Graduate School of Science and Engineering, Kagoshima University

Similar documents
CHEMICAL GEOTHERMOMETERS FOR GEOTHERMAL EXPLORATION

Geochemical monitoring of the response ofgeothermal reservoirs to production load examples from Krafla, Iceland

Geochemical Characteristics of Reservoir Fluid from NW-Sabalan Geothermal Field, Iran

Fluid Geochemistry at the Nir Geothermal Field, Nw-Iran

FLUID-MINERAL EQUILIBRIA AND SUBSURFACE TEMPERATURE EVALUATION OF SELECTED HOT SPRINGS, JIANGXI PROVINCE, SE-CHINA

Geochemical Modelling of Low-Temperature Geothermal Fields from Bihor County, Romania

Geochemical Monitoring of the Lakes District Area

MULTICOMPONENT EQUILIBRIUM MODELS FOR TESTING GEOTHERMOMETRY APPROACHES

GEOCHEMISTRY OF RWENZORI HOT SPRINGS. Vincent Kato Department of Geological Survey and Mines, Entebbe, Uganda

Effective geochemical methods for identifying geothermal systems in the western branch of the EARS

GEOCHEMICAL CHARACTERISTICS OF ACID FLUIDS IN MT PINATUBO, PHILIPPINES

Enhancement of Silica-Enthalpy Mixing Model to Predict Enthalpy of Geothermal Reservoir

HEAT AND MASS TRANSFER PROCESSES AFTER 1995 PHREATIC ERUPTION OF KUJU VOLCANO, CENTRAL KYUSHU, JAPAN

Prediction of Calcite Scaling at the Oguni Geothermal Field, Japan: Chemical Modeling Approach

Bouillante geothermal field: mixing and water/rock interaction processes at 250C.

Geochemical and Hydrological Assessment of Thermal Features in the Vicinity of the Champagne Pool in the Waiotapu Geothermal System

SURFACE EXPLORATION AND MONITORING OF GEOTHERMAL ACTIVITY IN THE KVERKFJÖLL GEOTHERMAL AREA, CENTRAL ICELAND

Estimation of reservoir temperature using silica and cationic solutes geothermometers: a case study in the Tengchong geothermal area

DISSOLUTION, TRANSPORT AND PRECIPITATION OF SILICA IN GEOTHERMAL SYSTEM

Carbonates and Silica Scaling Model Applied to Hot Water Pipes for Sanitary Use at Hotel Río Perlas, Costa Rica

Luigi Marini and Claudio Pasqua. ELC-Electroconsult S.p.A. Via 1 Maggio 41, I Baranzate, Milano, Italy

The Initial-State Geochemistry as a Baseline for Geochemical Monitoring at Ulubelu Geothermal Field, Indonesia

THE CHEMICAL CHARACTERISTICS OF GEOTHERMAL FLUIDS IN JIAODONG PENINSULA, SHANDONG, CHINA

GEOCHEMICAL INTERPRETATION OF THERMAL FLUID DISCHARGE FROM WELLS AND SPRINGS IN BERLÍN GEOTHERMAL FIELD, EL SALVADOR

Kizito Maloba Opondo. Kenya Electricity Generating Company

Study on Dālaki Geothermal Resource in Bushehr Province, in the North of Persian Gulf

APPLICATION OF GEOCHEMICAL METHODS IN GEOTHERMAL EXPLORATION. Halldór Ármannsson November 2007

Various Geoscientific Investigations of Low-Enthalpy Geothermal Sites in the United Arab Emirates

HYDROTHERMAL FLUID FLOW AND MINERAL ALTERATION IN A FRACTURED ROCK UNDER MULTIPHASE H 2O- CO 2 MIXTURE CONDITIONS

Anna Yushantarti Center For Mineral, Coal, and Geothermal Resources, MEMR Jl Soekarno Hatta 444, Bandung, Indonesia

GEOCHEMICAL INTERPRETATION OF THE MASAYA-GRANADA-NANDAIME CHEMICAL DATA, NICARAGUA

Geothermometer, Geoindicator and Isotope Monitoring in Lahendong Wells during

MODELING OF FORMATION OF ACID WATER DISCHARGED FROM HIGH TEMPERATURE GEOTHERMAL RESERVOIR

JosC Tenorio Mejia', Franco D'Amore' and Jane Y. Gerardo3

ALTERATION ZONATION OF SILICA MINERALS IN A GEOTHERMAL SYSTEM A NUMERICAL SIMULATION BASED ON REACTION-TRANSPORT MODEL

ASSESSMENT OF GEOTHERMAL RESOURCES AT THE AL-LITH AREA, KINGDOM OF SAUDI ARABIA

GEOCHEMISTRY OF THE TENDAHO GEOTHERMAL FIELD, ETHIOPIA

The geothermal potential of Jizan area, Southwestern parts of Saudi Arabia

Preliminary Assessment of the Ohinewai Low Enthalpy Geothermal System, New Zealand

THE FLUID CHARACTERISTICS OF THREE EXPLORATION WELLS DRILLED AT OLKARIA-DOMES FIELD, KENYA

Chapter 7 Metamorphism, Metamorphic Rocks, and Hydrothermal Rocks

WATER-ROCK INTERACTION IN THE BAKKI LOW-TEMPERATURE GEOTHERMAL FIELD, SW-ICELAND

Study on the Geochemistry of Potential High Temperature Geothermal Resources in Taxkorgan, Xinjiang, China

Geochemistry and Isotope Study of Discharged Geothermal Fluids, NW Sabalan Geothermal Field, NW Iran

Model Study of Formation of the Cap Rocks for Geothermal System Using ChemTOUGH2

Geochemistry: water-rock interaction, water and gas geochemistry, isotopes, geothermometry

GEOTHERMAL EXPLORATION PHASE

Mercury Concentrations in Fumarolic Gas Condensates and Mercury Chemical Forms in Fumarolic Gases

Heat (& Mass) Transfer. conceptual models of heat transfer. large scale controls on fluid movement. distribution of vapor-saturated conditions

Taller de Geotermica en Mexico Geothermal Energy Current Technologies

The 1997 phreatic eruption of Akita-Yakeyama volcano, northeast Japan: Insight into the hydrothermal processes

EQUILIBRIUM VERSUS KINETICS IN C02 DOMINATED HYDROTHERMAL ALTERATION F. MAY

Evidence of a recent input of magmatic gases into the quiescent volcanic edifice of Panarea, Aeolian Islands, Italy

APPLICATION OF GEOCHEMICAL METHODS IN GEOTHERMAL EXPLORATION

predictive mineral discovery*cooperative Research Centre A legacy for mineral exploration science Mineral Systems Q3 Fluid reservoirs

APPLICATION OF GEOCHEMICAL METHODS IN GEOTHERMAL EXPLORATION

A New Method of Evaluation of Chemical Geothermometers for Calculating Reservoir Temperatures from Thermal Springs in Nevada

AN OVERVIEW OF THE GEOTHERMAL POTENTIAL OF PAPUA NEW GUINEA

Thermal springs and balneology in the Peri-Adriatic area: geochemical status and prospects

A Comparative Study on the Energy Potential of Geothermal Fields. along the Qinghai-Tibet Railway in China

Isotope and Gas Geochemistry of Dieng Geothermal Field, Indonesia

(Received December 18, 2002; Revised February 12, 2003; Accepted February 20, 2003)

Active Faults and Geothermal Potential in Vietnam: a Case Study in Uva Area, Dien Bien Phu Basin, Along Dien Bien -Lai Chau Fault

Quantification of the 3D thermal anomaly in the orogenic geothermal system at Grimsel Pass

Japan Engineering Consultants, Inc., Energy and Industrial Technology Development Organization,Tokyo, Japan

INTERPRETATION OF CHEMICAL COMPOSITION OF GEOTHERMAL FLUID FROM THE GEOTHERMAL FIELD OF BARANSKY VOLCANO, ITURUP ISLAND, RUSSIA

David I. Norman and Joseph N. Moore

GEOCHEMISTRY CHANGE DURING CIRCULATION TEST OF EGS SYSTEM

Opportunities for Geothermal Development Created by New Technologies S2-1-2

HYDROTHERMAL MODEL OF THE MOMOTOMBO GEOTHERMAL SYSTEM, NICARAGUA

WATER-ROCK INTERACTION IN A LOW-ENTHALPY BACK-RIFT GEOTHERMAL SYSTEM, NEW ZEALAND

Hydrogeological Modelling of Some Geothermal Waters of Havran, Ivrindi and Gonen in the Province Capital of Balikesir, Western Anatolia, Turkey

Status of geothermal energy exploration at Buranga geothermal prospect, Western Uganda

GEOCHEMICAL INTERPRETATION OF THERMAL WATER AND BOREHOLE WATER FROM THE ASAL-GHOUBBET REGION, DJIBOUTI

Chapter 4 Rocks & Igneous Rocks

INTRODUCTION TO GEOCHEMICAL MAPPING

South Island Barrier Volcano Namarunu. Emuruangogolak. Kilimanjaro

GEOCHEMICAL STUDY OF THE XIANYANG LOW-TEMPERATURE GEOTHERMAL FIELD, SHAANXI PROVINCE, CHINA

CO 2 -water-rock reactivity at hydrothermal temperatures: The BigRig2 experiment

Estimate of the Aquifer Temperature of Assammaqieh Well in Akkar by Geothermometric Equations

BIBLIOGRAPHIC REFERENCE

organisms CaCO 3 + H 2 O + CO 2 shallow water

Numerical Simulation of Devolution and Evolution of Steam-Water Two-Phase Zone in a Fractured Geothermal Reservoir at Ogiri, Japan

40 th Anniversary Chemical Characteristics of Geothermal Fluids in Jiaodong Peninsula, Shandong, China. Tingting Zheng Student UNU GTP

Thermal Water's Isotope Geochemistry Study of Evros Area, NE Greece

SUBSURFACE HYDROTHERMAL ALTERATION AT THE ULUBELU GEOTHERMAL FIELD, LAMPUNG, SOUTHERN SUMATRA, INDONESIA. Suharno 1, 2 and PRL Browne 2

MODELING AND NUMERICAL ANALYSIS OF THE TWO-PHASE GEOTHERMAL RESERVOIR AT OGIRI, KYUSHU, JAPAN

Published by Keck Geology Consortium

Depth estimation of fumarolic gas source deduced by fume pressure measurement

INTERPRETATION OF GEOCHEMICAL WELL TEST DATA FOR WELLS OW-903B, OW-904B AND OW-909 OLKARIA DOMES, KENYA

Numerical Simulation Study of the Mori Geothermal Field, Japan

HOT SPRING MONITORING AT LASSEN VOLCANIC NATIONAL PARK, CALIFORNIA Michael L. Sorey. U.S. Geological Survey Menlo Park, California

Arsenic and Mercury Concentrations at Several Geothermal Systems in West Java, Indonesia

Takigami geothermal system, northeastern Kyushu, Japan

Chapter 4 Up from the Inferno: Magma and Igneous Rocks

Effect of chemical composition to large scale CO 2 Injection in Morrow Sandstone, Farnsworth Hydrocarbon Field, Texas, USA

CO-EXISTING VOLCANISM AND HYDROTHERMAL ACTIVITY AT KELIMUTU, FLORES ISLAND, EASTERN INDONESIA

APPLICATION OF GEOCHEMICAL METHODS IN GEOTHERMAL EXPLORATION

FLUID STRATIGRAPHY OF THE COSO GEOTHERMAL RESERVOIR

PHYSICAL AND CHEMICAL CHARACTERISTICS OF HYDROTHERMAL HEAT CARRIER OF MUTNOVSKOYE FIELD

Transcription:

20 +- -,+ +. / +- Geochemical Interpretation on Hydrothermal Formation Mechanism of the Thermal Water in the Iwodani Region and the Vicinity of the Hayashida Region of the Kirishima Volcanic Area Shun-ichi FUJITA and Hayao SAKAMOTO Graduate School of Science and Engineering, Kagoshima University Abstract The Kirishima volcanic region, lying on the northern extension of the Ryukyu arc, is located in Kagoshima Prefecture, south Kyushu, Japan. There are many thermal manifestations related to volcanic activity in this area. We define chemical features of hydrothermal system of the Iwodani region and the vicinity of the Hayashida region in the Kirishima volcanic area on the basis of Giggenbach s chemical geothermometry, mineral equilibrium calculation, etc. The water samples for chemical analysis were collected from some hot spring in the vicinity of the Hayashida region and mud pool in the Iwodani fumarolic area. Almost all the collected water samples were acid-so. type water, generated by steam heating, and the Giggenbach s Na-K-Mg and K/Mg-K/Ca diagram indicated immaturity of the water. It was considered that water samples were secondary thermal water formed by mixture of shallow groundwater and the steam, which separated from two-phase geothermal fluid formed underground. Therefore it is believed that there is hardly any mixture of the thermal water in the Iwodani region that derives from deep underground, but it is believed that there is a little mixture of the thermal water in the vicinity of the Hayashida region that derives from deep underground. The reservoir temperature of the fluid was roughly estimated to be about /- 11 (the Iwodani region), 2-31 (the vicinity of the Hayashida region) by K/Mg geothermometry. These acid-so. type waters lie on the Giggenbach s rock-dissolution line. The result showed that thermal water has been formed by water-rock interaction. Key words : Kirishima volcano, Hydrothermal system, Chemical geothermometry,

/,,**, 21 Water-Rock interaction : + +3/1 +303 +3/1 +33. -* +33. +* +330 +* km Ohba et al. +331 ;,**+ +33* ; Ohba et al. +331 ;,*** Mud Pool Giggenbach, +322,,*** Na,K Ca,,Mg, SiO, Cl, IC SO. IC - -+ Table + Fig. + Ingebritsen and Sorey +322 Yano and Ishido +33/ Cap rock

22 Table + Chemical data of thermal waters collected from the Iwodani area and around the Hayashida area, and of condensate collected from the Iwodani area of the Kirishima volcanic region. The data of thermal water were cited from Fujita et al. (,***). Location Date ph Temp. Na mg l + K mg l + Ca, mg l + Mg, mg l + Cl, SO. SiO, mg l + mg l + mg l + K-Mg** Iwodani +, -. / 0 1 2* 32/+,/+*,.3 -.* -.+ -.*,.2,.1 2.1/ 2.+1 +..* +..3 +,.0 3.*+ +,.2 *.,0 /..1 /.*3 ++.* ++.1 1.+1 -.3, +*., *.*+ 0.+3 1.++ 2.** +*.+ +/.2,.3, 0.,0,.+,,3 -.0 -,/.+. 00+ /0+ 0*., +.. +02,-0,,,,,.,/*,/3.0., /2., 12., /0.+ 0+., 2/.- 00.+ 32.0 -.13 -.01../0 /.3- ++./ /.*, 1.3*..*0 -.2-,.0,,..- -.1/,.++,.+, *./+ 0-.0 0,.- 11.1 10.* /1.- /-.- 03.. Hayashida +, -. / 0 1 2 3 +* ++ 0*.3 /1./ /1.0 0/.2 /2.2.2.2.2., 0+.2 /2.2 /-.1 /+.+ -+., -*., -*.2 -/.+.*.1,,.1,-.2-3.1-1..,1.0,/.. +/.2 +/.,,*.3 +/.3,-.0 ++.* ++.*,*.0 +2., +,.0 +-.2 -.+ -.- -.. -.* -.+,+.2,*.0,,.* +1..,*.0 +1.1 +0.3,+.+,*.- +2.- +2.+ +,.2 +-.* +,.+ + +0.* 3.0. +*., +-.2 +,.- +*.2 +*.* 0.3+ 0.1+ 0.33 1./- 2.,2..2/ /.*. 1.,1 0./+ /.3. /..,,+0,++,.2,/-,3+ +1/ +0.,-.,*3,-1,,* +-0 +-- +.* +.0 +1- +*3 ++* +3+ +1. +,2 +-- 23.0 22./ 23.1 2,.2 2/.2 22.2 21.+ 22.+ 22./ 21.* 21.3 Myoban +, -. / -.+ -.. 01.+ 0-.* /1., 02.1 -/./ -/.+,3.2 -*., -,.+ +3.2,,.,,/.+ -*.+,1.* +..* +*., 3./2 +,.+ +*.* ++.2 1.,- 0.1, 1.11 0.3.../.,-.0,/.0 +2./ +3.3 ++..,+1,*2,-3,-, +/, +01 +/* +01 +01 +,* 23./ 3-.0 30.0 3/., 2-.1 Enoo +, - / /*.2.1.2 -.- -.-,/.-,...,0.+ +1.+,,.,,*.1 +*./ 3.2. +*.2 /..* /.*. /.0/ +1.+ +0.0 +1.1 +2* +1* +3. ++1 ++/ ++3 20./ 3.., 3*.3 Note : * condensate of fumarolic gas, **geothermometric temperature,,300+ mg l + *./+ mgl + 0*., mgl +

/,,**, 23 ++.*,0./ mgl + -, Na-K-Mg Giggenbach +322 Na,K,Mg, - NaK KMg Na-K-Mg albitek K-feldsparNa *.2 K-mica*., chlorite/.. silica,k,.2 K-feldspar+.0 H,OMg, Full equilibrium Immature water Giggenbach, +322 Na-K-Mg Fig., NaK KMg Fig. + Fig. + Relationships between Cl, and SO. concentrations of thermal waters and condensate collected from the Iwodani region and the vicinity of the Hayashida region of the Kirishima volcanic area. Maruo data were cited from NaK Fujita and Sakamoto (,**+).

24 NaK,1*-** Giggenbach +322 NaK KMg Giggenbach, +322 KMg /-11 2-31 -- KMg-KCa Giggenbach +322 K,Ca,,Mg, - KMg-KCa Giggenbach +322 *.2 K-mica*., chlorite/.. silica,k,.2 K-feldspar+.0 H,OMg, - K-feldsparCO,Ca, K-micacalcite0 silica,k KMg-KCa Full equilibrium KCa CO, KMg K-Ca-Mg Fig. - Giggenbach +322 CO, Fig., Na-K-Mg diagram (after Giggenbach, +322) of thermal waters from the Iwodani region and the vicinity of the Hayashida region. Full equilibrium line is derived from chemical equilibria between thermal water and the assemblage of minerals ; albite, K-feldspar, K-mica, chlorite, silica. Maruo data were cited from Fujita and Sakamoto (,**+).

/,,**, 25 Fig. - K/Mg-K/Ca diagram (after Giggenbach, +322) of thermal waters from Iwodani region and the vicinity of the Hayashida region. Full equilibrium line is derived from chemical equilibria between thermal water and the assemblages of minerals ; K-feldspar, chlorite, K-mica, calcite, silica. The rock dissolution line refers to solutions of +*, +**, +,*** g of an average crustal rock in + kg of water (after Giggenbach, +322). Maruo data were cited from Fujita and Sakamoto (,**+). Fig.. Relationships between temperatures and SiO, concentrations of thermal waters and condensate water collected from the Iwodani region and the vicinity of the Hayashida region. CO, Immature water

26 CO, -. +, -., CO, KMg-KCa -. ao SiO, SiO, Nicholson +33- SiO, Fig.. R, *./*.0,.,,.. Fig. / A schematic presentation of a genetic model of thermal water in the Iwodani region and the vicinity of the Hayashida region of the Kirishima volcanic area (modified from Fujita et al.,,***).

/,,**, 27. Fig. / Na-K-Mg KMg /-11 2-31 KMg-KCa /. +- 2,- +3/1 : 0-.--...,*** : /* +++.,**+ : /*,,+,,3. Giggenbach, W. F. (+322) : Geothermal solute equilibria. Derivation ofna-k-mg-ca geoindicators. Geochim. Cosmochim. Acta, /,,,1.3,10/. +33. : 03 +23,*3. Ingebritsen, S.E. and Sorey, M.L. (+322) : Vapor-dominated zones within hydrothermal systems: evolution and natural state. J. Geophys. Res, 3-, +-0-/+-0//. +330 :.+,+/,,/. Nicholson, K (+33-) : Geothermal Fluids. Springer Verlag Berlin Heidelberg, 031+. Ohba, T., Nogami, K. and Hirabayashi, J. (+331) : Hydrothermal System ofthe Kirishima

28 Volcanic Area Inferred from the Chemical and Isotopic Composition of Spring Waters and Fumarolic Gases. Bull. Volcanol. Soc. Japan,.,, ++/. +31/ : / + +303 : /, 2/+*+. +33* : + +23. Yano, Y. and Ishido, T. (+33/) : Numerical Modeling of the Evolution of Two-phase Zone under a Fractured Caprock. Geothermics,,., /*1/,+.

2024 © sciencedocbox.com Privacy Policy | Terms of Service | Feedback