All Issue

2020 Vol.25, Issue 1 Preview Page
31 March 2020. pp. 12-24
Abstract
References
1

Bierschenk, W.H., 1963, Determination well efficiency by mul-tiple step-drawdown tests, Intern. Assoc. Sci. Hydrol., 64, 493-507.

2

Bouwer, H. and Rice, R.C., 1976, A slug test for determining hydraulic conductivity of unconfined aquifers with completely or partially penetrating wells, Water Resour. Reser., 12(3), 423-428.

10.1029/WR012i003p00423
3

Cooper, H.H.Jr. and Jacob, C.E., 1946, A generalized graphical method for evaluating formation constants and summarizing well field history, Trans, Amer. Geophy. Union, 27(4), 526-534.

10.1029/TR027i004p00526
4

Fetter, C.W., 2001, Applied Hydrogeology 4th Ed, Prentice Hall, Upper Saddle River.

5

Hernández, M., Camprovín, P., Bernat, X., Massana, J., and Castelló, J., 2015, ASR en Barcelona: Nuevo régimen de operación para hacer frente a nuevos escenarios [ASR in Barce-lona: New operating regime to deal with new scenarios]. IV Jor-nadas de Ingeniería del Agua La precipitación y los procesos erosivos, Cordoba, October 2015.

6

Jacob, C.E., 1947, Drawdown test to determine effective radius of artesian well, Trans. Amer. Soc. Civil Engrs., 112, 1047-1064.

10.1061/TACEAT.0006033
7

KIGAM (Korea Institute of Geoscience and Mineral Resources), 2011, Application of analysis technique and model-ing for coupled groundwater-surface water flow system, KIGAM, 491 p.

8

Kim, H.S., Bary, J., and Elton, L., 2003, Groundwater securing and supplying techniques using the aquifer storage and recovery (ASR) – Case study on actual groundwater supply using the ASR, Oregon state, USA, Proceedings of the Korean society of soil and groundwater environment 2003 fall meeting, Jeju.

9

KOSIS (Korean Statistics Information Service), 2019, https:// kosis.kr/ [accessed 2019.08.16]

10

KRC (Korea Rural Community Corporation), 2014, A study on the supply plan of clean groundwater and groundwater heat for facilities in agricultural complex, KRC, Naju, 221 p.

11

KRC (Korea Rural Community Corporation), 2017, A report on the artificial recharge and recovery to Danmok greenhouse facil-ities zone, Jinju, Gyongsangnamdo, Korea, KRC, Naju, 164 p.

12

KREI (Korea Rural Economic Institute), 2019, Agriculture out-look 2019 Korea, 834 p.

13

Lee, H., Koo, M., and Oh, S., 2019, Modeling stream-aquifer interactions under seasonal groundwater pumping and managed aquifer recharge, Groundw., 57(2), 216-225.

10.1111/gwat.12799
14

MAFRA (Ministry of Agriculture, Food, and Rural Affairs) and KRC (Korea Rural Community Corporation), 2015, A report on feasibility for an artificial recharge and recovery to greenhouse facilities zones, MAFRA and KRC, Sejong, 268 p.

15

MAFRA (Ministry of Agriculture, Food, and Rural Affairs) and KRC (Korea Rural Community Corporation), 2018, A annual report on the rural groundwater management network system, Korea, MAFRA and KRC, Sejong, 173 p.

16

Malisa, M.L. and Randolph, R.B., 1986, Methods and computer program documentation for determining anisotropic transmissiv-ity tensor components of two-dimensional ground-water flow:

10.3133/ofr86227
17

U.S. Geological Survey Open-File Report 86-227, 64 p.

18

Maliva, R.G., Guo, W., and Missimer, T.M., 2006, Aquifer stor-age and recovery: Recent hydrogeological advances and system performance. Water Environ. Res., 78(13), 2428-2435.

10.2175/106143006X123102
19

MLTMA (Ministry of Land, Transportation, and Maritime Affairs) and K-water, 2009, A practical guide on developing groundwater well and its operating facilities, MLTMA and K-water, Gwacheon, 191 p.

20

MOLIT (Ministry of Land, Infrastructure, and Transportation), 2017, The national groundwater management plan 2nd Ed. (2017~2026), MOLIT, Sejong, 168 p.

21

Moon, S.H., Kim, Y., Jeong, Y.Y., and Hwang, J., 2016, Ground-water-stream watger interaction induced by water curtain culti-vation activity in Sangdae-ri area of Cheong-ju, Korea, Econ. Environ. Geol., 49(2), 105-120.

10.9719/EEG.2016.49.2.105
22

MSIT (Ministry of Science and ICT) and KIGAM (Korea Insti-tute of Geoscience and Mineral Resources), 2013, Development of intergrated core technologies in aquifer recharge system for groundwater sustainability, MSIT and KIGAM, Sejong, 261 p.

23

MST (Ministry of Science and Technology) and K-water, 2004, Sustatinable groundwater development and artificial recharge, MST and K-water, Gwacheon, 850 p.

24

Rao, R. and Giridhar, MVSS., 2014, Rooftop rainwater harvest-ing for recharging shallow groundwater, J. Geol. Geosci., 3(6), 1-6.

10.4172/2329-6755.1000172
25

Song, S.H., Lee, B.S., and An, J.G., 2016, Quantitative evalua-tion for improvement effects of performance after mechanical rehabilitation treatments on agricultural groundwater well, J. Soil Groundw. Environ., 21(4), 42-49.

10.7857/JSGE.2016.21.4.042
26

Stuyfzand, P.J., 2016, Histroy of managed aquifer recharge in the Netherlands, Proceedings of IAH (International Association of Hydrogeologists) 43rd congress, Montpellier, France.

27

Theis, C.V., 1935, The relation between the lowering of piezo-metric surface and the rate and duration of discharge of a well using ground water storage, Trans. Amer. Geophy. Union, 16(2), 519-524.

10.1029/TR016i002p00519
Information
  • Publisher :The Korean Society of Soil and Groundwater Environment
  • Publisher(Ko) :한국지하수토양환경학회
  • Journal Title :Journal of Soil and Groundwater Environment
  • Journal Title(Ko) :지하수토양환경
  • Volume : 25
  • No :1
  • Pages :12-24
  • Received Date : 2019-10-19
  • Revised Date : 2019-11-14
  • Accepted Date : 2020-02-13