포어 네트웍 모델들 (Pore network model)은 토양 공극의 구조를 조사할 때 유용한 도구들이다. 이런 모델들은 삼차원 이미지들에서 공극의 구조와 관련된 양적 정보를 제공한다. 이 연구는 포어 네트웍 모델을 이용하여 공극의 구조와 수리학적 특성들을 양적으로 측정하였다. 연구목표는 큰 크기의 이미지에서 공극의 구조에 관한 양적 정보를얻기 위해 포어 네트웍 모델을 적용하고, 토양수분특성과 수리 전도도를 삼차원 이미지로부터 계산하고 이 값들은 실험을 통해 얻어진 실험값들과 결합하여 토양의 수리적 특성을 분석하는 것이었다. 토양 시료들은 발티모아 도시 중심에 있는발티모어 과학센터에 위치한 실험부지에서 채취되었다. 불교란 원주형 시료들이 채취되었고, 22 μm 의 해상도로 x선 단층 촬영되었다. 포어 네트웍은 중심축 변형에 의해 공극에서 축출되었고 이를 바탕으로 공극 구조가 계산되었다. 토양수분특성과 불포화 수리 전도도 값들은 토양 이미지에서 계산 되었다. 토양 밀도, 토양수분특성과 불포화 수리 전도도들은 3 토양 시료들로부터 실험을 통해 구하였다. 삼차원 이미지 분석은 토양 공극의 특성들을, 예를 들어 공극 부피, 길이, 굴곡도, 가장 정확히 분석하였다. 이런 정확한 분석은 토양 내 수문학적 정보를 정확히 산출할 수 있게 하였다. 계산된 값과 실험을 통한 실험치의 결합은 공극에 대한 더 광범한 범위를 분석할 수 있게 하였다. 이 연구를 통해 이미지에서 계산되고 측정된 수문학적 자료들은 토양내 대기공과 소기공을 모두 다 설명해 줄 수 있는 방법이라는 것이 밝혀졌다.

Pore network models are useful tools to investigate soil pore geometry. These models provide quantitative information of pore geometry from 3D images. This study presents a pore network model to quantify pore structure and hydraulic characteristics. The objectives of this work were to apply the pore network model to characterize pore structure from large images to quantify pore structure, calculate water retention and hydraulic conductivity properties from a three dimensional soil image, and to combine measured hydraulic properties from experiments with calculated hydraulic properties from image. Soil samples were taken from a site located at the Baltimore science center, which is located inside of the city. Undisturbed columns were taken from the site and scanned with a computer tomographer at resolutions of 22 μm. Pore networks were extracted by medial-axis transformation and were used to measure pore geometry from one of the scanned samples. Water retention and unsaturated hydraulic conductivity values were calculated from the soil image. Properties of soil bulk density, water retention and unsaturated hydraulic conductivity were measured from three replicates of scanned soil samples. 3D image analysis provided accurate detailed pore properties such as individual pore volumes, pore length, and tortuosity of all pores. These data made possible to calculate accurate estimations of water retention and hydraulic conductivity. Combination of the calculated and measured hydraulic properties gave more accurate information on pore sizes over wider range than measured or calculated data alone. We could conclude that the hydraulic property computed from soil images and laboratory measurements can describe a full structure of intra- and inter-aggregate pores in soil.

• Introduction
• Materials and Methods
• Results and Discussion
• Conclusion
• References

1 Bastardie, F., "X-ray tomographic and hydraulic characterization of burrowing by three earthworm species in repacked soil cores" 24 (24): 3-16, 2003

2 Wosten, J.H.M., "Using texture and other soil properties to predict the unsaturated soil hydraulic functions" 52 : 1762-1770, 1988

3 Strudley, M.W., "Tillage effects on soil hydraulic properties in space and time: State of the science" 99 : 4-48, 2008

4 Peth, S., "Three-dimensional quantification of intraaggregate pore-space features using synchrotron-radiationbased microtomography" 72 (72): 897-907, 2008

5 Pagliai, M., "The structure of two alluvial soils in Italy after ten years of conventional and minimum tillage" 34 (34): 209-223, 1995

6 Pagliai M., "The soil pore system as an indicator of soil quality" 35 : 2002

7 Amemiya, M., "The influence of aggregate size on soil moisture content capillary conductivity relations" 29 : 744-748, 1965

8 Horn, R., "Structure formation and its consequences for gas and water transport in unsaturated arable and forest soils" 82 : 5-14, 2005

9 Radcliffe, D.E., "Soil water movement. in: Soil Physics Companion" CRC Press 2002

10 Kutilek, M., "Soil hydraulic properties as related to soil structure" 79 : 175-184, 2004

11 Vogel, H.J., "Quantitative morphology and network representation of soil pore structure" 24 (24): 233-242, 2001

12 Wittmuss, H.D., "Physical and chemical properties of aggregates in a Brunizem soil" 22 : 1-5, 1958

13 Posadas, A.N.D., "Multifractal characterization of soil particle-size distributions" 65 (65): 1361-1367, 2003

14 Balland, V., "Modeling soil hydraulic properties for a wide range of soil conditions" 219 (219): 301-316, 2008

15 Pires, L.F., "Micromorphological analysis to characterize structure modifications of soil samples submitted to wetting and drying cycles" 72 (72): 297-304, 2008

16 Lindquist, W.B., "Medial axis analysis of void structure in three-dimensional tomographic images of porous media" 101 (101): 8297-8310, 1996

17 Vervoort, R.W., "Linking hydraulic conductivity and tortuosity parameters to pore space geometry and pore size distribution" 272 (272): 36-49, 2003

18 Lindquist, W.B., "Investigating 3D geometry of porous media from high resolution images" 25 : 593-, 1999

19 Tamboli, P.M., "Influence of aggregate size on moisture retention" 71 : 103-108, 1964

20 Leij, F.J., "Infiltration in two parallel soil columns" 42 (42): W12408-, 2006

21 Durner, W., "Hydraulic conductivity estimation for soils with heterogeneous pore structure" 30 : 211-233, 1994

22 Pires, L.F., "Gamma-ray computed tomography to investigate compaction on sewage-sludge-treated soil" 59 (59): 17-25, 2005

23 Gimenez. D., "Fractal models for predicting soil hydraulic properties: a review" 48 (48): 161-183, 1997

24 Abenny-Mickson, S., "Evaluation of two soil water retention models for the prediction of hydraulic conductivity of Daisen Kuroboku (volcanic ash) soil" 74 : 17-27, 1996

25 Ventrella, D., "Estimating hydraulic conductivity of a fine-textured soil using tension infiltrometry" 124 (124): 267-277, 2005

26 Durner, W., "Determination of parameters for flexible hydraulic functions by inverse modeling" 817-830, 1999

27 Sleutel, S., "Comparison of different nano-and micro-focus X-ray computed tomography set-ups for the visualization of the soil microstructure and soil organic matter.Comput.Geosci.34(8):931-938" 34 (34): 931-938, 2008

28 Ziska, L.H., "Characterization of an urban-rural CO2/temperature gradient and associated changes in initial plant productivity during secondary succession" 139 (139): 454-458, 2004

29 Hayashi, Y., "Changes in pore size distribution and hydraulic properties of forest soil resulting from structural development" 331 : 85-102, 2006

30 Green, R.E, "Calculation of hydraulic conductivity: A further evaluation of some predictive methods" 32 : 561-565, 1971

31 Udawatta, R.P., "CT-measured pore characteristics of surface and subsurface soils influenced by agroforestry and grass buffers" 145 (145): 381-389, 2008

32 Spohrer, K., "Applicability of uni- and bimodal retention functions for water flow modelling in a tropical acrisol" 5 : 48-58, 2006

33 Sheldrick, B.H., "Analytical Methods Manual. LRRI Contribution No. 84–30. Agriculture Canada, Ottawa, Ontario"

34 Mualem Y.A., "A new model for predicting the hydraulic conductivity of unsaturated porous media" 12 : 513-522, 1976

35 Elliot, T. R., "A comparison of optical and X-ray CT technique for void analysis in soil thin section" 141 (141): 60-70, 2007