DIFFUSE COMPONENT OF THE SOLAR
ULTRAVIOLET RADIATION IN TREE SHADE
A.V. Parisi1,*, M.G. Kimlin1, J.C.F. Wong2,
M. Wilson1
1Centre for Astronomy and Atmospheric Research, University of
Southern Queensland, Toowoomba, 4350, Australia. Ph: 61 7 46 312226. Fax: 61 7
46 312721. Email: parisi@usq.edu.au
2Centre for Medical and Health Physics, Queensland University of
Technology, GPO Box 2434, Brisbane 4001, Australia. Ph: 61 7 38642585. Fax: 61 7
38641521.
*To whom correspondence should be addressed
ABSTRACT
This paper has provided the first set of quantitative data of diffuse
erythemal UV and UVA in tree shade at a sub-tropical Southern Hemisphere
latitude. Over the summer, approximately 60% of the erythemal UV radiation in
the tree shade is due to the diffuse component. Similarly, approximately 56% of
the UVA radiation in the tree shade is due to the diffuse component. In the tree
shade these diffuse UV percentages are relatively constant from the morning to
noon to afternoon periods. In comparison, in full sun, there is a decrease in
the percentage diffuse UV from morning to noon to afternoon. The exposures to
diffuse UV on a horizontal plane in the tree shade between 9:00 EST to 15:00 EST
were of the order of 4 MED and 14 J cm-2 for erythemal UV and UVA
respectively. The high diffuse UV component in the shade may result in high UV
exposures to not only parts of the body on a horizontal plane that are not
protected, but also, equally high UV irradiances to parts of the body, including
the eyes and face, that are not UV protected.
1. INTRODUCTION
Personal UV exposure to humans is due to sunlight received as both direct
radiation and diffuse radiation. In full sun, the diffuse component is higher
for larger solar zenith angles for similar cloud conditions (Blumthaler et al.,
1994). This diffuse radiation may constitute a significant component to the UV
exposure received by humans’ eyes and skin as it is incident from all directions
and difficult to minimise with the usage of hats, tree shade and shade
structures as it can reach surfaces shaded from the direct component. Modelling
of the diffuse solar irradiances has been previously described (for example,
Bird, 1984). Blumthaler and Ambach (1991) have measured the spectral global and
diffuse solar ultraviolet radiation. The diffuse UV to global radiation ratio
increases with decreasing wavelength due to the stronger Rayleigh scattering at
the shorter wavelengths. Ireland and Sacher (1996) have employed radiometers
with narrow band interference filters to measure the angular distribution of UV
radiation at a Southern Hemisphere site and Blumthaler et al., (1994) have
measured the effects of clouds on the diffuse UV irradiances.
This modelling and measurement by previous researchers of the diffuse UV
irradiances has been in unshaded sunlight. The UV irradiances in tree shade have
been measured (Parisi et al., 1999, Parsons et al., 1998 and Grant, 1997) and
under crop canopies (Grant, 1991) and forest canopies (Flint and Caldwell,
1998). In tree shade, a larger proportion of the UV compared to that in full sun
may be as a result of the diffuse component due to attenuation and filtering of
the direct component. However, no previous research has considered the diffuse
UV irradiances in tree shade. This paper presents the results of quantitative
measurements of the diffuse erythemal and diffuse UVA (320 to 400 nm) at ground
level on a horizontal plane during a Southern Hemisphere sub-tropical summer.
2. MATERIALS AND METHODS
2.1 Irradiance Measurements
The erythemal UV irradiance, UVery is defined as:
(1)
where S(l) is the source UV spectrum, A(l)
is the erythemal action spectrum (CIE, 1987) and the integration is over the UV
wavelengths. The erythemal irradiances and the UVA irradiances were measured
with a radiometer (model 3D V2.0, Solar Light Co., Philadelphia, USA) fitted
with an erythemal sensor and a UVA sensor. Both the erythemal sensor and the UVA
sensor were calibrated against a calibrated dual holographic grating
spectroradiometer with calibration traceable to the National Measurement
Laboratory (Wong et al., 1995). Additionally, for each measurement of the
erythemal and UVA irradiances, the visible irradiances were measured with a LUX
meter (model EMTEK LX-102, supplier, Walsh’s Co., Brisbane, Australia). The
ambient erythemal UV irradiances in full sun on a horizontal plane were
continuously monitored during daylight hours through the summer with a Biometer
(model 501, Solar Light Co., Philadelphia, USA) permanently mounted on an
unobstructed building roof. The Biometer was calibrated against the calibrated
spectroradiometer.
The irradiance measurements were at ground level on a horizontal plane over a
Southern Hemisphere summer in the tree shade on the side of the trunk
furthermost from the sun between 1 December 1998 and 28 February 1999. The trees
employed in the research were forty-two isolated trees in the grounds of the
University of Southern Queensland campus, Toowoomba, Australia at a latitude of
27.5o S. The width of the tree canopies ranged from 2.2 to 13 m, the
tree heights ranged from 6.4 to 25 m and the height above the ground to the
first branches ranged from 0.4 to 10 m. The cloud cover varied between zero
cloud and seven eights of the sky dome covered in cloud as determined by an
observer. The cloud cover and atmospheric conditions vary with time and from day
to day. The measurements over the summer were designed to take into account the
typical cloud and other atmospheric conditions that would be encountered over a
Southern Hemisphere summer.
2.2 Diffuse Irradiances
The diffuse UVery and UVA irradiances were measured by holding a
shadow band approximately 15 cm above the respective detector to shadow it. The
irradiances were measured approximately in the centre of the visible tree shade
for the relevant tree. No measurements were made if there was no shade visible
due to cloud cover. The diffuse UV radiation in both wavebands was also measured
in full sunlight and at least 3 metres clear of any shade. These measurements
were as close as possible in time to the measurements in the tree shade to
minimise the effects of variations in solar zenith angle and atmospheric
conditions.
The diffuse irradiances were measured for each of the trees between 8:30
Australian Eastern Standard Time (EST) and 9:30 EST, 11:30 EST and 12:30 EST and
14:30 EST and 15:30 EST. For the remainder of this paper, these time periods are
referred to as morning, noon and afternoon.
3. RESULTS
3.1 Diffuse UV
The diffuse erythemal UV irradiances as a percentage of the erythemal UV in the
tree shade are presented in Figure 1 for the morning, noon and afternoon. In
comparison, the diffuse erythemal UV irradiances as a percentage of the
erythemal UV in full sun are also shown. The percentage diffuse UVery
irradiances in tree shade range from 19% to 82%, 39% to 80% and 45% to 92% for
the morning, noon and afternoon respectively. Figure 2 provides the percentage
of the UVA in the tree shade at the three time periods. The variation in the
percentages of diffuse UV in both the sun and the shade is most likely due to
the variation in the amount of cloud cover from zero cloud to seven eights cloud
over the summer of the measurements. In the shade, the additional contributing
factor to the variation is any contribution that differences in canopy density
between trees may make on the diffuse UV.
Figure 1 – The percentage diffuse erythemal UV in the (a) morning, (b)
noon and (c) afternoon.
Figure 2 – The percentage diffuse UVA radiation in the (a) morning, (b) noon
and (c) afternoon.
For the majority of the cases, the percentage diffuse UVery and
UVA are higher in the tree shade compared to the respective diffuse irradiance
percentages in the full sun. At noon, there is a better defined separation
between the diffuse erythemal UV in the tree shade compared to the diffuse
erythemal UV in the full sun. In comparison, for the morning and afternoon, the
diffuse erythemal UV in the full sun is in general higher with less difference
between the diffuse UV in the tree shade and the full sun. This is most likely
due to the higher atmospheric pathlength in the morning and afternoon resulting
in higher percentage diffuse UV in the full sun.
In Figure 1 there are two data points in the morning and one data point in
the afternoon with more than 70% diffuse erythemal UV in full sun. Similarly, in
Figure 2 there is one data point in the morning and one data point in the
afternoon with more than 70% diffuse UVA in full sun. These high diffuse
irradiances in full sun were most likely due to the seven eights cloud at the
time on these specific days. The percentage diffuse UVA in Figure 2 is different
to the percentage diffuse UVery in Figure 1, possibly due to the
differences in Rayleigh scattering for the two wavebands.
3.2 Average Diffuse UV
The absolute diffuse UVery and UVA irradiances on a horizontal plane
at ground level averaged over all of the trees in tree shade and in full sun are
provided in Table 1 for the morning, noon and afternoon. The unit for the UVery
irradiances is MED/h, where an MED (minimum erythemal dose) is the amount of
biologically effective UV required to produce barely perceptible erythema after
an interval of 8 to 24 hours following UV exposure (Diffey, 1992). The
error is one standard deviation of the mean. The diffuse irradiances have been
averaged over all of the trees measured over the summer to take into account the
atmospheric conditions encountered over the summer. The diffuse irradiances in
the tree shade may also be affected by the tree parameters such as canopy
density. However, the aim of this paper is to provide a general guide for the
trees employed in the project. The standard error in the diffuse UV radiation is
less than 10%.
The diffuse UVery and UVA irradiances in the tree shade are higher
at noon by 48% and 20% respectively compared to the average of the morning and
afternoon irradiances, most likely due to the higher noon irradiances. Employing
linear interpolation between the three measurement times provides an exposure
due to the diffuse UV to a horizontal plane in tree shade of 4 MED and 14 J cm-2
between 9:00 EST and 15:00 EST for erythemal UV and UVA respectively. For
comparison, the erythemal UV irradiances on a horizontal plane in full sun for a
relatively cloud free day (4 December 1998) and a cloudy day (17 December 1998)
are provided in Figure 3. The units are in MED/15 minutes as 15 minutes was the
recording period of the datalogger on the Biometer. The erythemal irradiances
summed between 9:00 EST and 15:00 EST are 29.1 MED and 25.4 MED for the cloud
free and cloudy days respectively.
Table 1 – The diffuse UVery and UVA irradiances averaged over all
of the trees in tree shade and in full sun.
| Waveband |
Diffuse UV Radiation
|
| |
Tree Shade
|
Full Sun
|
| |
morning
|
noon
|
afternoon
|
Morning
|
Noon
|
afternoon
|
| UVery (MED/h) |
0.56± 0.02
|
0.80± 0.06
|
0.52± 0.03
|
0.70± 0.03
|
0.90± 0.03
|
0.77± 0.04
|
| UVA (mW cm-2) |
0.61± 0.03
|
0.72± 0.06
|
0.59± 0.03
|
0.73± 0.04
|
0.82± 0.03
|
0.77± 0.03
|
Figure 3 – Erythemal UV data for a relatively cloud free day and a cloudy day
in summer.
The averages over all the trees of the percentage diffuse UV radiation in the
tree shade compared to the UV in the tree shade and the percentage diffuse UV
radiation in the full sun compared to the UV in full sun are provided in Table
2. Additionally, the percentage diffuse visible radiation in tree shade and full
sun are provided for comparison. The error is one standard deviation of the
mean.
For the summer measurements in this research, the percentage diffuse
radiation of UVery in the tree shade is relatively constant at about
60% from the morning period to the afternoon period. In comparison, as expected
due to the longer atmospheric pathlength causing additional scattering in the
morning and afternoon, the percentage diffuse radiation in the full sun is
higher in the morning and afternoon compared to that at noon. The differences
between the visible waveband and the erythemal UV of the percentage diffuse
radiation in the tree shade was approximately the same in the morning, noon and
afternoon time periods. In comparison, the same difference in the full sun
varies over the three periods.
Table 2 – Average over all the trees of the percentage diffuse UV and visible
irradiances in tree shade and in full sun.
| Waveband |
Percentage Diffuse Radiation (%)
|
| |
Tree Shade
|
Full Sun
|
| |
morning
|
noon
|
afternoon
|
Morning
|
Noon
|
afternoon
|
| UVery |
60± 2
|
60± 2
|
61± 2
|
39± 2
|
26± 1
|
46± 3
|
| UVA |
54± 2
|
57± 3
|
56± 2
|
26± 2
|
20± 1
|
28± 2
|
| Visible |
53± 3
|
54± 3
|
54± 4
|
21± 4
|
14± 1
|
19± 3
|
DISCUSSION
Quantitative measurements and research on UV radiation in different environments
and settings is vital in developing and assessing UV preventative strategies for
the reduction of skin cancer and other UV related problems for humans. This
paper has provided the first set of quantitative data of diffuse erythemal UV
and UVA in tree shade at a sub-tropical Southern Hemisphere latitude. Over the
summer, approximately 60% of the erythemal UV radiation in the tree shade is due
to the diffuse component. Similarly, approximately 56% of the UVA radiation in
the tree shade is due to the diffuse component. The standard error in the set of
measurements is less than 10%. These values approach the percentage diffuse UV
component in full sun for winter. However, in the tree shade they are relatively
constant from the morning to noon to afternoon periods. In comparison, there is
a decrease in the percentage diffuse UV in full sun at noon compared to the
morning and afternoon. For the erythemal UV, the decrease is from approximately
40% in the morning and afternoon to 26% at noon. The tree shade has increased
the diffuse component in summer from 26% to 60% at noon and from approximately
40% in the morning and afternoon to 60%.
This high percentage of diffuse radiation has a consequence that the UV
protective capability of hats for the relatively high UV irradiances in tree
shade (Parisi et al., 1999, Parsons et al., 1998), while useful, is not as high
as in full sun. The exposures to diffuse UV on a horizontal plane in the tree
shade between 9:00 EST to 15:00 EST were of the order of 4 MED and 14 J cm-2
for erythemal UV and UVA respectively. This high diffuse UV component in the
shade may result in high UV exposures to not only parts of the body on a
horizontal plane that are not protected, but also, equally high UV irradiances
to parts of the body, including the eyes and face, that are not UV protected.
Acknowledgments – This research was partially funded by
Queensland Department of Health. Two of the authors (MK and MW) were employed
through the funding. The authors also acknowledge Ken Mottram, Oliver Kinder and
Graeme Holmes in Physics, USQ for their technical assistance in this project.
REFERENCES
Bird, R.E. 1984, "A simple, solar spectral model for direct-normal and diffuse
horizontal irradiance," Solar Energy, vol.32, pp.461-471.
Blumthaler, M., Ambach, W. & Salzgeber, M. 1994, "Effects of cloudiness on
global and diffuse UV irradiance in a high-mountain area," Theoretical and
Applied Climatology, vol.50, pp.23-30.
Blumthaler, M. & Ambach, W. 1991, "Spectral measurements of global and
diffuse solar ultraviolet-B radiant exposure and ozone variations,"
Photochemistry and Photobiology, vol.54, pp.429-432.
CIE (International Commission on Illumination) Research Note 1987, A
reference action spectrum for ultraviolet induced erythema in human skin,
CIE J. 6, 17-22.
Diffey, B.L. 1992, "Stratospheric ozone depletion and the risk of
non-melanoma skin cancer in a British population," Physics in Medicine and
Biology, vol.37(12), pp.2267-2279.
Flint, S.D. & Caldwell, M.M. 1998, "Solar UV-B and visible radiation in
tropical forest gaps: measurements partitioning direct and diffuse radiation,"
Global Change Biology, vol.4(8), pp.863-870.
Grant, R.H. 1991, "Ultraviolet and photosynthetically active bands: Plane
surface irradiance at corn canopy base," Agronomy Journal, vol.83(2),
pp.391-396.
Grant, R.H. 1997, "Biologically active radiation in the vicinity of a single
tree," Photochemistry and Photobiology, vol.65(6), pp.974-982.
Ireland, W. & Sacher, R. 1996, "The angular distribution of solar
ultraviolet, visible and near-infrared radiation from cloudless skies,"
Photochemistry and Photobiology, vol.63(4), pp.483-486.
Parisi, A.V., Willey, A., Kimlin, M. & Wong, J.C.F. 1999, "Penetration of
solar erythemal UV radiation in the shade of two common Australian trees,"
Health Physics, vol.76(6), pp.682-686.
Parsons, P., Neale, R., Wolski, P. & Green, A. 1998, "The shady side of solar
protection," Medical Journal of Australia, vol.168, pp.327-330.
Wong, C.F., Toomey, S., Fleming, R.A. & Thomas, B.W. 1995, "UV-B radiometry
and dosimetry for solar measurements," Health Physics, vol.68(2),
pp.175-184.
