Report on Adopting Groasis Waterboxx for Water Saving Measures at the La PrimaVera Coop

Report: the Groasis waterboxx©
ISTC 01 Technical Communication Techniques
Final report
Diego Schiavon, student number #7937
Potential adoption of water-saving measures by members
of the cooperative
This report has been prepared by Diego Schiavon for the management
board of the La Primavera agricultural cooperative.

ISTC 01 Technical Communication Techniques - Diego Schiavon, #7937 Page i
Report: the Groasis waterboxx
Copyright and Disclaimer Notice
AquaPro, Groasis and waterboxx are registered
trademarks of AquaPro BV.
All pictures and illustrations of the Groasis
waterboxx shown in this report are subject to
the copyright and usage restrictions of
AquaPro BV.
The La Primavera logo is a registered
trademark of Cooperativa Agricola La
Primavera Scarl.

ISTC 01 Technical Communication Techniques - Diego Schiavon, #7937 Page i i
Executive summary
This report presents the Groasis waterboxx and can be used by the members of the management board to
form an opinion about the device. It consists of ten sections, covering the history of the device, its
components and usage, some suggestions about the installation, the available test results and a concluding
evaluation
The first three sections present the historical background of the waterboxx from the prototype stage to the
present, a physical description of the device and a general explanation of the principles used to design it.
Drawings of the device and graphical illustrations of its usage are included as well.
The fourth section lists the single components of the device and their function, and provides some
graphical illustration of how the waterboxx is to be assembled. The fifth section expands on the previous
one, lists the different steps necessary to install a waterboxx, provides some brief suggestions about
planting materials and strategies, and concludes with instructions about removing the device.
Section 6 describes the data collection techniques and experiment designs to be used when testing the
waterboxx, with some practical suggestions about the experiment setup. Section 7 lists some of the
species used in the past for test purposes, and the countries where these tests have taken place. The
evidence gathered from the tests is briefly evaluated in section 8.
Section 9 evaluates the compatibility with organic regulations, both at a national and supernational level,
and concludes that the waterboxx is most likely to be suitable for organic farming, although the
cooperative technical service and the certifying agency should be contacted to confirm this.
Finally, a general evaluation and a recommendation is presented in the conclusion.

ISTC 01 Technical Communication Techniques - Diego Schiavon, #7937 Page i i i
Table of contents
Introduction
1 About the waterboxx
2 A short description
3 Waterboxx: the concept
4 The components
5 Using the waterboxx
5.1 Soil preparation
5.2 Orientation
5.3 Laying the paperboard
5.4 Planting the seedlings
5.5 Placing the water tank
5.6 Mounting the waterboxx
5.7 Final preparations
5.8 Removing the waterboxx
6 Logging procedure
7 Experiments
8 Test results
9 Suitability for organic farming
10 Conclusion
References
Addenda
Item I: International Groasis waterboxx plantings 2010/2011
Item II: the AquaPro pricelist
1
2
3
4
5
6
6
6
6
7
7
7
7
8
9
10
10
11
12
13
I
II
IV

ISTC 01 Technical Communication Techniques - Diego Schiavon, #7937 Page 1
This report has been requested by the management board to establish whether the cooperative should use
the waterboxx©, a device to farm without irrigation. The wateboxx has recently received media attention
as a device that makes it possible to farm marginal, arid lands: this is of importance in the light of
increased competition on the market and lower food prices.
The present report is a collection of available information about the Groasis waterboxx, its history,
components, usage and applications. The members of the management board should use this report to
form an opinion about the product. An assessment of this product is provided in the concluding section.
As described in the report, the waterboxx is a device that could prove useful on the chalk- and sulphate-
rich fields of our Southern members, as well as improve water drainage on our peach, apple and pear
fields in the North. However too few test results have been published, and therefore it is the
recommendation of this report that this product should not be used until more data become available.
The Cooperative could discuss the possibility of carrying out their own tests with the support of the
Technical Service.
Introduction

Pieter Hoff (1953) is a
Dutch inventor and
businessman. He has a
wide agronomical
background,
accumulated while
running his family
nursery garden. In
2003 he decided to
sell his company and
focus on developing a
strategy to fight
desertification. In the
prologue to his 2008 book "CO2, a gift from
heaven", he writes that he was motivated by
frustration at the pitiful state of the Italian
Apennines around Naples, once lush with
vegetation and now abandoned to erosion1.
The Groasis waterboxx is the result of his
research, culminated in 2004 with a prototype: a
round, donut-shaped plastic box with a 20-inch
radius; once filled with water, it sequestrates more
water from the atmosphere in the form of
condense and drips it down to the seedlings
planted in its middle. It allows plants to grow
under extremely harsh conditions on desert soils
and even rocks.
Mr. Hoff extensively tested his invention on arid
soils, first in his native Holland, and then in the
Moroccan Sahara, in Zaragoza (Spain) and
California (USA). The testing phase lasted four
years, from 2005 until 2010, and resulted in
improvements on the prototype design. Further
testing was conducted starting in 2010 in Spain,
Morocco, Kenya and California. In total, over
15,000 waterboxxes with trees will have been
tested in 20 research and demonstration areas2.
The test in Morocco was conducted with the
support of the University of Oujda, Morocco. The
results are presented on Mr. Hoff's company
website, www.groasis.com. He claims that after
four years, 88,2% of the trees planted with a
waterboxx were in good condition, with 11,8%
alive but "weak". Of the control group, consisting
of trees irrigated weekly but without the
waterboxx, 89,5% died, and 10,5% were alive and
in good condition3. Mr. Hoff also claims that
plants survive once the waterboxx is removed4.
The waterboxx project attracted media attention
ever since the testing phase: the first articles in the
national press appeared in 20075 and the invention
was soon mentioned in newspapers in the English-
speaking world and beyond. In 2008, the
waterboxx was awarded the prestigious Dutch
BètaDragon Award and 10,000EUR6. Finally, in
November 2010 the American magazine Popular
Science awarded it the 2010 Grand Award of
Green Tech and the Overall Award of Popular
Science7. Petrus Hoff was invited to present his
invention at the PopTech 2010 conference in
Camden, Maine. The appearance in Popular
Science greatly increased the popularity of the
waterboxx.
The project also attracted public funding: the
Dutch Ministry of Economic Affairs, the Dutch
Province of Brabant and the EU EFRO-
Programme OP Zuid 2007-2013 contributed part
of the money to make the latest innovations
possible8.
The Groasis waterboxx is the means to a much
more grandiose end: stopping climate warming
and feeding the world not through government
regulation, but by planting trees on marginal, non-
productive lands. Mr. Hoff's views are laid out in
his 2008 book, "CO2: a gift from heaven", where
he calls for a global effort to reafforest 2 billion ha
worldwide9.
1 About the Groasis waterboxx
Fig. 1 Petrus (Pieter) Hoff, inventor
of the Groasis waterboxx.
Fig. 2 A waterboxx installed on arid soil in Oman

The waterboxx is a circular water tank made of
plastic with a radius and height of 25 cm. It is
covered by a corrugated plastic sheet slanting
inwards towards the center, where a tubular
opening allows for the planting of one or two
seedlings. The sheet covers a circular tank to be
filled with water.
Along the tubular
opening are two
small pipes: the
plastic sheet is
supposed to
sequestrate water
from the atmosphere
in the form of
condense, which
then slides towards
the central tubular
opening and reaches the water tank through the
small pipes.
The tubular opening can accomodate one, two or
three plants, depending on the model. The model
with a double opening is more recent, and arose
from the need to reduce the economical damage if
the only plant dies. AquaPro, the company
producing the waterboxx, recommends to cut the
smaller of the two plants.
On the bottom of the water tank there is a wick,
whose purpose is to drip small quantities of water
into the soil; the waterboxx can also be installed
without the overflow pipe.
Optionally, the device can be provided with two
wind protectors to anchor it to the soil and prevent
it from being blown away by strong winds. Two
nails are necessary for each anchoring pin.
The waterboxx is available in polypropylene or in
a biodegradable product called Ecopur: the former
can be re-used several times, while the latter is to
be used only once and then left to decompose,
particularly in remote regions and extremely poor
soils.
2 A short description
Fig. 3 A drawing of the waterboxx
as shown on the AquaPro website.

The waterboxx is a work of bio-mimicry: an
imitation of how nature works. Mr. Hoff observed
that while humans cultivate by plowing the soil,
under natural conditions the seeds are first
dispersed (for example by animals) and then
germinate directly in the topsoil, i.e. the top ~10cm
soil layer. Plowing destroys the capillary canals
present in the soil, but in nature they stay intact and
help retain the humidity necessary for the seed to
germinate.
Zoochory, or seed transportation by animals,
provides another lesson on how to protect a
growing seedling: a seed ingested by an animal and
then excreted with the feces can use the water and
nutrients in the feces to grow. The feces also
prevent evaporation and keep the water stored in
the subsoil capillary canals.
Finally, many plants survive in extremely arid
conditions by absorbing morning dew and
occasional fog, like Tillandsia spp. and some
lichens and pine seedlings10.
The waterboxx design takes the points above into
account: the seed is sown on the topsoil without
damaging the subsoil capillaries, and the
waterboxx is put on top of it. The waterboxx,
basically a round hollow plastic tank, prevents
water evaporation just like animal feces do in
nature; finally, the water tank creates a temperature
differential that causes water vapour condensation.
The waterboxx tank, filled with water, will stay
cooler in the morning when the outside air
temperature starts to rise. The difference between
the lower inside temperature and the higher outside
temperature causes the atmospheric water vapor to
condense on the outside cover of the waterboxx.
From there, it drips through internal tubes to the
inside water tank and is then conveyed to the
underneath soil by means of a wick. The system is
able to collect rainwater in a similar way.
The waterboxx has the advantage of stabilizing soil
temperature: the water present in the tank and the
water regularly dripped into the soil can buffer
temperature fluctuations because of water's high
specific heat capacity, i.e. the high amount of
energy necessary to alter water temperature. Mr.
Hoff claims the soil temperature below the
waterboxx is about 25°C11. This is a very important
feature for a product to be used in desert areas,
where daily temperature excursion can run in the
dozens of Celsius degrees and plants may not be
able to survive.
Temperature regulation is not limited to the soil,
but extends to the plant micro-climate as well. The
young plants are surrounded by the waterboxx
water tank: the inside water absorbs heat during the
day and releases it during the night, stabilizing air
temperature around the plant. And as long as the
plant is smaller than the waterboxx height, it is
protected from strong and dry winds as well.
By completely surrounding the plants, the
waterboxx also has the advantage of preventing
weed growth and of protecting the plant from
damage by rodents12. Labor costs for weeding are
also reduced.
3 Waterboxx: the concept
Fig. 4 The wick drips approximately of 50 ml per day in the soil
under the waterboxx.
Fig. 5 The primary root reaches water 2 meters underground.

The waterboxx consists of seven different
components:
Water tank: the water
tank is the main body of
the device. It is circular
or elliptical in shape and
delimited by 25cm-high
edges. In the center, a
tubular duct opens to
uncover a small portion
of the underlying ground. The mid-plate and the
cover sheet can be secured to the tank structure.
Additionally, two openings at the bottom of the
tank can accommodate the wind protectors, and a
hole can accommodate the wick;
Wick: the wick is a cotton
pipe of 25cm of length. It
must be inserted in the
hole at the bottom of the
water tank, with about half
the length inside the tank
and half outside. It drips
water collected in the tank
from the atmosphere into
the underlying soil;
Mid-plate: the mid plate is a plastic disc slightly
smaller in radius than the water tank. It has an 8-
shaped hole allowing for the central opening in the
waterboxx, and a further hole to let water inside
from the top opening in the cover sheet. The mid-
plate needs to be secured
to the water tank. It
separates the water from
the outside air: the shaft is
cooler than the outside in
the morning, and causes
water vapor condensation
on the plastic cover sheet;
Cover sheet: the cover sheet is a corrugated,
round plastic sheet that slopes inwards towards the
center at an angle of 45 degrees. It has an 8-shaped
opening in the middle, a simple compass shape for
easier orientation, two smaller holes to secure the
siphons and a round hole from which water can be
added to the tank. The corrugation pattern allows
the condense droplets to easily flow downwards
towards the siphons,
from where they reach
the tank and, through the
wick, ultimately the
ground. The cover sheet
also doubles as a
growing surface for
climbing plants like
tomatoes or pumpkins;
Wind protectors: the wind protectors are small
plastic plaques shaped like the AquaPro logo (see
Fig. 5 and 8). The can be clicked into place at the
bottom of the water tank and need to be nailed into
the ground to prevent wind damage. They are
optional and need to be ordered separately.
Alternatively, some rocks or heavy material can be
used to hold down the water tank;
Siphons: the siphons are two small pipes to be
inserted next to the central opening on the cover
sheet. They gather the water from the cover sheet
and convey it to the underlying tank;
Cap: this is is a round plastic
cap sealing the water tank and
the whole waterboxx. When
open, water can be poured into
the inside. Otherwise it should
always be kept closed to
prevent evaporation.
Additionally, the installation set consists of a
paperboard to be laid on top of the seedlings (see
Fig. 11 on the following page). This is the first
protection against evaporation and can have one,
two or three holes, depending on the number of
seedlings to be used per box.
4 The components
Fig. 5 The water tank, the main
body of the waterboxx.
Fig. 6 The cotton wick at the
bottom of the tank.
Fig. 7 The mid plate mounted
on the tank.
Fig. 8 The cover sheet mounted
on top of the mid-plate.
Fig. 9 The cap and the
siphons.

A number of variables have to be taken into
account while designing a waterboxx installation,
such as climate, temperature, rainfall, soil or
growing medium, wind and sun exposure.
Installing the waterboxx requires the following
steps:
It is crucial that the waterboxx is levelled
horizontally and to guarantee efficient collection of
the condensed water. The underlying soil must be
horizontal as well and free from rubble. Aquapro
suggests to dig a hole with a diameter of 60 cm and
a depth of maximum 10 cm; the dug up earth will
be used later on in the installation to protect the
waterboxx from the wind blowing underneath the
water tank.
Some rocky terrains have developed no soil at all,
or what there is is too hard for water to penetrate,
as in the case of a hardpan developing on top of
limestone soils. In these cases digging a hole can
prove hard or impossible, and Mr. Hoff suggests to
use a capillary drill instead.
A capillary drill is an automatically balanced drill
that can be connected to a tractor lift. It can drill a
horizontally levelled, 60cm-diameter hole within
30 seconds. The capillary drill can break through
the hardpan but still leave the subsoil capillary
canals intact. Initially developed in the mining
industry, it has been adapted by Mr. Hoff for
agriculture. It is still at a prototype stage and can
be rented from AquaPro at a fee. Note that this
could indeed prove useful on the hard Apulian clay
soils.
The use of the capillary drill has the added
advantage of requiring little manpower in areas
where providing for workers is hard or impossible,
like deserts and remote regions. Finally, the drill
allows to exactly calculate the time and cost of
preparing the soil, thus making budgets more
consistent.
The waterboxx has an 8-shaped central opening
where two small trees can be sown or planted. It is
important that the two plants receive the most
sunlight when it is least damaging, i.e. in the
morning and evening, and the least during the
afternoon heat. Care must be given to installing the
device with the holes in a East-West direction: a
compass shape on the cover sheet helps
determining North and South.
AquaPro supplies paperboard sheets with one, two
or three holes. As explained above, the paperboard
is a first barrier against evaporation and covers that
part of the soil not directly supporting the water
tank.
The paperboard should be laid on top of the
planting soil with the holes oriented in a East-West
direction; the holes in the paper should be used as
marker for the planting holes, to be dug with with a
small shovel or a hollow awl. The hole depth
depends on the plant species: ideal planting depth
is usually 2-3 times the seed size13.
Fig. 10 The capillary drill mounted on a tractor.
5 Using the waterboxx
5.1 Soil preparation
5.2 Orientation
5.3 Laying the paperboard
Fig. 11 A three-hole paperboard on top of
germinating seed.

Mr. Hoff recommends using water-soaked seed for
planting because it gives the highest planting
results. Alternatively, he recommends to have
young plants bred especially for the planting,
although he admits that the resulting primary roots
will be weaker. He recommends not to transplant
the young trees in order not to hurt the primary
roots in the process14.
The twinboxx variant of the waterboxx allows for
two or three plants. A number of strategies can be
used, for example growing a small fruit tree as
cash crop and a taller hardwood tree as a longer-
term investment, or two trees of the same species
of which only the strongest will be kept, or two
cereal plants, or again just one climbing plant and a
support15.
Before placing the waterboxx on the soil, the wick
and the wind protectors must be put in place. The
wick should be inserted in the apposite hole on the
bottom of the water tank: about half of the cotton
should stay on the inside, and half on the outside.
The wind protectors are optional and need to be
ordered separately; they can be clicked into place
on the bottom of the water tank.
The water tank should be placed so that the central
tubular openings correspond to the holes in the
paperboard. One should make sure not to damage
the plants, seeds or other planting materials while
placing the water tank.
If wind-protectors are in use, they need to be nailed
into the soil once the water tank is in place. Special
nails are delivered together with the wind
protectors. If no wind-protectors are in use, it is
suggested to put a weight of about 3kg, for
example stones, in the water tank.
The isolation plate, or mid-plate, needs to be put in
place on top of the water tank. The cover sheet
must be placed immediately on top of the mid-
plate: it will click into place along the edges of the
water tank. Both the mid-plate and the cover sheet
have an 8-shaped opening that will fit exactly on
top of the similarly shaped relief on the water tank.
The earth that was first removed when preparing
the soil should now be added around the bottom of
the waterboxx to prevent evaporation and the wind
from blowing underneath the box.
Once the soil is in place, enough water should be
added to fill up the water tank (about 16 liters) and
4 more liters should be poured through the central
opening onto the ground.
The final pieces still need to be mounted: the blue
siphons need to be pushed into the apposite
openings and clicked in the correct position, and
the water tank needs to be sealed with the cap.
A layer of about 3 cm of soil should be added to
the ground through the central opening for further
protection against wind, animals, and evaporation.
Fig. 12 The bottom of a waterboxx with a mounted wick, ready to
be put on top of two seedlings.
Fig. 13 The blue siphons are to be inserted in the apposite slots.
5.4 Planting the seedlings
5.5 Placing the water tank
5.6 Mounting the waterboxx
5.7 Final preparations

After about one year the plant primary roots should
have grown deep enough to reach the underground
water and have become strong enough to survive
without the help of the waterboxx. This stage
becomes evident when the trees exhibit a strong
growth phase. When this happens, the
polypropylene waterboxx can be removed and used
for a new planting. Note that AquaPro claims that a
polypropylene model can be re-used 10-20 times:
in order to get an idea of the average cost per
planting, a pricelist is included at Item II of the
Addenda.
The soil now laying bare should be protected with
a layer of paperboard, sand, cloth or hay to prevent
excessive evaporation and curb weed growth.
If the model used has a double opening for two or
three plants, and more than one plant has suvived,
this is also the time to cut the weakest of the plants
and leave the fittest to grow.
In case the biodegradable, "Ecopur" model is in
use, there is no need to remove the waterboxx, and
usually this was not the intention in the first place:
the device can be left where it is. It will protect the
trees for longer, decompose and release its
nutrients in the environment. The decayed
waterboxx will increase the soil nutrient content.
5.8 Removing the waterboxx

AquaPro encourages individuals and institutions to
experiment with the waterboxx and make their
results public. To this end, a section of the website
is dedicated to collecting information and making
it accessible to third parties. Registered users can
submit their data to the AquaPro database.
In order to make results comparable, AquaPro
recommends a standard procedure to gather
results. Next to information about place, local
climate conditions, soil quality and species, data
can be entered about temperature and relative
humidity.
In particular, AquaPro recommends to use two
electronic loggers, one to be exposed to the outside
air but not to sunlight, for example under a roof,
and one inside the water tank. The logged data can
then be uploaded to the website at the address
http://testform.groasis.com/. Additionally, a soil
thermometer can be used to log soil temperature.
Standardized climate information is to be retrieved
from the National Climatic Data Center website
(http://www.ncdc.noaa.gov/oa/ncdc.html).
AquaPro recommends using the Lascar Easylog
EL-USB-2-LCD logger. A very detailed procedure
is available on the company website15.
AquaPro requires a control group of 2-10 saplings
of Cupressus sempervirens (cypress), wherever in
the world the planting is taking place.
6 Logging procedure
Fig. 14 One of the loggers needs to be inside the waterboxx.

The Groasis website claims that the waterboxx has
been tested in the United States, the Netherlands,
Morocco, Spain, France and Kenya. The range of
species is quite large, ranging from fruits and
vegetables plants like grapes (Vitis vinifera) and
squash (Cucurbita pepo), to hardwood species like
holly (Quercus ilex), bushes and bio-fuel plants
(Jatropha spp.).
AquaPro claims that some of the tested plants have
medicinal properties: Warburgia ugandensis is
supposed to cure malaria and Moringa oleifera is
supposed to cure AIDS16. However, the
AgroForestry Tree Database puts these claims17,18
into question, and a study by the German GTZ
questions Jatropha's value as a bio-fuel crop19. A
full list of the species used in 2010/2011 can be
found in the Addenda at the end of the report.
The initial tests took place in the Moroccan Sahara
with the support of Mohammed I University of
Oujda, Morocco. Plantings have also occurred at
US vineries in Napa Valley and Sonoma Valley, at
the Californian Preserve Dos Palmas, Preserve
Pipes Canyon and Preserve Whitewater, in West-
Sahara with the cooperation of the University of
Agadir, and in seven Spanish provinces with the
cooperation of the University of Valladolid20. The
website does not specify which provinces.
The waterboxx was used for landscaping and
urban landscaping purposes at the Port of Sohar in
Oman and for regreening purposes at sites owned
by the Union Minera del Norte, a Spanish coal
mining company. Further plantings are mentioned
in Ecuador, Mongolia and India, but the website
does not expand on these claims21.
7 Experiments
The weakest point in the Groasis waterboxx
project is the lack or peer-reviewed evidence and
publicly accessible data. Very little detail is
provided about experiment design and results.
Whatever results are available are of dubious
significance: for example, regarding the planting
for Minera del Norte, Mr. Hoff claims that
"although Spain had one of its hottest summers in
2010 the planting experiment showed a result of
over 95% success ratio"22, with no further
elaboration.
No research papers are quoted, and none can be
found on the JSTOR and IngentaConnect academic
databases. A search with Google Scholar only
returns an invitation to test the product.
The site page dedicated to research turns out to be
just a commercial for the device23, just like the
pages supposedly reporting the experiment
results24. The web page where growth data can be
logged is only accessible for registered users, and
all it shows are pictures of "successful" plantings.
The company left unanswered my emails asking
for more information.
While AquaPro is a commercial venture and
understandably needs to promote its product, the
lack of presented evidence is a major weakness.
8 Test results

9 Suitability for organic farming
There are no reasons to believe that the adoption of
the waterboxx would in any way breach the EU
Regulation 2092/9125, the most important
regulation in organic farming. If outside inputs are
kept within the parameters given in the Regulation
Annexes, no problem should arise. However the
Technical Service should be contacted, if
necessary, to confirm this.
National regulations can be stricter than the
European one. In particular, the Bio Austria
General Standard26, the Bio Suisse Standard27 and
the UK Soil Association Organic Standards28 place
restrictions on hydroponics and other soil-less
techniques. While the waterboxx clearly uses soil,
similar techniques like bottle-irrigation are
assimilated to hydroponics: the Technical Service
should clarify whether this would somehow breach
national regulations.
An article from the Dutch magazine
Groenten&Fruit Actueel shows an organic farmer
using the waterboxx in a greenhouse29, so we could
conclude that using the device does not breach
organic regulations. However the article raises
more questions: no dew can develop at the almost
constant temperatures inside a greenhouse, so one
has to wonder about the added value of the
waterboxx.
If the Council is to decide to proceed with our own
field tests, our certification organization ICEA
should be contacted for clarifications as well.

Mr. Hoff's invention seems to be quite promising: many of our eroding fields in Southern Italy could
benefit from it, and it could be an improvement over gravitational irrigation for our fruit fields in the
North. Members planning to upgrade their watering systems to sprinklers or drip-irrigators could combine
those systems with the waterboxx. The cooperative members could certainly benefit from reduced
irrigation costs and improved soil quality. However the waterboxx cannot be recommended for extended
usage at the present stage: too little test results are available.
Among the good sides of the product are the sound understanding of root growth and the thorough
troubleshooting and design improvements over the years. Positive reviews in the press and by prize
committees are encouraging, and the product does not violate any EU and national organic standards,
although the Technical Service could be contacted for further clarifications on this point.
What really is missing are peer-reviewed test results and references from the academic and agronomical
community; without those, the waterboxx should not be introduced. The cooperative should instead wait
for more conclusive research or carry out its own tests.
10 Conclusion

References
1 Hoff, P. (2009) CO2, a gift from heaven. 2nd ed. Eburon, Delft, the Netherlands.
2-4 AquaPro Holland (2007) AquaPro Project Presentation [online] Available at:
<http://groasis.com/download/aquapro_project_presentation.pdf> [Accessed 13 September 2011].
5 AquaPro Holland (2007) Press Presentation [online] Available at:
<http://groasis.com/page/uk/publications.php> [[Accessed 16 September 2011].
6 Eburon Academic Publishers (2010) Eburon-Auteur wint prestigieuze BètaDragons prijs [online]
Available at: <http://www.eburon.nl/eburon_auteur_wint_prestigieuze_beta_dragons_prijs>
[Accessed 16 September 2011].
19 Deutsche Gesellschaft für Technische Zusammenarbeit (GTZ) GmbH (2009) Jatropha Reality Check,
GTZ – Regional Energy Advisory Platform (East Africa), Nairobi.
7 Popular Science (2010) The best of what's new 2010 Grand Awards [online] Available at:
<http://www.popsci.com/bown/2010/awards> [Accesses 16 September 2011].
8 AquaPro Holland (2010) Technology / Stimulus [online] Available at:
<http://groasis.com/page/uk/stimulis.php> [Accessed 16 September 2011].
9 Hoff, P. (2009) CO2, a gift from heaven (p. 82). 2nd ed. Eburon, Delft, the Netherlands.
10 J. L. Andrade Dew deposition on epiphytic bromeliad leaves: an important event in a Mexican tropical
dry deciduous forest, Journal of Tropical Ecology (2003), 19: 479-488.
11-12 AquaPro Holland (2010) Technology / Principle [online] Available at:
<http://groasis.com/page/uk/principle.php> [Accessed 16 September 2011].
14 AquaPro Holland (2010) Technology / Planting materials [online] Available at:
<http://groasis.com/page/uk/material.php> [Accessed 16 September 2011]
17 AgroForestry Tree Database, Warburgia ugandensis [online] Available at:
<http://www.worldagroforestry.org/sea/products/afdbases/af/asp/SpeciesInfo.asp?SpID=1699>
16 AquaPro Holland (2011) International Groasis waterboxx plantings 2010/2011 [online] Available at:
<http://groasis.com/download/species.doc> [Accessed 16 September 2011].
15 AquaPro Holland (2010) Manual [online] Available at:
<http://testform.groasis.com/upload/manual_en.pdf> [Accessed 16 September 2011].
13 "Sowing." Wikipedia: The Free Encyclopedia. Wikimedia Foundation [online] Available at
<http://en.wikipedia.org/wiki/Sowing> [Accessed September 16 2011].
18 AgroForestry Tree Database, Moringa oleifera [online] Available at:
<http://www.worldagroforestry.org/Sea/Products/AFDbases/AF/asp/SpeciesInfo.asp?SpID=1169>
20 AquaPro Holland (2011) Advanced overview of plantings [online] Available at
<http://groasis.com/download/overview_plantings.doc> [Accessed 16 September 2011].
21 AquaPro Holland (2011) Press / Photo library [online] Available at
<http://groasis.com/page/uk/photoalbum.php> [Accessed 16 September 2011].
22 AquaPro Holland (2011) Experience in gravel in Oman and mine spills in Spain [online] Available at
<http://www.groasis.com/download/Groasis%20waterboxx%20introduction%20for%20the%20recovery%
20of%20mine%20spills.doc> [Accessed 16 September 2011].
23 AquaPro Holland (2011) Technology / Research [online] Available at
<http://groasis.com/page/uk/research.php> [Accessed 16 September 2011].
24 AquaPro Holland (2011) Experimental results [online] Available at
<http://groasis.com/page/uk/exp_results.php> [Accessed 16 September 2011].

28 Soil Association (2011), Soil Association organic standards for producers, revision 16.4 June 2011
[online] Available at:
<http://www.soilassociation.org/LinkClick.aspx?fileticket=ic4qKgG2aiM%3d&tabid=353> [Accessed 20
September 2011].
27 Bio Suisse (2011) Bio Suisse Standards, Edition of 1.1.2011 [online] Available at: <http://www.bio-
suisse.ch/en/library/import/standards.php> [Accessed September 20 2011].
26 Bio Austria Verein zur Förderung des Biologischen Landbaus
(2010), Produktionsrichtlinien Fassung September 2010 [online]
Available at: <http://www.bio-austria.at/content/download/28687/207257/file/Richtlinien_2010.pdf>
25 Regulation (EC) 2007/834 of 28 June 2007 on organic production and labelling of organic products
and repealing Regulation (EEC) No 2092/91, OJ L 189, p. 1 of 20.7.2007.
29 Visser, P. (2011, September 6) Tomaten plukken in woestijnbestendige teelt. Groenten&Fruit
ACTUEEL, p. 19.

ISTC 01 Technical Communication Techniques - Diego Schiavon, #7937 Page I
Addenda
Item 1: International Groasis waterboxx plantings 2010/2011
Item 2: the AquaPro pricelist

ISTC 01 Technical Communication Techniques - Diego Schiavon, #7937 Page I I
UNITED STATES
Whitewater (High Desert), Mission Springs
(Low Desert), Dos Palmas (Salton Sea), CA
Honey Mesquite -- Prosopis glandulosa
Screwbean Mesquite -- Prosopis pubescens
Blue Paloverde -- Parkinsonia florida
Sugarbush – Rhus ovata
Velvet Ash – Fraxinus velutina
California Sycamore – Platanus racemosa
Holly Leaf Cherry - Prunus ilicifolia
Wishbone Bush - Mirabilis bigelovii
Cheesebush - Hymenoclea salsola
Paperbag Bush - Salazaria mexicana
Beargrass - Nolina parryi
Joshua Tree - Yucca brevifolia
Apricot Mallow - Sphaeralcea ambigua
California-Napa,Sonoma:
Vines
Chardonnay – Vitis vinifera
Zinfandel – Vitis vinifera
Vegetable
Squash – Cucurbita pepo
HOLLAND
English Oak - Quercus robur
Irish Yew - Taxus baccata aurea fastigiata
MOROCCO
Argan - Argania spinosa
SPAIN
Stone Pine - Pinus pinea
Maritime Pine - Pinus pinaster
Portuguese Oak - Faginea
Almond - Almendra
Hawthorn - majuelo
Poplar - alamo
Holly Oak - Quercus ilex
Pine - Pinus spp.
Cherry - Cerezos
Juniper - Juniperus spp.
Scots Pine - Pino silvestre
Sessile Oak - Roble albar
Birch - Petrea abedal
FRANCE
Maple - Acer monspessulanum
Boxwood - Buxus serpervirens
Mastic - Pinus halepensis
Evergreen - Pistacier lentiscus
Mahaleb cherry - Prunus mahaleb
Laurestine - Viburnum tinus
KENYA
Plant resources:
Biodiesel - Jatropha spp.
Neem tree - Azadirachta indica
Prostrate - Prunus africana
AIDS - Moringa oleifera
Malaria - Warbugia ugandensis
Acacia species:
tortilis
mellifera
hockii
seyal
xonthophloea
Trees with timber value:
Menu oak - Vitex keniensis
Elegon teak - Olea welwitschii
African cedar - Junipera procera
Fruits - climbers and runners:
Strawberry-Fragaria virginiana
Passion fruit - Passiflora edulis
Fruits - trees:
Orange - Citrus sinesis
Mango - Fera indica
Lemon - Citrus limon
Pawpaw - Papaya crica
Avocado - Persea americana
Oil plants
Palm oil - Elaeis guineensis
Rape - Brassica napus
Soya - Glycine max
Date palm - Phoenix dactylifera
Item I: International Groasis waterboxx plantings 2010/2011

ISTC 01 Technical Communication Techniques - Diego Schiavon, #7937 Page I I I
Vegetables
Carrots - Daucus carota
Cabbage - Brassica oleracea
Tomatoes - Solanum spp.
Radish - Raphanus sativus
Legumes
Beans - Phaseolus spp.
Black beans - Lablab albus
International Groasis waterboxx plantings 2010/2011 (continued)

ISTC 01 Technical Communication Techniques - Diego Schiavon, #7937 Page I V
Item II: the AquaPro pricelist

Report on Adopting Groasis Waterboxx for Water Saving Measures at the La PrimaVera Coop

More Related Content

Similar to Report on Adopting Groasis Waterboxx for Water Saving Measures at the La PrimaVera Coop

More from School Vegetable Gardening - Victory Gardens

Recently uploaded

Report on Adopting Groasis Waterboxx for Water Saving Measures at the La PrimaVera Coop