日本地球惑星科学連合2019年大会

講演情報

[E] ポスター発表

セッション記号 S (固体地球科学) » S-CG 固体地球科学複合領域・一般

[S-CG49] ハードロック掘削科学~陸上掘削から深海底掘削、そしてオマーン~

2019年5月28日(火) 17:15 〜 18:30 ポスター会場 (幕張メッセ国際展示場 8ホール)

コンビーナ:道林 克禎(名古屋大学大学院環境学研究科地球環境科学専攻地質・地球生物学講座岩石鉱物学研究室)、高澤 栄一(新潟大学理学部地質科学科)、秋澤 紀克(東京大学 大気海洋研究所 海洋底科学部門)

[SCG49-P01] 比抵抗の測定に基づくオマーン掘削プロジェクトでの浸透率プロファイル

*片山 郁夫1岡崎 啓史2阿部 なつ江2Ulven Ole Ivar3Hong Gilbert4Zhu Wenlu5Cordonnier Benoit3畠山 航平1赤松 祐哉1道林 克禎6Godard Marguerite7Kelemen Peter8The Oman Drilling Project Phase 2 Science Party (1.広島大学、2.海洋研究開発機構、3.オスロ大学、4.ソウル国立大学、5.メリーランド大学、6.名古屋大学、7.モンペリエ大学、8.コロンビア大学)

Permeability is a key property that controls heat and chemical exchange in the oceanic lithosphere as well as microbial activity in the sub-seafloor. Although direct measurements of permeability were not made on board D/V Chikyu during analysis of cores from the Oman Drilling Project, we estimated permeability profiles based on onboard measurements of electrical resistivity. For each core sample, we measure its resistivity at nominally dry conditions to obtain the dry resistivity. We then saturate the sample with NaCl solution (3.5g/L) and repeat the resistivity measurements at brine-saturated conditions to obtain the wet resistivity. Owing to the conductive brine in the pore space, the wet resistivity is systematically lower than dry resistivity. Because the difference between dry and wet resistivity is predominantly controlled by the movement of dissolved ions in the brine that occupied the pore space, we can use the resistivity data to infer the volume fraction of pores that contribute to electrical transport (termed “transport porosity”). We apply the Hashin-Shtrikman upper bound to estimate transport porosity. The estimated transport porosity shows a positive correlation with bulk porosity measured on board (MAD analysis), but is approximately one order of magnitude lower. Using an empirical cubic law between transport porosity and permeability, we produce estimated permeability profiles for the crust-mantle transition zone and the serpentinized mantle sections in the Hole CM1A, BA1B, BA3A and BA4A. The results indicate, (1) the gabbro sequence exhibits a markedly lower permeability than the underlying mantle sequence, (2) serpentinized dunites have higher permeability compared to serpentinized harzburgites, and (3) the general variation of discrete sample permeability is correlated with fault zone and intervals with abundant fractures. These permeability structures are most likely modified by alteration and juxtapositions, and do not represent the in-situ profile of the oceanic lithosphere; but this technique can be applicable to infer on-board permeability in future hard rock drilling.