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تأثیر مدیریت مرتع در میزان ترسیب کربن گونۀ گون کوهی (Astragalus peristerus) در مراتع فشم استان تهران | ||
| محیط شناسی | ||
| مقاله 15، دوره 41، شماره 1، فروردین 1394، صفحه 193-199 اصل مقاله (977.47 K) | ||
| نوع مقاله: مقاله پژوهشی | ||
| شناسه دیجیتال (DOI): 10.22059/jes.2015.53909 | ||
| نویسندگان | ||
| مریم صارمی* 1؛ عینالله روحیمقدم2؛ اکبر فخیره3 | ||
| 1دانشآموختۀ کارشناسی ارشد مرتعداری، گروه مرتع و آبخیزداری، دانشکدۀ منابع طبیعی، دانشگاه زابل | ||
| 2استادیار، گروه مرتع و آبخیزداری، دانشکدۀ منابع طبیعی، دانشگاه زابل | ||
| 3دانشیار گروه مرتع و آبخیزداری، دانشکدۀ منابع طبیعی، دانشگاه گنبد | ||
| چکیده | ||
| عامل اصلی دمای کرۀ زمین، دیاکسیدکربن است. بنابراین، به منظور کاهش دیاکسیدکربن اتمسفری و ایجاد تعادل در محتوای گازهای گلخانهای، کربن اتمسفر باید جذب و در فرمهای متعدد ترسیب شود. مراتع میتوانند از این نظر حائز اهمیت باشند. تحقیق حاضر به بررسی اثر مدیریت چرا و قرق در ترسیب کربن گون کوهی (Astragalus peristerus)، بهمنزلۀ یکی از گونههای غالب موجود در منطقۀ فشم میپردازد. در این پژوهش که در قالب طرح بلوک کاملاً تصادفی انجام شد، پس از استقرار ترانسکتها، پلاتگذاری انجام شد و گونههای غالب تعیین شدند. اندام هوایی و زیرزمینی گونهها برداشت و به منظور تعیین ضریب تبدیل کربن اندام هوایی و زیرزمینی به کربن آلی، از روش احتراق استفاده شد. به همین منظور نمونههای گیاهی که در آون خشک شده بودند کاملاً آسیاب شدند و از هر گونه 3 نمونۀ 5 گرمی تهیه شد. سپس این نمونهها توزین شدند و به مدت 5 ساعت در کورۀ الکتریکی با دمای 550 درجۀ سانتیگراد قرار گرفتند. با ضرب ضریب تبدیل کربن آلی در وزن تر اندام هوایی و زیرزمینی هر گونه، وزن کل کربن ترسیبشده به دست آمد. برای مقایسۀ وزن زیتودۀ گیاهی و ترسیب کربن گیاه بین دو منطقۀ قرق و تحت چرا از آزمون t-Test استفاده شد. با مقایسۀ ضریب تبدیل اندام هوایی و زیرزمینی گونۀ A.peristerus در دو مرتع قرق و چراشده، مشخص شد که اختلاف معنیداری بین ضریب تبدیل اندام مذکور در دو منطقه وجود ندارد (05/0P<). متوسط ترسیب کربن زیتودۀ هوایی و گیاهی گونۀ A.peristerus، در دو منطقۀ چراشده و قرق اختلاف معنیداری ندارد (05/0P<)، اما متوسط ترسیب کربن زیتودۀ زیرزمینی دارای تفاوت معنیدار بود (05/0P<). در نهایت میتوان گفت، افزایش بیومس اگر همراه چرای متعادل باشد، به علت ورود مقادیر بیشتر مواد آلی به سیستم خاک سبب ارتقای کل کربن موجود در مرتع خواهد شد. | ||
| کلیدواژهها | ||
| ترسیب کربن؛ چرا؛ قرق؛ گون؛ مراتع فشم | ||
| عنوان مقاله [English] | ||
| Pasture Management Effects on Carbon Sequestration Rates of Astragalus peristerus in Fasham Rangelands, Tehran. | ||
| نویسندگان [English] | ||
| Maryam Saremi1؛ Einollah Rouhimoghaddam2؛ Akbar Fakhireh3 | ||
| 1M.Sc. Postgraduate in range management, Natural resource Faculty of watershed and range management, Zabol University | ||
| 2Assistant Professor in Range and watershed Management, Faculty of range and watershed management science, Zabol University | ||
| 3Lectureship in Range and watershed Management, Faculty of range and watershed management science, Gonbad University | ||
| چکیده [English] | ||
| Introduction Climate change is one of the most important challenges in sustainable development, which has a negative impact on aquatic and terrestrial ecosystems. This will change rainfall patterns the power to increase hurricane and the risk of drought, flood and will strengthen pressure on water resources. Researchers generally agree that the main cause of the increase in global temperature is carbon dioxide. So in order to reduce atmospheric carbon dioxide and greenhouse gas balance of content, in the form of numerous atmospheric carbon capture and should be sequestration. Rangelands us good options for research on carbon sequestration projects, because on the one hand, many pastures Iran located in the arid and semiarid region that encompasses an area of about 90 million hectares. Due to the pasture species on carbon sequestration, several studies within and outside the country have been conducted. to investigate the carbon sequestration potential shrub species dominate (Helianthemum lippii, Dendrostellera lessertii and Artemisia sieberi) in arid rangelands Grbaygan FASA, showed that the ability of the three species differ in carbon sequestration and Artemisia sieberi plant was highest. Effect of different vegetation types on carbon sequestration in grasslands Miankaleh showed that the rate of carbon sequestration in plants and different species And with increasing levels of woody cover and percentage increases. Increase the electrical conductivity of the soil in sand sagebrush species like the atmosphere, reducing the amount of precipitation, but has an adverse effect on the species of wild pomegranate. In the review of rangeland carbon sequestration in North America, it was concluded that the relationship between carbon sequestration and the percentage of annual plants in pastures grazed negative. Mills rangeland carbon sequestration potential in two different species of Artemisia sieberi and Stipa barbata in management were assessed. According to the results, the percentages cover of plant species in the area because of the most plain and at the lowest long-term protection. The highest rate of carbon sequestration in the area because it was so S.barbata. In recent years the role of pastures as a basis for reducing atmospheric carbon dioxide and carbon sequestration are given more importance. But so far, many studies on the effects of grazing management on carbon sequestration is taken. This study evaluated the effects of grazing and enclosure management on carbon sequestration potential species (Astragalus peristerus) as one of the dominant species in Fasham rangelands. Material & Methods Material Study area at a distance of approximately 24km from the city Shemiran and the North East of Tehran is made. The study area has a 314 /5 ha area.159 acres it to preserve plant and animal species, enclosure the surface contains 155/5 hectares that are grazing in the face. Such a wide geographic region between longitudes51° 29¢to 51 ˚ 36¢and35˚ 55¢ to35˚ 58¢ is located. Based on data recorded rainfall, average rainfall will see website Fasham station as the station 696/ 2mm ,mean maximum and mean minimum annual rainfall is in 1321 and 248/5 mm. The average annual temperature in 15/2C° and the average warmest and coldest months of the year July and January, respectively, with 28/4 and 1/7C° have been. The absolute maximum and minimum recorded temperatures such as those belonging to two months, and 39 /8 and -11/4 C° is. Prevailing wind direction in the area southwest of the annual average wind speed of most is 6/3 Nat. The strongest wind direction and speed this year average West is 47 nots. General area of bare soil or soil with very low stone, gravel depth of medium to heavy texture on the floor with FAO classification Lithicand Eutric Leptosols or Calcaric Regosols are classified. Soil acidity this is the area between 7/2-7/5. Methods After preliminary identification and delimitation of the study area, in order to study the vegetation variables, stochastic methods - systematic methods. That each of the treatments (enclosure and under grazing) two transect length of 100 meters (a transect perpendicular to the direction of the slope and a transect slope) along each transect, 10 plots of one square meter (based on plant distribution pattern) was established. To determine canopy cover and dominant species, the existing plant lists and percentage of vegetation cover within each plot was determined to be separate species. For estimating above-ground biomass of crops including direct measurement method (cutting and weighing) were used. Underground biomass estimate of the root: shoot ratio was used. To this end, 10 of these were selected by digging the soil to a depth of root penetration root biomass was harvested. Then having a total weight of plant biomass (above ground biomass + underground biomass) mass ratio biomass underground aerial biomass was determined by applying the ratio of the weight of the aerial biomass, the weight of the underground biomass were estimated land area .aerial and ground to determine the conversion coefficient of carbon to organic carbon, the combustion method was used. Therefore, the plant samples were dried in the oven thoroughly grinding of any third sample was prepared from 5 g .Both were estimated land areas. Then the samples were weighed and the electric oven temperature to 550 C° was 5 hours. Samples (organic material or ash) after leaving electric oven and cool were weighted by the desiccator. Then the amount of organic carbon (g) of each plant organ separately calculated. Thus, the total weight of carbon sequestration was to (g m). This study was conducted in a completely randomized block design. The data normality by the Kolmogorov-Smirnov and homogeneous variances were analyzed by test Leven. To compare plant biomass weight, feed conversion and plant carbon sequestration in enclosure and area under grazing-Test was used totes it. SPSS16 software for statistical computing and graph drawing was done in Excel 2010. Discussion of Results&Conclusions Biomass weight The mean weight of aboveground and underground biomass of the species listed in the area of protection and because there is a significant difference (P < 0.01), but the biomass of plant species in the area, there is no significant difference. coefficient of biomass Conversion coefficient of biomass to organic carbon by comparing aerial and ground feed in the pasture enclosure and grazed A.peristerus determined no significant differences between feed There are two areas of the body (P<0.05). Carbon Sequestration Aerial biomass carbon sequestration and biomass of plant species in the area grazed and ungrazed A.peristerus no significant difference. But biomass carbon sequestration underground, cant difference was significant (P<0.05). Carbon distribution Both grazed and enclosure grassland carbon underground organs over shoots. Grassland ecosystem carbon levels are the best tools for effective management: grazing intensity and frequency of grazing through the system why are applied. More biomass of plant species in grazed A.Peristerus greater amount allocated to is.Compared to carbon convert coefficient of the two treatments grazed and enclosure A.peristerus grazing doesn’t represent cant difference in the two regions. Maybe animal grazing don’t have a large influence on the ability to store carbon is. Conversion coefficient of carbon in underground organs to above ground because of the higher wood moisture content less is more. Increase carbon sequestration from biomass grazed A.peristerus is underground. Among these are perennial plants that which is grazing the normal range increases the underground biomass of this species is the result of increasing carbon sequestration. Perhaps the greatest effect because the carbon dynamics because of the effect on the composition of plant communities. Grazing encourage the species of grasses and annual Forb which is the root cause of the fiber density, not down can contribute to carbon sequestration. The distribution of carbon in A.peristerus biomass underground was more than aerial biomass. Biomass carbon content below about 10% of the total carbon in biomass and its turnover is very slow performing (every 7 years). Thus, short-term disturbances above ground biomass can not only because of the great variation of soil organic carbon is stored. A large amount of organic matter inputs to soils of grazing land is the organ part underlying soil (e.g. root). As a result, the upper land disturbances such as grazing, fire, etc. on the bottom of the soil organic matter is indirectly. Can be said in general, pasture management is multi-faceted. Achieved if biomass is increased with moderate grazing, due to larger amounts of organic matter to the soil system will enhance the total carbon in pasture .There sult is making moderate grazing capacity of rangeland management is the best option to accompany taking advantage of the natural benefits of carbon storage and sequestration and them Itigation of global warming shall be. It is worth noting that in terms of soil and vegetation in enclosure pastures are stall condition, cand eploy and protectthe soiland be effective to taken later in the pasture ready to be principled. | ||
| کلیدواژهها [English] | ||
| Carbon sequestration, Grazing, enclosure, Astragalus peristerus, fasham pasture | ||
| مراجع | ||
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