beginning to make regular measurements of
the sun and sky 17 years ago.
In May 1988, I began making regular
measurements of direct solar ultraviolet-B (UV-B) in
the field outside the tiny 2-room farm house that serves
as my office and shop. By 4 February 1990, I was using
a suite of homemade instruments to measure direct UV-B,
the total amount of ozone and water vapor in a column
through the atmosphere and the aerosol optical depth
(or thickness) of the atmosphere. Sky appearance is
noted, and temperature, relative humidity, dew point
and pressure are measured. The main measurements are
made at or near local solar noon on every day the sun
is not obscured by clouds.
In 1995 I added a wide range of full-sky
irradiance measurements to the daily observations. These
include measurements of UV-B and photosynthetic radiation.
In 1998 I added photographs of the solar aureole (the
haze-modulated glow around the sun), the zenith sky
and the sky over the north horizon. In 2001 fisheye
photographs of the full sky were added.
This research
program has resulted in a number of discoveries
that were published in various scientific journals (and
more papers are on the way). These papers attracted
the attention of professional scientists and resulted
in various assignments to take my instruments to Japan
(for the Environmental Protection Administration) and
Brazil (for NASA's Goddard Space Flight Center). They
also attracted the attention of Dr. James Slusser, Program
Director of the United States Department of Agriculture
(USDA) UVB
Radiation Monitoring Program. One year ago the latest
USDA UV-B site was placed nearby on the roof of the
Moody Science Building at Texas Lutheran University
in Seguin, Texas. This sophisticated array of automated
instruments is now providing a major boost to the 15
years of regular measurements I've been making manually.
Spring is a great time to begin a measurements
program. I started mine in May, and I hope to stay with
it for at least 25 years. You can do the same thing,
and now is not too early to start making plans. You
don't need to conduct your project for as long as I
have to make discoveries and establish a data base.
And don't worry if you lack academic preparation in
the science you choose to pursue. Do-it-yourself background
research, hands-on experience and perseverance are more
important to a successful science project than a stack
of degrees. 
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