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1月 2018
土壤酸鹼度計與溼度計使用方法 DM 15 Takemura Electric Works Ltd., Japan
土壤酸鹼度計與溼度計使用方法 DM 15 Takemura Electric Works Ltd., Japan
這是日本 Takemura Electric Works Ltd 出的儀器,雖然使用上有一些限制,但在田間非常好使用,不需麻煩要帶樣土回去檢測,直接可以讀取數值,可快速測試田間各點的土壤,,這型號還有測式溼度功能,可決定是田間是否要供水,使用上有一些要注意,不然很容易就壞了,如果好好正確使用,可以用十年以上。
DM-15 土壤酸鹼度計與溼度計特性規格如下:
實現快速簡單的方法來獲得準確的價值。
將金屬電極插入地面,可以立即測量pH和含水率
不需要化學工具測量。
測量pH範圍為3-8的土壤pH值,精確率為0.2pH。
水分含量:1-8%。
尺寸:48(寬)x 48(高)x 160(長)毫米。
重量:135克。
產廠說明:
If the soil to be test is dry or contains much manure, the meter will not indicate a correct ph value, therefore, sprinkle about a bucketful of water on the soil, and wait 20-30 nimutes, before testing.
Before using the meter, be sure to throughly polish its metallic surface with a piece of wetting cloth or sandpaper. When using a brand-new meter, be sure to insert in into the soil a few time in order to remove the oily impurities from it’s metallic surface.
Insert the meter directly into the field or paddy soil under consideration. Completely embed the metallic surface and tamp down the surrounding soil so that it adheres closely to the meter’s metallic electrode surface.
About one minute after insertion the meter in the soil, the pointer will cease to deflect-the value of the soil may then be read.
the meter may sometimed register different values depending on soil condition, such as, adhesion to teh meter’s metallic surface, moisture content, or the amount of manure it contains. it is therefore ideal to make an average of several measurements.
In order to determine whether or not liming has been properly done, after one or two weeks mix the soil well and measure is pH value.
翻譯如下:
1.如果測試的土壤乾燥或含有大量的肥料,儀器不會顯示正確的pH值,因此,在土壤上撒上一桶水,等待20-30分鐘,然後再進行測試。
2.在使用儀器之前,一定要用濕布或砂紙徹底拋光金屬表面。當使用一個全新的儀器,一定要插入土壤幾次,以除去金屬表面的油性雜質。
3將儀器直接插入的田間或水稻土壤中。土壤完全嵌入金屬表面,使其緊密粘附在儀器的金屬電極。
4將儀器插入土壤後大約一分鐘,指針停止偏轉 ,然後讀取土壤的值。
5根據土壤條件(例如對金屬表面的附著力,水分含量或其含有的肥料),測量儀可能會記錄不同的值。因此平均進行多次測量是理想的。
6為了確定土壤是否進行適當石灰處理,要在一至二個星期後土壤充分混合後測量
使上上注意事項:
1.不要嚴重摔到機器
2.不適合測量溶液與堆肥
3.土壤積水不適合使用
4.不可用水沖(探頭不可水洗)
5.溼度7%以下讀值是正確的
6.使用完最好放入防潮箱
拿葡萄風信子來測試
土壤含水量為 3%
各作物適合 pH:
Slightly Tolerant(pH 6.8 to 6.0)
Asparagus
Beet
Broccoli
Cabbage
Cauliflower
Celery
Chard, Swiss
Cress, garden and upland
Chinese cabbage
Leek
Lettuce
Muskmelon
New Zealand spinach
Okra
Onion
Orach
Parsnip
Salsify
Soybean
Spinach
Watercress
Moderately Tolerant (pH 6.8 to 5.5)
Bean
Bean, lima
Brussels sprouts
Carrot
Collard
Corn
Cucumber
Eggplant
Garlic
Gherkin
Horse-radish
Kale
Kohlrabi
Mustard
Parsley
Pea
Pepper
Pumpkin
Radish
Rutabaga
Squash
Tomato
Turnip
Very Tolerant (pH 6.8 to 5.0)
Chicory
Dandelion
Endive
Fennel
Potato
Rhubarb
Shallot
Sorrel
Sweet potato
Watermelon
資料來源:
file:///Users/zhanrongzhang/Downloads/ph_soil_tester_en.pdf
樹木的臉
樹木的臉
Lakeshore Park, Novi Michigan
Hickory Glen Park, Commerce, Michigan
Lilley Cornett Woods, Hallie, Kentucky
Waterford Oaks County Park, Michigan
Kensington Metropark, Milford, Michigan
Rose Oaks County Park, Holly, Michigan
資料來源 :
軟木橡樹 Cork oak - Quercus suber
軟木橡樹
Cork oak - Quercus suber
在數千年以前,羅馬人發現,它會漂浮,用於製作漁網浮標及涼鞋。
現今,軟木橡樹是製作葡萄酒瓶塞原料主要來源,原生於歐洲西南部和非洲西北部,海拔300至500公尺的地方,樹高約20公尺,與其它橡樹不同,軟木橡樹是常綠的,葉子是不會掉落。
為什麼軟木橡樹有這麼厚的樹皮,因為林森火災發生時,厚的樹皮可以隔熱保護樹不致於被燒死,枝條可以迅速再生,來填補空缺的樹冠。在地中海火生態系統中獲得了生存勝利。
樹齡達到25年後,每隔9至12年就可以可收穫一次,收割軟木完全依靠人工。因取樹皮而不傷害樹木需要一些技術,收割人員需要培訓。一棵軟木橡樹在200年種植過程可以收穫約12次。每年可以生產 30萬噸,產值15億歐元,3萬人以此維生。
現今,軟木橡樹是製作葡萄酒瓶塞原料主要來源,原生於歐洲西南部和非洲西北部,海拔300至500公尺的地方,樹高約20公尺,與其它橡樹不同,軟木橡樹是常綠的,葉子是不會掉落。
為什麼軟木橡樹有這麼厚的樹皮,因為林森火災發生時,厚的樹皮可以隔熱保護樹不致於被燒死,枝條可以迅速再生,來填補空缺的樹冠。在地中海火生態系統中獲得了生存勝利。
樹齡達到25年後,每隔9至12年就可以可收穫一次,收割軟木完全依靠人工。因取樹皮而不傷害樹木需要一些技術,收割人員需要培訓。一棵軟木橡樹在200年種植過程可以收穫約12次。每年可以生產 30萬噸,產值15億歐元,3萬人以此維生。
資料來源:
Quercus suber, commonly called the cork
oak, is a medium-sized, evergreen oak tree in the section Quercus sect. Cerris.
It is the primary source of cork for wine bottle stoppers and other uses, such
as cork flooring and as the cores of cricket balls. It is native to southwest
Europe and northwest Africa. In the Mediterranean basin the tree is an ancient
species with fossil remnants dating back to the Tertiary period. The cork oak
forest is one of the major plant communities of the Mediterranean woodlands and
forests eco-region. Cork oak grows best in areas with cold, moist winters and
hot summers. It is commonly found at 300-600 m, but can occur up to 1,000 m
above sea level.
Cork oak bark has been harvested for thousands of years, and
with good reason. The Romans discovered that it would float and used it for
buoys in fishing nets, as well as for making sandals. Today, the main uses of
cork are in the production of wine bottle stoppers and insulation material.
From medieval times cork has been used to insulate buildings, keeping heat in
during the winter and keeping it out during the summer. Monasteries were
sometimes built with cork oak to protect them from the heat of the summer sun
Quercus suber is slow-growing and long-lived, some individuals
surviving to 250 years of age. Cork oak landscapes are mosaics of forest
habitats, comprising cork, holm and deciduous oak species, stone and maritime
pines, wild olive trees, maquis (a type of Mediterranean shrubland), and
pasture. Cork oak is an evergreen tree with low, twisted branches and downy
twigs. It can grow up to 20 m high, but it is typically more stunted in its
native environment. It has very thick and deeply ridged bark, which is
harvested as cork. The green leaves are 4-7 cm long, with spiny-ended lobes. and
their margins are often curved downwards. The leaves fall during the second
year of growth. Once a year, the tree produces fruits, known as acorns. The
acorns are 2-3 cm long, and sit in a deep cup fringed with elongated scales.
Cork oak is wind pollinated and monoecious (having separate male and female
flowers on the same plant). As with other oaks, the seed of Quercus suber
should be collected in the autumn when green. The viability of acorns can
decline very quickly. In the glasshouse, seeds germinate after around 6-8
weeks, whilst those in the field do not germinate until the following spring.
The tree forms a thick, rugged bark containing high levels of
suberin. Over time the cork cambium layer of bark can develop considerable
thickness and can be harvested every 7 to ten years to produce cork. The
harvesting of cork does not harm the tree, in fact, no trees are cut down
during the harvesting process. Only the bark is extracted, and a new layer of
cork regrows, making it a renewable resource.
As a pyrophyte, this tree has a thick, insulating bark that
makes it well adapted to forest fires. After a fire, many tree species
regenerate from seeds (as, for example, the maritime pine) or resprout from the
base of the tree (as, for example, the holm oak). The bark of the cork oak
allows it to survive fires and then simply regrow branches to fill out the
canopy. The quick regeneration of this oak makes it successful in the
fire-adapted ecosystems of the Mediterranean biome.
Virgin cork (or 'male' cork) is the first cork cut from
generally 25-year-old trees. Another 9 to 12 years is required for the second
harvest, and a tree can be harvested about 12 times in its lifetime. It is
obtained by peeling the bark away from the trunk, leaving a thin layer of new
cork still covering the functional part (secondary phloem) of the trunk. Cork
harvesting is done entirely without machinery, being dependent solely on human
labor. Usually five people are required to harvest the tree's bark, using a
small axe. The process requires training due to the skill required to harvest
bark without harming the tree. The European cork industry produces 300,000
tonnes of cork a year, with a value of €1.5 billion and employing 30,000
people. Wine corks represent 15% of cork usage by weight but 66% of revenues.
The cork left after stoppers have been made is used to make a
wide range of products, including insulation panels, floor and wall tiles and
sound-proofing in the car industry, as well as for handicrafts and artistic
uses. This include cork paper, used in printing, book covering, clothing
manufacture, cork maroquinerie and other products. Cork is also used in making
cricket balls, badminton shuttlecocks, handles of fishing rods and special
devices for the space industry.
The habitats that support cork oak are under ever-increasing
threat, mainly due to human activity such as the intensification of agriculture
and careless causes of forest fires (too frequent fires can damage the trees,
as it makes them susceptible to fungal infection).
The increasing use of plastic wine stoppers and metal screw tops
could reduce the value of cork oak forests, leading to their conversion or
abandonment. WWF has been working to publicise the environmental and economic
value of cork stoppers, in particular with the wine industry, to show what
would be lost if cork forests disappeared, and has a major programme to promote
products derived from sustainably managed cork oak forests.
Sources:
植物紋身傳感器 plant tattoo sensors
植物紋身傳感器 plant tattoo sensors
美國愛荷華州立大學的研究人員已經開發出這些“植物紋身傳感器”,可以及時直接測量農作物的用水量。 這些是傳感材料是以石墨烯做出來的,怎麼有點像蕨類孢子
"We're trying to make sensors that are cheaper and still high performing," Dong said.
美國愛荷華州立大學的研究人員已經開發出這些“植物紋身傳感器”,可以及時直接測量農作物的用水量。 這些是傳感材料是以石墨烯做出來的,怎麼有點像蕨類孢子
Engineers
make wearable sensors for plants, enabling measurements of water use in crops
Iowa State University plant scientist Patrick
Schnable quickly described how he measured the time it takes for two kinds of
corn plants to move water from their roots, to their lower leaves and then to
their upper leaves.
This was no technical,
precise, poster talk. This was a researcher interested in working with new,
low-cost, easily produced, graphene-based, sensors-on-tape that can be attached to plants and can provide new kinds of data
to researchers and farmers.
"With
a tool like this, we can begin to breed plants that are more efficient in using
water," he said. "That's exciting. We couldn't do this before. But,
once we can measure something, we can begin to understand it."
The
tool making these water measurements possible is a tiny graphene sensor that
can be taped to plants - researchers have dubbed it a "plant tattoo
sensor." Graphene is a wonder material. It's a carbon honeycomb just an
atom thick, it's great at conducting electricity and heat, and it's strong and
stable. The graphene-on-tape technology in this study has also been used to
produce wearable strain and pressure sensors, including sensors built into
a "smart glove" that measures hand movements.
Researchers
describe the various sensors and the "simple and versatile method for
patterning and transferring graphene-based nanomaterials" to create the
flexible sensors in a paper featured on the cover of the December 2017 issue of
the journal Advanced Materials Technologies.
The
research has been primarily supported by the Faculty Scholars Program of Iowa
State's Plant Sciences Institute.
Liang
Dong, an Iowa State associate professor of electrical and computer engineering,
is the lead author of the paper and developer of the technology. Seval Oren, a
doctoral student in electrical and computer engineering, is a co-author who
helped develop the sensor-fabrication technology. Co-authors who helped test
applications of the sensors are Schnable, director of Iowa State's Plant Sciences
Institute, a Charles F. Curtiss Distinguished Professor in Agriculture and Life
Sciences, the Iowa Corn Promotion Board Endowed Chair in Genetics and the Baker
Scholar of Agricultural Entrepreneurship; and Halil Ceylan, a professor of
civil, construction and environmental engineering.
"We're trying to make sensors that are cheaper and still high performing," Dong said.
To
do that, the researchers have developed a process for fabricating intricate
graphene patterns on tape. Dong said the first step is creating indented
patterns on the surface of a polymer block, either with a molding process or
with 3-D printing. Engineers apply a liquid graphene solution to the block,
filling the indented patterns. They use tape to remove the excess graphene.
Then they take another strip of tape to pull away the graphene patterns,
creating a sensor on the tape.
The
process can produce precise patterns as small as 5 millionths of a meter wide -
just a twentieth of the diameter of the average human hair. Dong said making
the patterns so small increases the sensitivity of the sensors.
(The
process, for example, produced a detailed image of Iowa State's Cyclone mascot
that was less than 2 millimeters across. "I think this is probably the
smallest Cyclone," Dong said.)
"This
fabrication process is very simple," Dong said. "You just use tape to
manufacture these sensors. The cost is just cents."
In
the case of plant studies, the sensors are made with graphene oxide, a material
very sensitive to water vapor. The presence of water vapor changes the
conductivity of the material, and that can be quantified to accurately measure
transpiration (the release of water vapor) from a leaf.
The
plant sensors have been successfully tested in lab and pilot field experiments,
Dong said.
A
new three-year, $472,363 grant from the U.S. Department of Agriculture's Agriculture
and Food Research Initiative will support more field testing of water transport
in corn plants. Michael Castellano, an Iowa State associate professor of
agronomy and William T. Frankenberger Professor in Soil Science, will lead the
project. Co-investigators include Dong and Schnable.
The
Iowa State University Research Foundation has applied for a patent on the
sensor technology. The research foundation has also granted an option to
commercialize the technology to EnGeniousAg - an Ames startup company
co-founded by Dong, Schnable, Castellano and James Schnable, an assistant
professor of agronomy and horticulture at the University of Nebraska-Lincoln, a
collaborator on another Iowa State sensor project that sparked establishment of
the company (and Patrick Schnable's son).
"The
most exciting application of the tape-based sensors we've tested so far is the
plant sensor," Dong said. "The concept of wearable electronic sensors
for plants is brand new. And the plant sensors are so tiny they can detect
transpiration from plants, but they won't affect plant growth or crop
production."
But
that's not all the sensors can do. The technology could "open a new
route" for a wide variety of applications, the authors wrote in their
paper, including sensors for biomedical diagnostics, for checking the
structural integrity of buildings, for monitoring the environment and, after
appropriate modifications, for testing crops for diseases or pesticides.
資料來源:
樹枝、樹幹、樹根,在一年不同季節生長量
樹枝、樹幹、樹根,在一年不同季節生長量
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