tag:blogger.com,1999:blog-78089649083993228722024-03-06T07:01:24.871+11:00The Scientist's GardenRichard Stirzakerhttp://www.blogger.com/profile/05988422570421948398noreply@blogger.comBlogger90125tag:blogger.com,1999:blog-7808964908399322872.post-44666022245259847282011-08-01T10:36:00.004+10:002011-08-01T13:10:25.305+10:00Broccoli Crop (2)<a href="https://blogger.googleusercontent.com/img/b/R29vZ2xl/AVvXsEgk2oi5Us6ILcEl-W5KVElZnhWqhV30dC5tNwrO8hidUSEVTFx2RcIwrvqz6n6w8br5VnRI-5ULf8dNLgNmlTYiHtw_uoXgAzOmfeT1jphk9k0UEI2ZLx9cki0O1cGcqpyOU4DxdA_uguxG/s1600/nitrate+6.png"><img style="display:block; margin:0px auto 10px; text-align:center;cursor:pointer; cursor:hand;width: 400px; height: 190px;" src="https://blogger.googleusercontent.com/img/b/R29vZ2xl/AVvXsEgk2oi5Us6ILcEl-W5KVElZnhWqhV30dC5tNwrO8hidUSEVTFx2RcIwrvqz6n6w8br5VnRI-5ULf8dNLgNmlTYiHtw_uoXgAzOmfeT1jphk9k0UEI2ZLx9cki0O1cGcqpyOU4DxdA_uguxG/s400/nitrate+6.png" border="0" alt=""id="BLOGGER_PHOTO_ID_5635718249274647010" /></a><br /><br />Things happen slowly in winter. This July we had 17 mornings below zero with a minimum of -8 degrees C. I’m pleased to see such low temperatures because it will kill any overwintering fruit fly larvae. On the other hand the plants are marking time and the microbes are barely turning over. The nitrate level has gone down by less than 2 kg per ha per week over the last two months. I’m starting to hang out for spring!Richard Stirzakerhttp://www.blogger.com/profile/05988422570421948398noreply@blogger.com1tag:blogger.com,1999:blog-7808964908399322872.post-33291529209753336152011-06-19T23:35:00.000+10:002011-06-19T23:38:15.268+10:00The third crop - broccoli<a href="https://blogger.googleusercontent.com/img/b/R29vZ2xl/AVvXsEg-jUl1kp1z-3r5ig2Fzt2YX2q5gvqlksJhf01aRqrAxDgUWu9TDrnNLzLbZfNsQMBi_3vNdV9YSkooejncMT_JDvU8jBJA9XFV8Q0A4EIjqjUeMow_Msw_kzKhK9MKw98btbnM_S3rcLD5/s1600/nitrate+5.png"><img style="display:block; margin:0px auto 10px; text-align:center;cursor:pointer; cursor:hand;width: 400px; height: 190px;" src="https://blogger.googleusercontent.com/img/b/R29vZ2xl/AVvXsEg-jUl1kp1z-3r5ig2Fzt2YX2q5gvqlksJhf01aRqrAxDgUWu9TDrnNLzLbZfNsQMBi_3vNdV9YSkooejncMT_JDvU8jBJA9XFV8Q0A4EIjqjUeMow_Msw_kzKhK9MKw98btbnM_S3rcLD5/s400/nitrate+5.png" border="0" alt=""id="BLOGGER_PHOTO_ID_5619924368545454610" /></a><br />After the next crop is planted, the nitrate drops quite sharply. The blue line now represents the third crop in the sequence – broccoli. Some of the decrease in nitrate is due to crop uptake. However the initial decline is a bit too sudden to be explained by uptake alone. I had to irrigate to get the new crop started and rain following irrigation inevitably leads to some leaching.Richard Stirzakerhttp://www.blogger.com/profile/05988422570421948398noreply@blogger.com0tag:blogger.com,1999:blog-7808964908399322872.post-45805063717470463172011-06-08T09:57:00.001+10:002011-06-08T10:12:16.587+10:00The second fallow<a href="https://blogger.googleusercontent.com/img/b/R29vZ2xl/AVvXsEiqTqLyMh0auM7yMPvWdlTpCmVOGzHjRqOryJZpDYIAAI7qfw9sHTVrcO0mp6qVaAI3KX4MpilJ2KllNpk7FzDK4YiXGQkEUyHhTkNdVDOFFTee10YvTvQBFIVuopj6UOUnUJj00QOFGKN8/s1600/nitrate+4.png"><img style="display:block; margin:0px auto 10px; text-align:center;cursor:pointer; cursor:hand;width: 400px; height: 190px;" src="https://blogger.googleusercontent.com/img/b/R29vZ2xl/AVvXsEiqTqLyMh0auM7yMPvWdlTpCmVOGzHjRqOryJZpDYIAAI7qfw9sHTVrcO0mp6qVaAI3KX4MpilJ2KllNpk7FzDK4YiXGQkEUyHhTkNdVDOFFTee10YvTvQBFIVuopj6UOUnUJj00QOFGKN8/s400/nitrate+4.png" border="0" alt=""id="BLOGGER_PHOTO_ID_5615634903991944146" /></a><br />Despite all the wet weather, the nitrate comes bouncing back after the wheat harvest. Over 32 days the nitrate jumps from 23 to 109 kg N per ha. In other words the soil organic matter is mineralising at a rate that supplies 19 kg N per ha per week, even faster than we saw after the sweetcorn crop a year ago.<br /><br />My gardens have had regular applications of compost over the years, which of course is a good thing. But you can’t turn the microbes off, and so in warm wet soil they are having a field day. The implication of this is that the soluble nitrate must now be managed by very careful irrigation. Even a bed managed ‘organically’ can be swimming in nutrients in a highly soluble form.Richard Stirzakerhttp://www.blogger.com/profile/05988422570421948398noreply@blogger.com0tag:blogger.com,1999:blog-7808964908399322872.post-24161410663742025562011-06-01T20:17:00.004+10:002011-06-01T20:21:36.504+10:00Nitrate during the what crop<a href="https://blogger.googleusercontent.com/img/b/R29vZ2xl/AVvXsEhDQuPkYvviy608M1iIYVYb3nHHcvhMfQIhNOMRCR-zle5Qm4K3aRkYm0jTj1lCw_XLaJ5krW4GZHWVAIzoiyTIKckzOh-Z3r4i0TuBCbtH-Z7tB09uS8oi5ukEtGMkJoqLWNJbKPGT5MON/s1600/nitrate+3.png"><img style="display:block; margin:0px auto 10px; text-align:center;cursor:pointer; cursor:hand;width: 400px; height: 190px;" src="https://blogger.googleusercontent.com/img/b/R29vZ2xl/AVvXsEhDQuPkYvviy608M1iIYVYb3nHHcvhMfQIhNOMRCR-zle5Qm4K3aRkYm0jTj1lCw_XLaJ5krW4GZHWVAIzoiyTIKckzOh-Z3r4i0TuBCbtH-Z7tB09uS8oi5ukEtGMkJoqLWNJbKPGT5MON/s400/nitrate+3.png" border="0" alt=""id="BLOGGER_PHOTO_ID_5613193783369303890" /></a><br />The crop was close enough to 5 t/ha. Each ton of grain harvested removes about 20 kg N per ha. Let’s say the harvest index was 0.4 (grain / grain plus stubble), then the standing stubble would come in at 7.5 t/ha. This stubble would contain around 0.4% N, making 30 kg. So the total N uptake would be 100 kg (grain) + 30 kg (stubble) = 130 kg N.<br /><br />The change in soil nitrate between sowing and harvest was 149 kg – 20 kg = 129 kg (the gold line in the graph above). This is almost the same value as the 130 kg N uptake calculated above – but the match is fortuitous. There would have been mineralisation of organic matter after sowing, losses through leaching, and other factors in play.Richard Stirzakerhttp://www.blogger.com/profile/05988422570421948398noreply@blogger.com0tag:blogger.com,1999:blog-7808964908399322872.post-59458832594187809622011-05-30T22:35:00.001+10:002011-05-30T22:38:37.491+10:00A bumper 'crop'<a href="https://blogger.googleusercontent.com/img/b/R29vZ2xl/AVvXsEg7B5vxaBjGgwZOyTMdXB9yOs0XGkxEjl5sy1unNjXQ7dNXghOLvYOVH3fE4ToyUOJiv3galqmMHGiRHUPea5Ig41XRYf_QncfsfUNhLTMcjYCYDtY0wjhruj2dJJu6-wZMCN2ONts0ylvl/s1600/P1020359.JPG"><img style="display:block; margin:0px auto 10px; text-align:center;cursor:pointer; cursor:hand;width: 400px; height: 300px;" src="https://blogger.googleusercontent.com/img/b/R29vZ2xl/AVvXsEg7B5vxaBjGgwZOyTMdXB9yOs0XGkxEjl5sy1unNjXQ7dNXghOLvYOVH3fE4ToyUOJiv3galqmMHGiRHUPea5Ig41XRYf_QncfsfUNhLTMcjYCYDtY0wjhruj2dJJu6-wZMCN2ONts0ylvl/s400/P1020359.JPG" border="0" alt=""id="BLOGGER_PHOTO_ID_5612487264256752882" /></a><br />We returned to Australia on 31 December and I harvested the wheat a week later. It came in at 4.95 tonnes per hectare – a very respectable yield! All I did was sow, weed once and then harvest six months later.<br /><br />Of course it was an extraordinarily favourable season, although I was surprised to get such a high yield with no added fertiliser, especially after very little had been applied to the previous crop. In addition there were 45 days with high potential leaching (see red lines on last post). Unfortunately I have no idea how deep the roots went.Richard Stirzakerhttp://www.blogger.com/profile/05988422570421948398noreply@blogger.com1tag:blogger.com,1999:blog-7808964908399322872.post-16879128376825977512011-05-29T20:15:00.000+10:002011-05-29T20:16:26.175+10:00Water for the wheat crop<a href="https://blogger.googleusercontent.com/img/b/R29vZ2xl/AVvXsEgUZZf94G3bLiP7WctAHbiQqqKJoksOxT0Q8eDARO7YetRRMhHnrXNrEnbu1YKcuCaHTz_3kQEizkvnQM7of2MNlNwwo2o1oJXSm9jinySJQLofhYEnnv5Q-8o5Ejf9TuQUdKrr54fvNYRD/s1600/wheat+water.png"><img style="display:block; margin:0px auto 10px; text-align:center;cursor:pointer; cursor:hand;width: 400px; height: 266px;" src="https://blogger.googleusercontent.com/img/b/R29vZ2xl/AVvXsEgUZZf94G3bLiP7WctAHbiQqqKJoksOxT0Q8eDARO7YetRRMhHnrXNrEnbu1YKcuCaHTz_3kQEizkvnQM7of2MNlNwwo2o1oJXSm9jinySJQLofhYEnnv5Q-8o5Ejf9TuQUdKrr54fvNYRD/s400/wheat+water.png" border="0" alt=""id="BLOGGER_PHOTO_ID_5612079840289376098" /></a><br /><br />During the six month I spent in Africa, I put the whole vegetable garden under wheat and mustard. The bed we are following - where the sweetcorn had been grown - was sown to wheat on 25 April. The graph above gives a snapshot of the soil water regime at a depth of 30 cm from 1 July until harvest date. The topsoil remained wet up to the middle of September, as shown by the blue line (i.e. suction remained under 30 kPa). There were only two times during the season where the topsoil starts to dry – mid October and late November. But in both cases the rain soon returned. In fact it was a very wet season, with the crop receiving over 600 mm (shown on right hand axis).<br /><br />The horizontal red line shows the period when the wetting front detector at 40 cm depth contained water. In this case the floats were removed from the detector and replaced by a simple electrode which could be logged (A friend downloaded the logger while I was away so I could see when water was collected and later sucked out of the detectors by the drying soil).<br /><br />The pattern is quite obvious. When there is a lot of rain (the black cumulative rainfall line jumps up), the soil suction falls towards zero (the blue line). During the wettest periods the red line appears, showing the detector contained water. There are seven periods when the detector collected water – some for long periods and some for short. For example the detectors contained water for 109 hours in mid August after receiving 38 mm of rain over 3 days. But in mid October, after 57 mm rain, the detectors only held water for 25 hours. The reason is that the larger plants could suck water out of the soil much faster in the warmer October weather.<br /><br />Over the six month period the detector at 40 cm depth contained water for a total period of 45 days. These are the periods when water is moving downwards quite quickly, from the topsoil into the heavy clay below. We expect much of the nitrate would be moving down into the subsoil as well.Richard Stirzakerhttp://www.blogger.com/profile/05988422570421948398noreply@blogger.com1tag:blogger.com,1999:blog-7808964908399322872.post-45224577409590920342011-05-20T11:48:00.001+10:002011-05-20T11:50:56.717+10:00Nitrate in the fallow<a href="https://blogger.googleusercontent.com/img/b/R29vZ2xl/AVvXsEg9EzTs6X_PvEl_gd7PrnsGR0hKeZedyoQ4l129pZAflD6RC3RrBlZWTFRigkhBDYYae-PnCy87OD8J0Vw4iH-CiFR-xDlqTW5_vijC4jUjyG3xV5LuDCkGn_G5GJ4zVwptzAoAWBrKvoZS/s1600/nitrate+2.png"><img style="display:block; margin:0px auto 10px; text-align:center;cursor:pointer; cursor:hand;width: 400px; height: 190px;" src="https://blogger.googleusercontent.com/img/b/R29vZ2xl/AVvXsEg9EzTs6X_PvEl_gd7PrnsGR0hKeZedyoQ4l129pZAflD6RC3RrBlZWTFRigkhBDYYae-PnCy87OD8J0Vw4iH-CiFR-xDlqTW5_vijC4jUjyG3xV5LuDCkGn_G5GJ4zVwptzAoAWBrKvoZS/s400/nitrate+2.png" border="0" alt=""id="BLOGGER_PHOTO_ID_5608609546542298834" /></a><br /><br />We are going to move fairly quickly through 18 months of soil nitrate monitoring. The green line shows the drop in soil nitrate during the 12 weeks the sweet corn crop was in the ground. We started with 221 kg/ha and this fell to 9 kg/ha at harvest. I hope most of this nitrate was picked up by the crop, but no doubt some escaped below the root zone. <br /><br />Lesson #1 is don’t necessary believe the recommendations to apply fertiliser at planting. It’s prudent to measure first.<br /><br />The graph above shows what happened during the 77 days of fallow between the end of the corn crop and the subsequent wheat crop. The soil was still warm during March and April, and there were regular rainfall events. On 23 May the wetting front again reached 40 cm depth and the nitrate had risen from 6 kg/ha to 149 kg/ha. This equates to 143 kg/ha or 13 kg of nitrogen ‘appearing’ in the soil each week. The source of nitrate is the mineralisation of organic matter. In other words soil microbes feeding on the soil organic matter break it back down into plant nutrients. I only measured the nitrate, but the complete suite of plant nutrients would be there too.Richard Stirzakerhttp://www.blogger.com/profile/05988422570421948398noreply@blogger.com1tag:blogger.com,1999:blog-7808964908399322872.post-80324362977101952672011-05-18T09:55:00.003+10:002011-05-18T10:16:47.820+10:00From drought to flood<a href="https://blogger.googleusercontent.com/img/b/R29vZ2xl/AVvXsEikya5tedKoJd4nvpQXgCRHxs0XMN9apGEjFSsJ8wvKjB0wvO3q-uKjtJVcbnPuaT0s2Mzde59Qxpadocc15D8J-aC3tnar_b6yy1zFYznSEehTEup06eNglHegk5YxGJnE5_8WXNcreeBx/s1600/nitrate1.png"><img id="BLOGGER_PHOTO_ID_5607842144653493938" style="DISPLAY: block; MARGIN: 0px auto 10px; WIDTH: 400px; CURSOR: hand; HEIGHT: 190px; TEXT-ALIGN: center" alt="" src="https://blogger.googleusercontent.com/img/b/R29vZ2xl/AVvXsEikya5tedKoJd4nvpQXgCRHxs0XMN9apGEjFSsJ8wvKjB0wvO3q-uKjtJVcbnPuaT0s2Mzde59Qxpadocc15D8J-aC3tnar_b6yy1zFYznSEehTEup06eNglHegk5YxGJnE5_8WXNcreeBx/s400/nitrate1.png" border="0" /></a>This next sequence of blogs is all about nitrogen.<br /><br />I left Australia to work in Africa in June last year, during the worst drought in living memory. I returned in January 2011 to the worst floods in a quarter of a century.<br /><br />During the drought I was worried about salt in my soil because I had been using waste water. During the continuous wet weather my attention switched to soil nitrogen. Would it all be leached away?<br /><br />Before I get into this new story, a quick recap: I started this blog in January 2010 with the following paragraph<br /><br />“This blog accompanies my book “Out of the Scientist’s Garden”. The book is about how the world uses water in the business of feeding itself. It’s a serious book on a difficult topic, so I wrote in story form, through the lens of my fruit and vegetable garden. I kept the book free of tables and graphs because this type of information is for the specialist, and I was writing the book for everybody interested in water.”<br /><br />Of course you can’t get away from numbers and graphs if you really want to understand water. Those of you who have followed this blog will see that it is full of such information. I have been running a series of ‘live’ experiments and building up the data sets week by week as the experiments unfold. This makes all the data much easier to follow.<br /><br />The blog started with a sweetcorn crop grown using water from the washing machine. During the long drought and accompanying water restrictions, many people gave up on gardening all together. We maintained a fully irrigated and productive food garden whilst using less water than the average per capita consumption for our city. To keep this up we had to exploit every opportunity, and the challenge of waste water was one of those opportunities.<br /><br />Water from the washing machine contains salt and plants don’t like salt. The first of the ‘live’ experiments was about monitoring how the salt was building up in the soil. One of the surprises from this experiments (and all good experiments should have surprises) was how much nitrate was in my soil, even before any compost, manure or fertiliser was added.<br /><br />Plants need nitrogen as it is the essential component of enzymes, particularly the photosynthetic enzyme packed into the leaves. Most of the nitrogen the corn plant uses comes in the form of nitrate dissolved in the soil water. You will recall that wetting front detectors were placed at 20 and 40 cm depth in the soil. With a few assumptions I’m going to chart the level nitrate in the soil from the very start (Dec 09 to now May 11).<br /><br />The assumptions are<br />1) I take the water sample from the detector at 40 cm depth to be the average value over the top 50 cm of soil<br />2) I assume the soil is 35% volumetric water content when the soil water sample is captured<br />3) I use the ‘RQEasy’ meter to read the nitrate level off a colour test strip<br />4) The value of nitrate in mg/L is converted into kg/ha.<br /><br />Here is the corn crop that would have taken up approximately 200 kg of nitrogen on a per hectare basis. We only added the equivalent of 20 kg. The rest came from the soil. You can see all the details by scrolling back to the very beginning. In following blogs we will look what happens to the soil supply of nitrate over the next 3 crops.<br /><br /><a href="https://blogger.googleusercontent.com/img/b/R29vZ2xl/AVvXsEihXjO9lM8B5fZ72Ax4qW3mIrjVrd4ofSZcrR3cX-oRAgZcUz03lY6BY9cehKDUPM_O0tYveoX11CyloRpiiTnSjOzNV6871zHnq92fMxiPwCUK7QzU73xdcab9592oQ8xF7ylkQnTBMbKz/s1600/week+10.jpg"><img id="BLOGGER_PHOTO_ID_5607841926045724514" style="DISPLAY: block; MARGIN: 0px auto 10px; WIDTH: 300px; CURSOR: hand; HEIGHT: 400px; TEXT-ALIGN: center" alt="" src="https://blogger.googleusercontent.com/img/b/R29vZ2xl/AVvXsEihXjO9lM8B5fZ72Ax4qW3mIrjVrd4ofSZcrR3cX-oRAgZcUz03lY6BY9cehKDUPM_O0tYveoX11CyloRpiiTnSjOzNV6871zHnq92fMxiPwCUK7QzU73xdcab9592oQ8xF7ylkQnTBMbKz/s400/week+10.jpg" border="0" /></a><br /><br /><br /><br /><div><a href="https://blogger.googleusercontent.com/img/b/R29vZ2xl/AVvXsEjGvgNt7G3II09AR0JYVv0BZx4cV0qFQE-KMwQ6z09vBPj29Ny92fdaSRHj8CRxidV8S9ZaYtbr0iIC4eWDWHvZkWbFIyDD2j1566x4SF1zWAwRSfFeLVdPMaamMVr3ZhM2p3lJbsKHDoNb/s1600/week+10.jpg"></a><br /><br /></div>Richard Stirzakerhttp://www.blogger.com/profile/05988422570421948398noreply@blogger.com0tag:blogger.com,1999:blog-7808964908399322872.post-549321129142516032010-12-16T21:21:00.004+11:002010-12-16T21:33:05.781+11:00What we learned from the Zimpeto couve crop<a href="https://blogger.googleusercontent.com/img/b/R29vZ2xl/AVvXsEjQjyi0LxqLPwIfp5z1Yik4UEy8Bx9dNcA8IPHtssgh87lOPwFMCLfxLpQ71ZQ3pK_3hibDYnVfsdISNDhFhlzrGHHdbdnAEdu3lBgKSdAjTR5uUMfFXQ9W7bbMhIDJl0j80zIgg8AqkLVB/s1600/P1010688.JPG"><img id="BLOGGER_PHOTO_ID_5551223710578555698" style="DISPLAY: block; MARGIN: 0px auto 10px; WIDTH: 400px; CURSOR: hand; HEIGHT: 300px; TEXT-ALIGN: center" alt="" src="https://blogger.googleusercontent.com/img/b/R29vZ2xl/AVvXsEjQjyi0LxqLPwIfp5z1Yik4UEy8Bx9dNcA8IPHtssgh87lOPwFMCLfxLpQ71ZQ3pK_3hibDYnVfsdISNDhFhlzrGHHdbdnAEdu3lBgKSdAjTR5uUMfFXQ9W7bbMhIDJl0j80zIgg8AqkLVB/s400/P1010688.JPG" border="0" /></a><br /><div></div><br /><div>This is the final post on the Zimpeto couve crop. So what did we learn?</div><br /><div></div><div>It is possible, with the measurement techniques we had available, to grow a big couve crop with very little water, and in our case, no added nutrients.<br /><br />We could do this by watching the watermark sensors to check the soil did not get too dry, and at the same time ensuring that the 500 mm detectors were only activated occasionally, to check that the soil did not get too wet.<br /><br />Our irrigation strategy was very influenced by the nitrate readings. The very high readings around day 13 meant that we needed to be careful not to leach the nitrate out of the profile.<br /><br />For example, we measured above 500 mg nitrate/L at 300 mm depth at the start of the experiment. At a soil water content of 25%, 500 mg nitrate/L adds up to around 85 kg N per ha in the top 300 mm of soil. We add another 10 kg in the irrigation water. This would be a large proportion of the total nitrogen fertiliser the crop requires.<br /><br />How well could we have done if we just had the detectors and not the nitrate, conductivity and watermark sensors?<br /><br />We can draw some lessons from this experience which suit this soil type and irrigation system as follows: </div><div> </div><div>When we do not activate the detectors at 300 mm depth, the plants might be getting just enough water, or more likely not quite enough. When we activate the 500 mm detectors, the soil is very wet.<br /><br />We could come up with the following guidelines:<br /><br />1) When the plants are small, irrigate frequently but do NOT activate a 300 mm detector. This will ensure the nutrients are not leached. </div><div><br />2) As the plants start to grow quickly, activate the 300 mm detector once or twice per week </div><div><br />3) When the crop is at a yield-sensitive growth stage (for vegetables this is usually flowering time, or ‘hearting’ time for leafy crops) activate the 500 mm detectors a couple of times.</div><div> </div><div>There is one remaining lesson. We must minimise the leaching of nutrients, but we must also manage the salt. By the end of the season the wet side had an extra 624 kg Salt per ha in the roozone. The dry side had more (660 kg of salt / ha), applied in the irrigation water.</div><div> </div><div>A few larer irrigation events towards the end of the season, when the soil nutirent content tends to be low, will ensure salt levels do not build up too much in this soil. By deep I mean activating the 500 mm detectors. The detectors placed at 700 mm were too deep to be useful. </div>Richard Stirzakerhttp://www.blogger.com/profile/05988422570421948398noreply@blogger.com0tag:blogger.com,1999:blog-7808964908399322872.post-28350117999086100352010-12-16T21:14:00.003+11:002010-12-16T21:20:31.305+11:00Salt and nitrate leaching?<a href="https://blogger.googleusercontent.com/img/b/R29vZ2xl/AVvXsEjg27zP9MACz43KptUuCdDf-Z8g038K3ykxTCLzTrdN8BkbD8mPK1Xw59PzfGL5qNxbCxN8hN98aBznPkYKOi0X7MJL7GG4xtFN7Nbh2-Q857EQ9xvPfQYrRESU3M06c2TPslRjoNdo8MDR/s1600/P1000809.JPG"><img id="BLOGGER_PHOTO_ID_5551221900759038834" style="DISPLAY: block; MARGIN: 0px auto 10px; WIDTH: 400px; CURSOR: hand; HEIGHT: 300px; TEXT-ALIGN: center" alt="" src="https://blogger.googleusercontent.com/img/b/R29vZ2xl/AVvXsEjg27zP9MACz43KptUuCdDf-Z8g038K3ykxTCLzTrdN8BkbD8mPK1Xw59PzfGL5qNxbCxN8hN98aBznPkYKOi0X7MJL7GG4xtFN7Nbh2-Q857EQ9xvPfQYrRESU3M06c2TPslRjoNdo8MDR/s400/P1000809.JPG" border="0" /></a><br /><div>Here we are using a mini disk permeameter to get some idea of how fast the water moves into the soil, and how wide the wetting patterns become. This all helps us to manage salt and nutrients.<br /><br />We pumped water from the aquifer at an electrical conductivity of 0.8 dS/m. This equates roughly to 0.5 g of salt for every litre of water applied. So when we apply 159 mm of irrigation water we also add 865 kg of salt per ha. We did not measure which salts were in the water, but most of it is likely to sodium chloride. Plants don’t like sodium chloride. We can let it build up a bit in the soil, but eventually we have to apply extra water – more than the plants requirements, to leach the salt out.<br /><br />The groundwater also contained 30 mg/L of nitrate. So when we are irrigating we are also applying some fertiliser.<br /><br />On the 'wet side' we applied 159 mm of water, which has 865 kg of salt dissolved in it and this included 11 kg of nitrogen (in the nitrate form).<br /><br />On the 'dry side' we applied 134 mm of water, which has 686 kg of salt dissolved in it and this included 9 kg of nitrogen (in the nitrate form).<br /><br />That takes care of the input side of the equation. By collecting water from the wheelie bins - the water that the couve did not use - we can complete the output side of the picture (on a per hectare basis).<br /><br />On the wet side we collected the equivalent of 18.6 mm of drainage water which had 241 kg of salt dissolved in it which included 11 kg of nitrogen (in the nitrate form).<br /><br />On the dry side we collected the equivalent of 2.7 mm of drainage water which had 26 kg of salt dissolved in it which included 0.1 kg of nitrogen (in the nitrate form).<br /><br /><br /><br /></div>Richard Stirzakerhttp://www.blogger.com/profile/05988422570421948398noreply@blogger.com0tag:blogger.com,1999:blog-7808964908399322872.post-25140278257245128222010-12-16T19:45:00.004+11:002010-12-16T21:34:06.213+11:00What did we catch in the bins?<a href="https://blogger.googleusercontent.com/img/b/R29vZ2xl/AVvXsEicODQR8_G6-fbNsUe8H7yG7Chcl1rDaaknHVQogj7PaPSNBW4mfvRUtFqF0bpRZ0-nmhCWSsb1iVU2DO9iLcc6nwJsxJkNJTTAV6uTpbMJ9JJ3-B2VekwCYUzpLqgDjxDwatNqB7lmz5Ou/s1600/bins+in+ground.bmp"><img id="BLOGGER_PHOTO_ID_5551206982689227746" style="DISPLAY: block; MARGIN: 0px auto 10px; WIDTH: 400px; CURSOR: hand; HEIGHT: 219px; TEXT-ALIGN: center" alt="" src="https://blogger.googleusercontent.com/img/b/R29vZ2xl/AVvXsEicODQR8_G6-fbNsUe8H7yG7Chcl1rDaaknHVQogj7PaPSNBW4mfvRUtFqF0bpRZ0-nmhCWSsb1iVU2DO9iLcc6nwJsxJkNJTTAV6uTpbMJ9JJ3-B2VekwCYUzpLqgDjxDwatNqB7lmz5Ou/s400/bins+in+ground.bmp" border="0" /></a><br /><div><div></div><div></div><div>One of the buried wheelie bins is just visible in the left of the picture. Up to day 40, the 300 mm depth detectors collected water 3 times. Then on day 41, after a few larger irrigation events, the 500 mm detectors collected their first samples. The detectors at 700 mm did not collect water, and there was no water in the bins.<br /><br />A very large irrigation was applied on day 66 (13 hours or 8.45 littres per dripper or 28 mm averaged over the whole area). This time the 300 and 500 mm detectors collected, and water also started to collect in the bins. We measured drainage of 2.7 mm from the drier side and 18.6 mm from the wetter side.<br /><br />We did NOT collect ANY water in the detectors at 700 mm depth. </div><br /><div></div><div>Water must have gone past this depth because we measured water in the 900 mm deep wheelie bins. However none of this infiltrating water could be collected in a FullStop funnel at 700 mm depth. This tells us something about the limitation of the technique. They do not work when placed too deep. </div></div>Richard Stirzakerhttp://www.blogger.com/profile/05988422570421948398noreply@blogger.com0tag:blogger.com,1999:blog-7808964908399322872.post-26406311033163026662010-12-16T19:32:00.002+11:002010-12-16T19:45:26.113+11:00A New Trick<a href="https://blogger.googleusercontent.com/img/b/R29vZ2xl/AVvXsEgdo6YVncJYOYDVii2QlQRGIeyHq4l0Pm4lWe6VP1lDW4v4If6cSd0KfvHtSM95i6GX6RoroGh36Ap9sllw4SPCwsqVFnMdxc-QmmsFBxauZIhkB7xygmG82-dp2eEs2XPAHpMIQb22KMOF/s1600/lysim+2.jpg"><img id="BLOGGER_PHOTO_ID_5551195515237182738" style="DISPLAY: block; MARGIN: 0px auto 10px; WIDTH: 400px; CURSOR: hand; HEIGHT: 300px; TEXT-ALIGN: center" alt="" src="https://blogger.googleusercontent.com/img/b/R29vZ2xl/AVvXsEgdo6YVncJYOYDVii2QlQRGIeyHq4l0Pm4lWe6VP1lDW4v4If6cSd0KfvHtSM95i6GX6RoroGh36Ap9sllw4SPCwsqVFnMdxc-QmmsFBxauZIhkB7xygmG82-dp2eEs2XPAHpMIQb22KMOF/s400/lysim+2.jpg" border="0" /></a><br /><div>The sandy soil was easy to dig and had no structure at all, so we could try a new trick. We went to a hardware store and bought a couple of the largest “Wheelie” bins we could find. These were dug into the soil and gravel placed in the base. Now we needed a means of showing how much water collected at the bottom of the bins. We used the 'base piece' and 'float housing' from the wetting front detectors to make a ‘riser’ to the surface. The filter screen in the base piece allowed the water into the riser. The 4 mm off-take on the base piece and tubing was used to suck water out. Then we placed a thin round stick into the float housing (where the floats normally go) so we could measure the depth of water inside – much the same as we use a ‘dipstick’ to measure the amount of oil in the car engine.<br /><br />The bins were refilled with soil in the order it was removed from the hole and the drip tape went back over the top. Two couve plants were then planted in each bin. Now any water or nutrient going past the couve roots would collect at the bottom of the bin (900 mm) and could be measured accurately.<br /><br />You can see the setup going in on youtube at<br /><br /><a title="blocked::http://www.youtube.com/watch?v=" href="http://www.youtube.com/watch?v=Cyj6BzdUllI">http://www.youtube.com/watch?v=Cyj6BzdUllI</a></div>Richard Stirzakerhttp://www.blogger.com/profile/05988422570421948398noreply@blogger.com0tag:blogger.com,1999:blog-7808964908399322872.post-92062322515253697822010-12-13T03:20:00.003+11:002010-12-13T03:43:41.240+11:00How good were we really?<a href="https://blogger.googleusercontent.com/img/b/R29vZ2xl/AVvXsEg7fhAOr-VLCppP3nfdFC3ppidW2wXY5KXLvnN_6I-fOBx9DCcGJgnOhGHajzfYg3yAy4aRWoKX2LX3jRNZsf8szPjpaeyNjfytj8ljXxNQv_qhwdxx_qq9PDKCkI6fw_qrvbrtkPOBO2yj/s1600/Couve+Experiment+2010+002.jpg"><img id="BLOGGER_PHOTO_ID_5549836681153392258" style="DISPLAY: block; MARGIN: 0px auto 10px; WIDTH: 400px; CURSOR: hand; HEIGHT: 300px; TEXT-ALIGN: center" alt="" src="https://blogger.googleusercontent.com/img/b/R29vZ2xl/AVvXsEg7fhAOr-VLCppP3nfdFC3ppidW2wXY5KXLvnN_6I-fOBx9DCcGJgnOhGHajzfYg3yAy4aRWoKX2LX3jRNZsf8szPjpaeyNjfytj8ljXxNQv_qhwdxx_qq9PDKCkI6fw_qrvbrtkPOBO2yj/s400/Couve+Experiment+2010+002.jpg" border="0" /></a><br /><div>This was a good crop, grown with very little water. The first detector samples at 30 cm depth showed that we had lots of nitrate in the soil, left over from the chicken manure applied to previous crops. So we managed with just the nutrients already in this sandy soil. But how good were we really?<br /><br />For those who follow this blog you will know that I think across five strands of enquiry to answer this question:<br /><br />1. LOCAL KNOWLEDGE: what do the people I’m working with already know? What do they do and why, and how did they arrive at these practices?<br /></div><div>2. THERMODYNAMICS: Measure the water going on - by flow meter, irrigation run time, collecting water in cups (or whatever) and compare with the theoretical amount that can be evaporated - from a weather station, a model, an evaporation pan (or whatever). It does not matter if the method is rough – as long as it is consistent.<br /></div><div>3. SOIL WATER STATUS: I go for the simplest measurement protocol and, once I have some local experience, target only a few depths that can give me most of what I need to know (usually Watermark sensors at two depths)<br /></div><div>4. WETTING DEPTH: Wetting front detectors that give a visual indication to the irrigator of how deep the irrigation water has penetrated into the root zone<br /></div><div>5. SOIL SOLUTION: Measure the electrical conductivity and nitrate concentration from the water samples collected from the wetting front detectors<br /><br />The reason for five strands of enquiry is that they are independent, but complementary lines of evidence. Frequently, if you look at one strand alone, you think you are doing OK (say soil water status: strand 3). Then you look at nitrate leaching or salt accumulation (strand 5), and it gives a rather different picture. So then you need additional information, like the ratio between water applied and potential evapotranspiration so you can troubleshoot (strand 2).<br /><br />Wetting front detectors are useful at showing how deep the water is going, and the salt and nutrients that are being carried with the water. But they are not perfect. For example, infiltrating water is captured by the funnel, but when the soil in the funnel is saturated, and the soil outside the funnel is slightly drier, then water can be ‘wicked’ out of the funnel as fast as it arrives. This happens especially in fine sandy soils with no structure, and also when the wetting front detectors are placed quite deep. The water is passing the detector quite slowly, and although some water is accumulating inside, it is wicked out again before the float can pop up.<br /><br />This was a perfect site to test the ‘problem’ of deep detectors, and to see how much water and nutrient could go past.<br /><br /><br /><br /></div>Richard Stirzakerhttp://www.blogger.com/profile/05988422570421948398noreply@blogger.com0tag:blogger.com,1999:blog-7808964908399322872.post-41893505528089313732010-11-29T02:01:00.006+11:002010-11-29T02:12:52.851+11:00The couve crop: Day 70<a href="https://blogger.googleusercontent.com/img/b/R29vZ2xl/AVvXsEgwSnvC7cXDZtkMeKuHstcHGqd95sqfW2FWqfr9V3aZauaQ6w6Yr1CleBugb04k0X3Sz25aofSpx9rAjt3RP-k4i02c_F4QoNBOLHcO-TgsJ753YgpkhiyLJ_WpGXqep69n-qGJLHotzrtc/s1600/P1000793.JPG"><img id="BLOGGER_PHOTO_ID_5544617131538479074" style="DISPLAY: block; MARGIN: 0px auto 10px; WIDTH: 400px; CURSOR: hand; HEIGHT: 300px; TEXT-ALIGN: center" alt="" src="https://blogger.googleusercontent.com/img/b/R29vZ2xl/AVvXsEgwSnvC7cXDZtkMeKuHstcHGqd95sqfW2FWqfr9V3aZauaQ6w6Yr1CleBugb04k0X3Sz25aofSpx9rAjt3RP-k4i02c_F4QoNBOLHcO-TgsJ753YgpkhiyLJ_WpGXqep69n-qGJLHotzrtc/s400/P1000793.JPG" border="0" /></a><br />By day 70 all the couve had been harvested. We picked 27.7 tons per ha from the wetter side and 33.3 tons per ha from the drier side. When we add in the thinning harvest around day 40, the totals were 35.2 t/ha on the wetter side and 33.3 t/ha on the drier side. The crop looked good and tasted good, but we do not have any benchmark to compare it to. We could not find any other data from Mozambique.<br /><br /><br /><br /><a href="https://blogger.googleusercontent.com/img/b/R29vZ2xl/AVvXsEhBXAbHdrUZDK1BtpNMF-wZP6O2e6rI0c6WAXCpc1Qban25qw8UwMNOkIcqh_XaHGX9tJZj0Yg6J3ScM5AEK_8m-R3EtfkyaqSR6NR_uVye1C7dXtxuW4KkyClaB18PZHCvsJSpYQnn_iSa/s1600/Irrig+day+65.png"><img id="BLOGGER_PHOTO_ID_5544616512641612914" style="DISPLAY: block; MARGIN: 0px auto 10px; WIDTH: 400px; CURSOR: hand; HEIGHT: 198px; TEXT-ALIGN: center" alt="" src="https://blogger.googleusercontent.com/img/b/R29vZ2xl/AVvXsEhBXAbHdrUZDK1BtpNMF-wZP6O2e6rI0c6WAXCpc1Qban25qw8UwMNOkIcqh_XaHGX9tJZj0Yg6J3ScM5AEK_8m-R3EtfkyaqSR6NR_uVye1C7dXtxuW4KkyClaB18PZHCvsJSpYQnn_iSa/s400/Irrig+day+65.png" border="0" /></a> It took a total of 159 mm to grow 35.2 t/ha of couve and 134 mm to grow 33.3 t/ha on the dry side. Moreover the last few large irrigations probably were not needed – I just wanted to get samples from the 30 and 50 cm deep detectors. For those familiar with crop water use, this is an incredibly small amount of water to grow a 70 day crop. There is no weather station or evaporation pan data available in Maputo, but we know that irrigation averaged just 2.3 mm/day (wet side) and 1.9 mm/day (dry side) during the warm to hot weather marking the end of the dry season. Of this irrigation water, some must have been lost to direct evaporation from the soil. And maybe some to drainage? (more later on this topic!)<br /><br /><div><a href="https://blogger.googleusercontent.com/img/b/R29vZ2xl/AVvXsEhPRTxIBY93jnocbc2Nqz4XFzAcKUnyueeYg1pBwTWEo_mg8JvLzvAXbLAXdnSvwK8ccoHYmpwbOOWsfChMv4zW-WfiZFfXeOdjc5LSjSIeVchXb-CGR4vx8E4LqiS9puMnKESaUOpli0uC/s1600/day+70+dry+side.png"><img id="BLOGGER_PHOTO_ID_5544616313354801938" style="DISPLAY: block; MARGIN: 0px auto 10px; WIDTH: 400px; CURSOR: hand; HEIGHT: 198px; TEXT-ALIGN: center" alt="" src="https://blogger.googleusercontent.com/img/b/R29vZ2xl/AVvXsEhPRTxIBY93jnocbc2Nqz4XFzAcKUnyueeYg1pBwTWEo_mg8JvLzvAXbLAXdnSvwK8ccoHYmpwbOOWsfChMv4zW-WfiZFfXeOdjc5LSjSIeVchXb-CGR4vx8E4LqiS9puMnKESaUOpli0uC/s400/day+70+dry+side.png" border="0" /></a> The big irrigation at the end of the season wet the soil profile up again and allowed us to get some more nitrate samples from the detectors. The nitrate at 30 cm was 24 mg/L and at 50 cm was 37 mg/L – just a bit lower than the readings back around day 40.<br /><br /><br /><br /><div><a href="https://blogger.googleusercontent.com/img/b/R29vZ2xl/AVvXsEgaECmPsWoNbD78DUOZEN0tOmlUiAqS8_dFddDZkMJgZggfeAvIznQtllqpPGJGBkIgc9uNOFA29t9uMvnL7H-0xfG-Qywk-taI6GxMQzQNmnVmW0pI4tAwVnaznBWxTQW7CzYVRy1aGIa1/s1600/day+70+dry+side.png"><img id="BLOGGER_PHOTO_ID_5544616063310549410" style="DISPLAY: block; MARGIN: 0px auto 10px; WIDTH: 400px; CURSOR: hand; HEIGHT: 198px; TEXT-ALIGN: center" alt="" src="https://blogger.googleusercontent.com/img/b/R29vZ2xl/AVvXsEgaECmPsWoNbD78DUOZEN0tOmlUiAqS8_dFddDZkMJgZggfeAvIznQtllqpPGJGBkIgc9uNOFA29t9uMvnL7H-0xfG-Qywk-taI6GxMQzQNmnVmW0pI4tAwVnaznBWxTQW7CzYVRy1aGIa1/s400/day+70+dry+side.png" border="0" /></a> The big irrigation also refilled the profile on the dry side. The nitrate reading at 30 cm was 51 mg/L and at 50 cm still a high value – 139 mg/L. Both the wet and the dry side started with high levels of nitrate. How much of this did the plant actually get, and how much leached below the roots? Amazingly, we pretty much know the answer to this question. </div><div> </div><div>Coming soon!<br /><br /><br /><br /><div></div></div></div>Richard Stirzakerhttp://www.blogger.com/profile/05988422570421948398noreply@blogger.com1tag:blogger.com,1999:blog-7808964908399322872.post-28583226100724300762010-11-28T02:21:00.006+11:002010-11-28T02:42:05.938+11:00The couve crop: Day 65<a href="https://blogger.googleusercontent.com/img/b/R29vZ2xl/AVvXsEheg9IyLDA719vFbird-1IuwQ0ue1Wf6hCoN-gJ8gm2ay22zXAe1rNIdf32hYpxI5zdvaVLuvn1PxarWiXa8NkKG8WEqOXptwAIgE0rSKbsltoi9nnMqaOh2yqIUa862MczHpvtmXdOTKr2/s1600/Couve+Experiment+2010+006.jpg"><img id="BLOGGER_PHOTO_ID_5544254844238288738" style="DISPLAY: block; MARGIN: 0px auto 10px; WIDTH: 400px; CURSOR: hand; HEIGHT: 300px; TEXT-ALIGN: center" alt="" src="https://blogger.googleusercontent.com/img/b/R29vZ2xl/AVvXsEheg9IyLDA719vFbird-1IuwQ0ue1Wf6hCoN-gJ8gm2ay22zXAe1rNIdf32hYpxI5zdvaVLuvn1PxarWiXa8NkKG8WEqOXptwAIgE0rSKbsltoi9nnMqaOh2yqIUa862MczHpvtmXdOTKr2/s400/Couve+Experiment+2010+006.jpg" border="0" /></a> Day 65 and the couve harvest is in full swing. The couve are now 60 cm apart (after the ‘thinning harvest’ around day 42) and they are touching within the rows, but not fully covering the inter-row space.<br /><br /><div><a href="https://blogger.googleusercontent.com/img/b/R29vZ2xl/AVvXsEhcm30NqKzOeU4cqUIF9nni0NcgLO4SemMxstEXJS3EDqUHz90LgB4eBEojTndmuqffow6jgAGBztZ2VKVMiDwxXP_SXbBQkA6mkFRilVD6AanPlcs1cDoG7yd7vx4LmJK3EPgOdG3S1vtt/s1600/irrig+day+65.png"><img id="BLOGGER_PHOTO_ID_5544253955079382674" style="DISPLAY: block; MARGIN: 0px auto 10px; WIDTH: 400px; CURSOR: hand; HEIGHT: 198px; TEXT-ALIGN: center" alt="" src="https://blogger.googleusercontent.com/img/b/R29vZ2xl/AVvXsEhcm30NqKzOeU4cqUIF9nni0NcgLO4SemMxstEXJS3EDqUHz90LgB4eBEojTndmuqffow6jgAGBztZ2VKVMiDwxXP_SXbBQkA6mkFRilVD6AanPlcs1cDoG7yd7vx4LmJK3EPgOdG3S1vtt/s400/irrig+day+65.png" border="0" /></a>Around day 42 we did some larger irrigations just to get some wetting front detector samples for nitrate analysis (discussed on the last posting). Then we returned to miserly water supply – giving an average of just 0.9 mm per day on the dry side and 1.5 mm per day on the wet side. Have a look at the size of the plants again, and realise that the weather here is pretty warm – reaching 25-35 degrees C most days and no rain. Could it be possible that the soil remained moist with such a little water under such conditions??<br /><br /><div><a href="https://blogger.googleusercontent.com/img/b/R29vZ2xl/AVvXsEh5R28uFhDC9sO1gmkQ5dRBZa5e8cTR_9xFWH68NHb36cRzsl3BENz2rzVu4hILp63J4tD5fzI0k9NWtAAMqXN0YlINJZueDXy4Ff9CE_dBizahZYcOsd4G_RdxQdlkVc7I1mqORR_6bprC/s1600/day+65+wet+side.png"><img id="BLOGGER_PHOTO_ID_5544253693711716098" style="DISPLAY: block; MARGIN: 0px auto 10px; WIDTH: 400px; CURSOR: hand; HEIGHT: 198px; TEXT-ALIGN: center" alt="" src="https://blogger.googleusercontent.com/img/b/R29vZ2xl/AVvXsEh5R28uFhDC9sO1gmkQ5dRBZa5e8cTR_9xFWH68NHb36cRzsl3BENz2rzVu4hILp63J4tD5fzI0k9NWtAAMqXN0YlINJZueDXy4Ff9CE_dBizahZYcOsd4G_RdxQdlkVc7I1mqORR_6bprC/s400/day+65+wet+side.png" border="0" /></a> The idea was to irrigate the wet side for two hours when the watermark sensor at 20 cm depth reached 10 kPa. This was achieved, but in the process the subsoil (40 cm) started to dry out slightly as well. There was never enough water to reach the detectors at 30 cm .<br /><br /><br /><div><a href="https://blogger.googleusercontent.com/img/b/R29vZ2xl/AVvXsEgdkqe3Eev4gsEcLeI1tKiL2SvFep3r8dc_t1wRygbX1Oh7uOOPnJ40wbJToe8RW4O1Vsqeryj0lFnA9JY7MwUQjkOWYeW5nhaLlnio0fZVoCWxC7jXePeyaT6kjnlOvEh7tEEgbH4cKpNu/s1600/day+65+dry+side.png"><img id="BLOGGER_PHOTO_ID_5544253407277691682" style="DISPLAY: block; MARGIN: 0px auto 10px; WIDTH: 400px; CURSOR: hand; HEIGHT: 198px; TEXT-ALIGN: center" alt="" src="https://blogger.googleusercontent.com/img/b/R29vZ2xl/AVvXsEgdkqe3Eev4gsEcLeI1tKiL2SvFep3r8dc_t1wRygbX1Oh7uOOPnJ40wbJToe8RW4O1Vsqeryj0lFnA9JY7MwUQjkOWYeW5nhaLlnio0fZVoCWxC7jXePeyaT6kjnlOvEh7tEEgbH4cKpNu/s400/day+65+dry+side.png" border="0" /></a> The dry side was irrigated when the tension at 30 cm reached 20 kPa. This meant there were fewer irrigation events, and the subsoil started to dry dramatically. So clearly the couve was using more than the average supply of 0.9 mm/day, and was mining the soil storage to do so.<br /><br /><br /><br /><div></div></div></div></div>Richard Stirzakerhttp://www.blogger.com/profile/05988422570421948398noreply@blogger.com0tag:blogger.com,1999:blog-7808964908399322872.post-32820257669923465172010-11-08T19:34:00.007+11:002010-11-08T19:51:13.063+11:00The Couve crop: Day 42<div><img id="BLOGGER_PHOTO_ID_5537095310590438962" style="DISPLAY: block; MARGIN: 0px auto 10px; WIDTH: 300px; CURSOR: hand; HEIGHT: 400px; TEXT-ALIGN: center" alt="" src="https://blogger.googleusercontent.com/img/b/R29vZ2xl/AVvXsEj9zSUPAKt4DDmfL7UR_mCviaZbDig2GRwTePVJPNk1u3FEzL5MeC2T8f2qqaRCMLhS09AwZF8rR1lytQoJaR2DL04DETqvqgue0JhW6tK8uMd-mTvRfmqZaTnksMN_eZ1qtj8XuclyU3pD/s400/P1000804.JPG" border="0" /></div><br /><div>By day 42 the couve had grown substantially. Every second plant was harvested around this time, to give the remaining plants the space to grow to full size. We harvested the equivalent of 8 t/ha from the wet side and 7.1 t/ha from the ‘dry’ side of the block from this 'thinning'. </div><br /><div></div><div><img id="BLOGGER_PHOTO_ID_5537096009755555986" style="DISPLAY: block; MARGIN: 0px auto 10px; WIDTH: 400px; CURSOR: hand; HEIGHT: 198px; TEXT-ALIGN: center" alt="" src="https://blogger.googleusercontent.com/img/b/R29vZ2xl/AVvXsEjcoL5wwfGZtAcLpTpHQDA-EU-lIBmATGxK6026VNw7BUGyb-13a_afHL6REFJ9rEm2D4a3Kn6DDyoGI7ISQVorfgCe7G33P7r_pvpF5JSvKxm1c7tjIt2ZXIGYWrBG2vJ-LnttnZgDJcRB/s400/Irrig+42.png" border="0" />Between day 15 and 35, irrigation was applied every second day for about 30 minutes. During the last week of this period three larger irrigations in the range of 2-4 hours were applied to try and push water down to the detectors buried at 30 and 50 cm. Over the 15-42 day period the ‘wet side’ received an average of 2.5 mm per day and the dry side 2.1 mm per day. </div><div><br /><img id="BLOGGER_PHOTO_ID_5537095166574058482" style="DISPLAY: block; MARGIN: 0px auto 10px; WIDTH: 400px; CURSOR: hand; HEIGHT: 199px; TEXT-ALIGN: center" alt="" src="https://blogger.googleusercontent.com/img/b/R29vZ2xl/AVvXsEiMfspDwuv4HTBGfnFSEOpL2WSV8CHRx7mjxVpY3EvGW8jKi0GUCp0myaj1gKfouuZpXJ-Mwb1dyrwGxfk3Xt-FbuJ4ji_DKucheZiMNdC0bqfyqVK4h5eGCoYozNwepRjwFuE7qbOmvgCg/s400/wet+d42.png" border="0" /></div><div><div>Irrigation on the wet side every second day for about 30 minutes up to day 35 resulted in the soil drying slightly at both depths (to around 20 kPa). Each of the three longer irrigation events after day 35 activated the detector at 30 cm depth, giving nitrate values of 79 (day 36), 33 (Day 38) and 46 mg/L (day 41). The third event activated the detector at 50 cm giving 42 mg nitrate/L. At the same time the watermark sensors recorded the soil suction returning to close to zero art both depths. </div><div> </div><div><img id="BLOGGER_PHOTO_ID_5537097702337191410" style="DISPLAY: block; MARGIN: 0px auto 10px; WIDTH: 400px; CURSOR: hand; HEIGHT: 198px; TEXT-ALIGN: center" alt="" src="https://blogger.googleusercontent.com/img/b/R29vZ2xl/AVvXsEhGXu6rVRrWqiaz4II4BoiaKTZJxQrhdtJ98pyBI7vF1bMYKbeQtbrI0Vz67oa-Wax9n_L2iZnO_MX9BPUldowTBc2-nRyLGVGMAuRfJf59Khxf1tskAPJTrolo08_P9PjgtHZ2g44jGZ-3/s400/dry+D42.png" border="0" /></div><div>The soil suction also rose on the ‘dry side’ as the water use by the couve exceeded the 2.1 mm/day provided. Each of the three longer irrigation events between days 38 and 42 activated the detector at 30 cm depth giving values of 400, 235 and 192 mg nitrate/L. The third event activated the detector at 50 cm giving 164 mg nitrate/L.<br /></div><div>These nitrate values were much higher than the ‘wet side’, showing how small differences in irrigation management can have a huge impact on nutrition.<br /></div></div>Richard Stirzakerhttp://www.blogger.com/profile/05988422570421948398noreply@blogger.com0tag:blogger.com,1999:blog-7808964908399322872.post-33125030084812467302010-11-08T19:05:00.006+11:002010-11-08T19:30:04.390+11:00The Couve story: Day 15<a href="https://blogger.googleusercontent.com/img/b/R29vZ2xl/AVvXsEj-bipF0GsxcjuOsm7zx37NSjhVGBVielsEZ4Ir8j85lJTJJUz9iKcHeKrIuoIp9yHpvFqrlFI270vANc5PuZzmsJs7W0o3yxpj3OvmtOhSALXBtIlx9-jfEZE_XVYRjgQ0uE_MtzQ1w5ak/s1600/P1000669.jpg"><img id="BLOGGER_PHOTO_ID_5537090258420172290" style="DISPLAY: block; MARGIN: 0px auto 10px; WIDTH: 300px; CURSOR: hand; HEIGHT: 400px; TEXT-ALIGN: center" alt="" src="https://blogger.googleusercontent.com/img/b/R29vZ2xl/AVvXsEj-bipF0GsxcjuOsm7zx37NSjhVGBVielsEZ4Ir8j85lJTJJUz9iKcHeKrIuoIp9yHpvFqrlFI270vANc5PuZzmsJs7W0o3yxpj3OvmtOhSALXBtIlx9-jfEZE_XVYRjgQ0uE_MtzQ1w5ak/s400/P1000669.jpg" border="0" /></a><br /><div>Bare rooted seedlings start off slowly, and by day 15 the crop was still small. We irrigated every day for about 30 minutes, to keep the soil immediately around the seedlings wet. The block was divided in half, with a ‘wet’ side and a ‘dry’ side. The idea was to make sure the wet side always had enough water, and then to push the dry side as far as we could. However, over first two weeks both sides got just about the same – the equivalent of 1.7 mm per day on the wet side and 1.6 mm per day on the dry side.<br /></div><div><br /></div><div></div><div>For a few weeks we are going to follow the graphs below. On the left axis we see the soil 'wetness' (suction in Kpa) at depths of 20 and 40 cm as logged by the watermark sensors. On the scale below we consider a reading less than 10 kPa to be wet; 10-20 kPa to be 'OK'; 20-40 kPa to be getting dry; and greater than 60 to be dry. </div><div> </div><div>The pink and red diamonds show us when wetting front detectors captured samples at 20 and 40 cm depth. In this case we plot the data as the nitrate concetration of the water collected (on the right hand axis).</div><div><br /> </div><img id="BLOGGER_PHOTO_ID_5537088317429448498" style="DISPLAY: block; MARGIN: 0px auto 10px; WIDTH: 400px; CURSOR: hand; HEIGHT: 199px; TEXT-ALIGN: center" alt="" src="https://blogger.googleusercontent.com/img/b/R29vZ2xl/AVvXsEg_D7AzNP1dOw7ZFlRtmi_1przptoDu-9vNAmDfNTrcKHUmyHQOAXZYzrB5gusfmqo-DaXW7ISiBPJMK-Q5vc-0IfME4twvx2grHIWAUr2989hyphenhyphenTyS1M4I72-EqWKs1RIH3GkWahSdAAP2v/s400/Wet+d15.png" border="0" /> Tiny plants plus daily irrigation meant the soil stayed very moist on the ‘wet side’, but the irrigation events were not sufficiently long to activate the 30 cm detector. So on day 13 we did a longer irrigation (1.3 L per emitter) just so we could get a water sample at 30 cm. The nitrate level was 440 mg/L - a surprisingly high value (the pink diamond).<br /><br />Chicken manure had been applied to the previous crop, but just a few watering can loads of ‘compost tea’ to the young couve seedlings. The irrigation and nutrient strategy was obvious from here. No more fertiliser or manure, and irrigation needed to be short and frequent so as not to leach the nutrients below the shallow root zone.<br /><br /><div><img id="BLOGGER_PHOTO_ID_5537088852491337378" style="DISPLAY: block; MARGIN: 0px auto 10px; WIDTH: 400px; CURSOR: hand; HEIGHT: 199px; TEXT-ALIGN: center" alt="" src="https://blogger.googleusercontent.com/img/b/R29vZ2xl/AVvXsEj_09gzvEgTpk1wFs8mTS65kTXdfRJRR814SMBnvYVCKpTXV75oqt1rxE1sASJhopclW8H_OYgA8x7k1sC60SQe1PQnDto7_Epi50bnd6hhyphenhyphenPY1J9AZZn_02lreljUrHi-cfaOgOAwweWTM/s400/Dry+d15.png" border="0" /><br />Although the ‘dry side’ of the block received almost as much water as the 'wet side', the 40 cm watermark sensor showed the soil as slightly drier (the blue line - around 10 kPa). But the really big difference was the nitrate reading on day 13: 866 mg/L! This sandy soil had loads of nutrients (the pink diamond) despite applying nothing to this crop. </div><div> </div>Richard Stirzakerhttp://www.blogger.com/profile/05988422570421948398noreply@blogger.com0tag:blogger.com,1999:blog-7808964908399322872.post-38000382935465404672010-11-08T18:53:00.003+11:002010-11-08T18:57:54.616+11:00The Couve Stroy: Day 1We transplanted the couve just next to where the beetroot had been grown. The drip lines were spaced 1 m apart, with drip emitters 0.3 m apart giving about 0.65 L per hour.<br /><br />We used bare rooted seedlings which we bought from a farmer over the road. Seedlings were transplanted right next to the emitters (3.3 plants per square m).<br /><br />We watered the seedlings in with 'compost tea' but other than that applied no fertiliser. Here begins the experiment to see just how little water and nutrients we could get away with.<br /><br /><a href="https://blogger.googleusercontent.com/img/b/R29vZ2xl/AVvXsEgferD7sdZzb0JDfQYDYhyphenhyphenSbdQsUJobKZPw-P2fIdSs4cu8CR5ADzXNV7-PuZ3-WfvU_oTtCCmREZoV_Ch6VwkIppHfrAz3mkYVGVEa9fExzNB2ZNVnEwjCIe6aqDChZEbKo6icO8kqoIZG/s1600/P1000594.JPG"><img id="BLOGGER_PHOTO_ID_5537084052466351810" style="DISPLAY: block; MARGIN: 0px auto 10px; WIDTH: 400px; CURSOR: hand; HEIGHT: 300px; TEXT-ALIGN: center" alt="" src="https://blogger.googleusercontent.com/img/b/R29vZ2xl/AVvXsEgferD7sdZzb0JDfQYDYhyphenhyphenSbdQsUJobKZPw-P2fIdSs4cu8CR5ADzXNV7-PuZ3-WfvU_oTtCCmREZoV_Ch6VwkIppHfrAz3mkYVGVEa9fExzNB2ZNVnEwjCIe6aqDChZEbKo6icO8kqoIZG/s400/P1000594.JPG" border="0" /></a><br /><div></div>Richard Stirzakerhttp://www.blogger.com/profile/05988422570421948398noreply@blogger.com0tag:blogger.com,1999:blog-7808964908399322872.post-61276953863709160352010-11-08T18:01:00.003+11:002010-11-08T18:35:51.735+11:00The Couve Story: Before plantingBefore planting, we installed the usual gear. Wetting front detectors went in at 30, 50 and 70 cm depths directly below drip emitters. We had reason to believe from the previous beetroot crop that a lot of water might be going past the root zone on this sandy soil, hence the deep placement of detectors.<br /><br /><br /><a href="https://blogger.googleusercontent.com/img/b/R29vZ2xl/AVvXsEg6AxaVe38ZA5C6s2gIABkEUsNZzmBcCpTPQHrjv1Gy18GKDyJAgYkU9q58QuhjqBGoU_ETQpFRNEFmFiU_ndCeTn5467_broppLGykAoJGb9k96n4KqT95AMxJ0S1q69Y9QCejLwWCcHZs/s1600/P1000564.JPG"><img id="BLOGGER_PHOTO_ID_5537077492644016082" style="DISPLAY: block; MARGIN: 0px auto 10px; WIDTH: 400px; CURSOR: hand; HEIGHT: 300px; TEXT-ALIGN: center" alt="" src="https://blogger.googleusercontent.com/img/b/R29vZ2xl/AVvXsEg6AxaVe38ZA5C6s2gIABkEUsNZzmBcCpTPQHrjv1Gy18GKDyJAgYkU9q58QuhjqBGoU_ETQpFRNEFmFiU_ndCeTn5467_broppLGykAoJGb9k96n4KqT95AMxJ0S1q69Y9QCejLwWCcHZs/s400/P1000564.JPG" border="0" /></a> <br />Extra detectors were installed and converted to electronic, so we could log the time water arrived at 30 and 50 cm depths and the electrical conductivity of the draining water. In the picture above I am placing a home made electrode down into the wetting front detector. <br /><br />Watermark sensors were installed at 20 and 40 cm depths and these, together with the EC sensors, were connected up to a logger situated in the belly of the scarecrow on the right.<br /><br />Now we were ready to take all the usual measurements. We knew the amount of water going on (scroll back to the Beetroot experiment to see the crude flow meter). We could measure how depth the water penetrated and take water samples for nitrate and salt measurement from the wetting front detector, and we logged to soil water suction.<br /> <br /><br /><br /><a href="https://blogger.googleusercontent.com/img/b/R29vZ2xl/AVvXsEjxX_KBqJ6rpTxO0QaidE_c4b9yG9M2tLPwF6ZLuLwqq64hzG1Avlt5o5awUcfQHvlLxFVEkgGmbyoiFB0G72TzlZ3sWWWlRFyzkjw8QGdlPdE5sm-A1L4rG2IRBUi4bmUxKyTDLAN9Em5L/s1600/P1000594.JPG"></a><br /><br /><div></div>Richard Stirzakerhttp://www.blogger.com/profile/05988422570421948398noreply@blogger.com0tag:blogger.com,1999:blog-7808964908399322872.post-6681298240153488442010-11-08T17:55:00.004+11:002010-11-08T19:32:37.752+11:00The Couve StoryHere are some of the children and their carers at the Zimpeto Centre, Mozambique. Each day, 150 kg of rice is cooked up in the Centre’s kitchen to feed them. Meat is too expensive except for very special occasions, but the children do get beans or dried fish several times a week. The rice is served up with a kind of soupy vegetable stew, usually comprising onions and green leafy vegetable that looks to me like kale (a kind of loose leaved cabbage). The locals call it couve.<br /><br /><br /><a href="https://blogger.googleusercontent.com/img/b/R29vZ2xl/AVvXsEjhvv_QbqpoQEd_VmFqBQvC347dqBlSenAdwGdaDy_NBW-rOI7OHcBDfxEjLdGQS9B-EYTwgIvH6vUDOH4BRX5XD-GpEhKbppSa6aRa2cysZlezfFCSQm2tv34niCU3lyTlNOP9Uc_453lV/s1600/gaborone+012.jpg"><img id="BLOGGER_PHOTO_ID_5537069822436929250" style="DISPLAY: block; MARGIN: 0px auto 10px; WIDTH: 400px; CURSOR: hand; HEIGHT: 300px; TEXT-ALIGN: center" alt="" src="https://blogger.googleusercontent.com/img/b/R29vZ2xl/AVvXsEjhvv_QbqpoQEd_VmFqBQvC347dqBlSenAdwGdaDy_NBW-rOI7OHcBDfxEjLdGQS9B-EYTwgIvH6vUDOH4BRX5XD-GpEhKbppSa6aRa2cysZlezfFCSQm2tv34niCU3lyTlNOP9Uc_453lV/s400/gaborone+012.jpg" border="0" /></a> <div><br />Our task was to grow the couve, but there are two problems. First, Zimpeto is like a giant sand pit, as you can see from the picture, and that makes growing vegetables a challenge. Second there is no piped water in this part of Maputo. The Centre pumps all the water for the 400 inhabitants from groundwater beneath our feet, and from time to time we run out of drinking and washing water. Throwing water into the sandpit to grow couve made our maintenance man very nervous.<br /></div><div> </div><div>But this was the perfect setting to see how good we could be in managing the little water we have. </div>Richard Stirzakerhttp://www.blogger.com/profile/05988422570421948398noreply@blogger.com0tag:blogger.com,1999:blog-7808964908399322872.post-37513032150790157632010-09-26T22:43:00.004+10:002010-09-27T22:58:52.448+10:00Beetroot 2: What about the nutrients?For the first couple of weeks the beetroot was irrigated as per usual practice. We regularly collected water samples in the wetting front detectors. The nitrate readings were astoundingly high, much higher than I ever see in my garden (see the corn plots in earlier posts). No nutrients had been applied to the beetroot. However a large amount of chicken manure had been incorporated into the soil several months before, since this soil is little more than beach sand.<br /><br />Activating a detector at 30 cm depth was clearly not necessary for little beetroot plants. So we slowly cut back the water as can be seen on graph below (the cumulative irrigation line starts to rise more slowly). Although the water use was not excessive, the precipitous drop in nitrate through August was almost certainly due to leaching.<br /><br />For much of the second part of the season we irrigated in such as way so as NOT to activate the detector. This would help bring the leaching under control, but we were now not sure if we were giving too little water.<br /><br />This was going to be difficult soil to manage. Next we set up a much more detailed trial to answer these questions and more.<br /><br /><div><img id="BLOGGER_PHOTO_ID_5521202557676846898" style="DISPLAY: block; MARGIN: 0px auto 10px; WIDTH: 400px; CURSOR: hand; HEIGHT: 197px; TEXT-ALIGN: center" alt="" src="https://blogger.googleusercontent.com/img/b/R29vZ2xl/AVvXsEiJijroIA46fSEksEcxlZNuhIMOBXm70HaLOYCavUn84RColfSVkgrwEjvP969i6nj6e1o0JVAXyflPs8PXFu1wY84yBRmeR367CLc7wnT6xgc8tU-no5tACDZw8sSUT3SjNHcQz8OT3sPm/s400/beet1.png" border="0" /></div>Richard Stirzakerhttp://www.blogger.com/profile/05988422570421948398noreply@blogger.com0tag:blogger.com,1999:blog-7808964908399322872.post-72492038873571444962010-09-26T22:22:00.003+10:002010-09-26T22:42:14.589+10:00Beetroot 2: How much water does it need?<div>A second beetroot crop was transplanted the same week as the first one was harvested. This gave the opportunity to evaluate the irrigation in more detail. We had a system to show how much water was going on (the bottle). Now we needed an estimate of how much water the beetroot could use.<br /><br />Unfortunately we could not find any evaporation data for Maputo, so the usual crop factor x potential evaporation method was going to be difficult. Moreover the beetroot had been planted as one seedling on each dripper, because the wetting patterns were small on this sandy soil. With lines 1 m apart and dripper spaced at 30 cm, this gave just 3.3 plants per square metre. There was a lot of bare soil, making the choice of a crop factor difficult.<br /><br />So we installed a wetting front detector 30 cm below the drip emitter. In fact wetting front detectors had been installed in the first beetroot crop and the boys had reported that the indicator floats were almost always in the up position. Now we could link the amount of water applied with the response of the detectors.</div><br /><br /><div></div><img id="BLOGGER_PHOTO_ID_5521200419300406450" style="DISPLAY: block; MARGIN: 0px auto 10px; WIDTH: 300px; CURSOR: hand; HEIGHT: 400px; TEXT-ALIGN: center" alt="" src="https://blogger.googleusercontent.com/img/b/R29vZ2xl/AVvXsEiAGszidIUf2xV_YduFXjNS7GpKqT67W54ngRxBB8-vhQlCo9kXjChmB6JsNFfThmKbUxlfwplBrN_QcFm5DB2dL8dNy33lCPV9Wvpt7NnDuYJkJuZ6CTfPleLa911EO6Pjc5loDF65kc4e/s400/P1000668.JPG" border="0" /><br /><br /><div></div>Richard Stirzakerhttp://www.blogger.com/profile/05988422570421948398noreply@blogger.com0tag:blogger.com,1999:blog-7808964908399322872.post-26647589733740893682010-09-26T21:12:00.006+10:002010-09-26T22:22:05.151+10:00Beetroot 2: how much water goes on?<div>The beetroot were cooked up in a spicy sauce and served on top of rice for the 300 or so lunches that the kitchen serves up every day (meat is too expensive, so the children live largely on bread and rice topped with a vegetable-based sauce). It tasted good, but our question is how well was it grown? How much water and nutrients did it take to grow? Could we grow much more beetroot with the same inputs?<br /><br />The irrigation system was fitted with a tap timer, and there were small taps at the head of each drip line. So each drip line could be individually turned on and off. Theoretically we should know how long each drip line was run for and hence the application of water to the beetroot. Then we could look up the potential evapotranspiration for Maputo, make adjustments for the size of the crop, and we should be able to answer the question above - at least as far as water goes.<br /><br />In practice it’s not that easy. First, no one keeps good enough records of the on/off times of the taps. Second, the application rate of the drippers was not constant. Although rated at 1.0 L per emitter per hour, we were running the system at lower than recommended pressure, and the more lines open the more the pressure fell. Actual application rates varied between 0.5 and 0.7 L/h<br /><br />We rigged up a simple flow meter as in the picture below, with graduation marked on the bottle. We checked the uniformity of 20 drippers down the line, and compared this to the dripper we collected from. The system was uniform. So that solved the first question – how much water went on to the crop. </div><div> </div><img id="BLOGGER_PHOTO_ID_5521195335249022338" style="DISPLAY: block; MARGIN: 0px auto 10px; WIDTH: 300px; CURSOR: hand; HEIGHT: 400px; TEXT-ALIGN: center" alt="" src="https://blogger.googleusercontent.com/img/b/R29vZ2xl/AVvXsEiJmZi2b0IrGnaXoFKueH7cnIQabFFxzC8AeGBluXdj9Yme_utQvkgFYDC8NqoXw8wPpwQIuRfxt2U8z_LAqMA-XoivOiTH1LIe9PWrDmjybgGDBxhXwGka-1ub_h8n25C20Xgn28p5FEn-/s400/P1000664.jpg" border="0" />Richard Stirzakerhttp://www.blogger.com/profile/05988422570421948398noreply@blogger.com0tag:blogger.com,1999:blog-7808964908399322872.post-58420082015029474062010-09-26T05:03:00.006+10:002010-10-02T03:29:46.363+10:00Beetroot 1<a href="https://blogger.googleusercontent.com/img/b/R29vZ2xl/AVvXsEimasjrX-osPNhA4FtpYrBECJFcX2vDYhyphenhyphensXgEEDdI7c3svwuLgXtadr01pnTv-jcCSxHp62RuUkgxuQlLs1vky17BzMigK1vlM0BVOVCjViWxCUL2GLf8Em30B8hJh553-pLymNOc24WbS/s1600/P1000576.jpg"><img id="BLOGGER_PHOTO_ID_5520933285288032050" style="DISPLAY: block; MARGIN: 0px auto 10px; WIDTH: 225px; CURSOR: hand; HEIGHT: 400px; TEXT-ALIGN: center" alt="" src="https://blogger.googleusercontent.com/img/b/R29vZ2xl/AVvXsEimasjrX-osPNhA4FtpYrBECJFcX2vDYhyphenhyphensXgEEDdI7c3svwuLgXtadr01pnTv-jcCSxHp62RuUkgxuQlLs1vky17BzMigK1vlM0BVOVCjViWxCUL2GLf8Em30B8hJh553-pLymNOc24WbS/s400/P1000576.jpg" border="0" /></a><br /><br />Unlike the farms down the hill which are irrigated from shallow groundwater, we had to rely on water pumped from about 20 m beneath us. The water was pumped to plastic tanks on an 8 m high stand and then gravity fed into our drip irrigation system. The drip lines were spaced 1 m apart, with drippers 30 cm along the lines.<br /><br /><br />The boys were harvesting beetroot during my first week in Maputo. It was an impressive crop, especially given the light sandy soils.<br /><br />The Children's Centre has limited water, and the aquifer from which we were pumping already had some nitrate contamination. So although the crop looked good, we had to find out how much water and nutrients it took to grow it. This becomes our next project.<br /><br /><br /><img id="BLOGGER_PHOTO_ID_5520939498192110818" style="DISPLAY: block; MARGIN: 0px auto 10px; WIDTH: 225px; CURSOR: hand; HEIGHT: 400px; TEXT-ALIGN: center" alt="" src="https://blogger.googleusercontent.com/img/b/R29vZ2xl/AVvXsEgMb-kZ4cCKkxDlTEdhuetv5SORNonxuotHNoOF_EdCa5swGNJOMN3nbeLyY59Enb1kHu2NgZK0R_qs__QOI8DJXmrgrCfaFSz26vlv5_-lJSoCHWqBrmMRdIMB29tRp_a78dWnbqw8V9V9/s400/P1000575.jpg" border="0" />Richard Stirzakerhttp://www.blogger.com/profile/05988422570421948398noreply@blogger.com0tag:blogger.com,1999:blog-7808964908399322872.post-2069745017003223222010-09-25T20:36:00.011+10:002010-10-02T03:27:04.281+10:00A food plot in MaputoLast year I set up a food garden at the Zimpeto Children's centre together with some friends at Edu<a href="https://blogger.googleusercontent.com/img/b/R29vZ2xl/AVvXsEgoqeRejQ36HfpoAuqrYla3OUhqPVTX_irv7UxYQaRsE7yCZS0s20wZkQnnqdH6uXqUQA2o6uSKXLds4hLK3noO7UIRRIfLfUNfevZd6sLL1xnDBUBthWaZHsZBvga5U0MgmXzr_Fo7UI7T/s1600/P1000592.JPG"></a>ardo Mondlane University in Maputo, Mozambique. The Zimpeto Children's Centre feeds, houses and schools about 350 children every day. The purpos<a href="https://blogger.googleusercontent.com/img/b/R29vZ2xl/AVvXsEgoqeRejQ36HfpoAuqrYla3OUhqPVTX_irv7UxYQaRsE7yCZS0s20wZkQnnqdH6uXqUQA2o6uSKXLds4hLK3noO7UIRRIfLfUNfevZd6sLL1xnDBUBthWaZHsZBvga5U0MgmXzr_Fo7UI7T/s1600/P1000592.JPG"></a>e of the garden is to give some of the older children at the Centre training in food production, and to provide vegetables for the Centre's kitchen.<br /><br /><br /><img id="BLOGGER_PHOTO_ID_5520833221852368402" style="DISPLAY: block; MARGIN: 0px auto 10px; WIDTH: 400px; CURSOR: hand; HEIGHT: 300px; TEXT-ALIGN: center" alt="" src="https://blogger.googleusercontent.com/img/b/R29vZ2xl/AVvXsEhJ9PPz4-1-As2qzQfWC_mmkKxve_PkKZxbJtNx60J4shwAOznTsRel93XceY0puTvqC_tgzJ00Z_rQPCnslVaQJiBSH_4giy0ei7mqcaepBzpFQzsAdrZmcooC1xRKhe4Z7VzDze1CXTZv/s400/P1000592.JPG" border="0" /><br /><a href="https://blogger.googleusercontent.com/img/b/R29vZ2xl/AVvXsEh4fTdQD3q1tFBVECsrV1NXQVYF7dsK22bkleSbncjAGB-JOOoK5g38crJvPbZsYrgyXtBQSXAckikrUGrw8PRcdldN1azYVQXz8AmYd3GNE8qfAR8Yw-TJMVqN0vKvTOjwhZp2Z7HMhkUM/s1600/P1000592.JPG"></a><br />Before we look at the Zimpeto garden, we will take a short tour of the food plots just across the road from the Centre. Although it looks like a rural area, it is still within the city of Maputo, in a densely populated area. The vegetables are grown in small beds with raised edges and are watered by hand.<br /><br /><br /><br /><br /><br /><br /><br /><br /><br /><br /><br /><br /><br /><img id="BLOGGER_PHOTO_ID_5521177261613789346" style="DISPLAY: block; MARGIN: 0px auto 10px; WIDTH: 300px; CURSOR: hand; HEIGHT: 400px; TEXT-ALIGN: center" alt="" src="https://blogger.googleusercontent.com/img/b/R29vZ2xl/AVvXsEhgRrLRhKK1j7wmDDfXpRDDMFTX2hOjCNiV-UuI6cCAe-GDksnJtzArbu5w0_FW2WPi1-oKhP4kGwkla8n8gaFcx5mQH1SC_Ri3uS216RAWgo9_-JL94bJT7KpcS8D1MDPQlTX7ys23Jf7h/s400/P1000590.jpg" border="0" />The natural watertable is quite near the surface. The farmers dig holes so they can access this water. They dip the watering cans into the small pools of groundwater. Several hectares of land are irrigated using watering cans, mostly by young kids. The method seems to work well, but is incredibly time consuming. Also the Zimpeto Children's Centre is situated further up the hill where the groundwater is far too deep to access in this way.<br /><br /><br /><br /><br /><div><div></div><img id="BLOGGER_PHOTO_ID_5520834399840716354" style="DISPLAY: block; MARGIN: 0px auto 10px; WIDTH: 400px; CURSOR: hand; HEIGHT: 300px; TEXT-ALIGN: center" alt="" src="https://blogger.googleusercontent.com/img/b/R29vZ2xl/AVvXsEhGtRtkC8ijB5SLgxK3XRwH12lm8tgmrsvCJYbDNNg0uw4QlzndV0invuLm-Dbgb29r1-aj3-f0u3iAMSSq7eChC8GLEYWSSCUdc4sKPbgwffvrPihCRLuTB4RN6FCWmLL8nUd9o1073IEf/s400/P1000588.JPG" border="0" /> <div></div><div><a href="https://blogger.googleusercontent.com/img/b/R29vZ2xl/AVvXsEi9s474qFYqsE53otmwO_FytFHyq8D0FUgdgAl35DBy08NAlrGO1hyc1SLzsOG9gLD7sbZCH0omKg_SV2ymgs75FbZyBWe6gB8u0RIxObMF6eej5CnJxKD1OMIB0x4JD_UYm-Ik7grzJLOf/s1600/P1000588.JPG"></a></div><div><a href="https://blogger.googleusercontent.com/img/b/R29vZ2xl/AVvXsEi9s474qFYqsE53otmwO_FytFHyq8D0FUgdgAl35DBy08NAlrGO1hyc1SLzsOG9gLD7sbZCH0omKg_SV2ymgs75FbZyBWe6gB8u0RIxObMF6eej5CnJxKD1OMIB0x4JD_UYm-Ik7grzJLOf/s1600/P1000588.JPG"></a></div></div>Richard Stirzakerhttp://www.blogger.com/profile/05988422570421948398noreply@blogger.com0