1    Бенов, Д., М. Маждраков. АСМО модул – Ръководство на потребителя.
2.    Маждраков, М., Д. Бенов, Г. Трапов. CAD Min Автоматизирано планиране на минните работи в откритите рудници.

1.    Географический факультет МГУ „М.В.Ломоносова“, Кафедра „Картографии и геоинформатики“, Учебные материалы, 3 курс.
2.    Aboelkhair, H., N. Yoshiki, W. Yasushi, S. Isao. Processing and interpretation of ASTER TIR data for mapping of rare-metal-enriched albite granitoids in the Central Eastern Desert of Egypt. J. Afr. Earth Sci., 58(1), 2010, pp.141-151.
3.    Di Tommaso, I., N. Rubinstein. Hydrothermal alteration mapping using ASTER data in the Infiernillo porphyry deposit, Argentina, Ore.Geol. Rev. 32, 2007, pp.275-290.
4.    Gangopadhyay, P., K. Lahiri-Dutt, K. Saha. Application of remote sensing to identify coalfires in the Raniganj Coalbelt, India, International Journal of Applied Earth Observation and Geoinformation 8, 2006, pp. 188–195.
5.    Guha, A., K. Kumar. Potential Of Thermal Emissivity For Mapping Of Greenstone Rocks and Associated Granitoids of Hutti Maski Schist Belt, Karnataka, The International Archives of the Photogrammetry, Remote Sensing and Spatial Information Sciences, Volume XL-8, 2014, ISPRS Technical Commission VIII Symposium, 2014, Hyderabad, India.
6.    Huo, H., Zh. Ni, C. Gao, E. Zhao, Y. Zhang, H. Zhang, Sh. Zhang, X. Jiang, X. Song, T. Cui. A Study of Coal Fire Propagation with Remotely Sensed Thermal Infrared Data, Remote Sens. 7, 2015, pp. 3088-3113.
7.    Ishimwe, R., K. Abutaleb, F. Ahmed. Applications of Thermal Imaging in Agriculture – A Review. Advances in Remote Sensing, 3, 2014, pp. 128-140.
8.    Liu, S., Z. Xu, L. Wu, B. Ma, X. Liu. Infrared Imaging Detection of Hidden Danger in Mine Engineering, Progress In Electromagnetics Research Symposium Proceedings, Suzhou, China, Sept. 2011, pp. 12-16.
9.    Liu, S., Y. Zhang, L. Wu, et al.. Infrared radiation feature of concrete during fracturing and water seepage process, Chinese Journal of Rock Mechanics and Engineering, Vol. 28, No. 1, 2009, pp. 53-58.
10.    Ninomiya, Y., B. Fu, T. Cudahy. Detecting lithology with Advanced Spaceborne Thermal Emission and Reflection Radiometer (ASTER) multispectral thermal infrared ‘‘radiance-at-sensor” data. Rem. Sen.Environ., 99 (1-2), 2005, pp.127-139.
11. Ninomiya Y., Advanced remote lithologic mapping in ophiolite zone with ASTER multispectral thermal infrared data. Proc. IEEE 2003 International Geoscience and Remote Sensing Symposium (IGARSS‘03) v. 3, Toulouse, France, 2003, pp.1561-1563.
12.    Pour, A., M. Hashim. Application of advanced spaceborne thermal emission and reflection radiometer (ASTER) data in geological mapping, International Journal of the Physical Sciences Vol. 6(33), 2011, pp. 7657 – 7668.
13.    Prakash, A. Thermal Remote Sensing: Concepts, Issues аnd Applications, International Archives of Photogrammetry and Remote Sensing. Vol. XXXIII, Part B1, Amsterdam, 2000, pp.239-243.
14.    Qiu, F., M. Abdelsalam, P. Thakkar. Spectral analysis of ASTER data covering part of the Neoproterozoic Allaqi-Heiani suture, Southern Egypt .J. Afr. Earth Sci. 44, 2006, pp.169–180.
15.    Torres, C. Mineral Exploration Using GIS and Processed Aster Images, Research jour. of Advance GIS EES 6513, 2007.
16. http://www.flirmedia.com/MMC/THG/Brochures/RND_005/RND_005 _EN.pdf
17.     http://www.flir.co.uk/cs/display/?id=51907.

1. Чобанов, К., А. Андреев, Н. Чомпалова. Проблеми и възможности за етапно разширение на рудник „Елаците“, България. XI-та Национална конференция по открит и подводен добив на полезни изкопаеми. Варна, 2011 г.
2. Иванов, И., Ив. Василев, Г. Петров. Проект за изграждане на наблюдателна система за следене на деформации в бордовете на открит рудник „Елаците“. 2010 г. Фаза: Идейна. Архив на „Елаците-Мед“ АД.
3. Солитех АД. Инвестиционен проект за комплексна система за автоматизиран мониторинг и ранно предупреждение на открит рудник „Елаците“. 2012 г. Архив на „Елаците-Мед“ АД.
4. Василев, Ив., И. Иванов и Г. Петров – Проектиране и реализация на автоматизирана мониторингова система за изследване на деформации в бордовете на открит рудник. VІ-та Международна конференция по геомеханика. Варна, 2014 г.
5. Маждраков М., И. Иванов, Ив. Василев и Д. Бенов – Методи за изследване на деформации в бордовете на открит рудник „Елаците“. XIII-та Национална конференция по открит и подводен добив на полезни изкопаеми. Варна, 2015 г.
6. Василев, Ив., Ж. Ялъмов. Модерна наземна радарна система наблюдава устойчивостта на откосите в рудник „Елаците“. Минно дело и геология, 2014/7-8, стр. 45-50.
7. Василев, Ив., И. Иванов. Приложение на дълбочинните репери като част от системата за следене на деформации в бордовете на открит рудник „Елаците”. V-та Международна конференция по геомеханика. Варна, 2012 г.
8. Василев Ив., Н. Тошков. Наблюдение на склоновата устойчивост в открит рудник „Елаците“. V-та Национална конференция по технологии и практики при подземен добив и минно строителство. Девин, 2016 г.

1. Bargagli, R. Moss and lichen biomonitoring of atmospheric mercury: A review – Science of the Total Environment., 572, 2016. – 216-231.
2. Miteva, I., Esbrí, J.M., Higueras, P. Moss biomonitoring of mercury on Almadén mining district, South Central Spain – Journal of Mining and Geological Sciences., 60, 2017 -138-141
3. Trujillo-Ñacle, A.L., Concentration of mercury in water by the wells of the Almadén region (Ciudad Real). Degree dissertation. Almadén School of Mines, UCLM, 2013
4. Francisco, R. Estudio hidroquímico de las aguas subterráneas del Valle de Juan Gil. – Degree dissertation. Almadén School of Mines, UCLM., 2016.
5. García-Donas, N. Concentraciones de mercurio y otros metales potencialmente tóxicos en la parcela agrícola y ganadera de Solana de Peñarrubia, situada al NE de Almadén – Degree dissertation. Almadén School of Mines, 2016.
6. Barquero, J.I., Rojas, S., Esbrí, J.M., García-Noguero, E.M., Higueras, P. Factors influencing mercury uptake by leaves of stone pine (Pinus pinea L.) in Almadén (Central Spain) – Environmental Science and Pollution Research. DOI:10.1007/s11356-017-0446-8, ISSN1614-7499, 2017.
7. Esbrí, J. M., A. Martínez-Coronado & P. L. Higueras. Temporal variations in gaseous elemental mercury concentrations at a contaminated site: Main factors affecting nocturnal maxima in daily cycles – Atmospheric Environment., 125, 2016. – 8-14.
8. Naharro, R., Esbrí, J.M., Amorós, J.A., Higueras, P. Experimentación en absorción de mercurio por plantas agronómicas. IV Congreso Internacional de Geología y Minería Ambiental para el Desarrollo y el Ordenamiento del Territorio, abstracts book., 2016.
9. Higueras, P. L., Amorós, J. Á., Esbrí, J. M., Pérez-de-los-Reyes, C., López-Berdonces, M. A., & García-Navarro, F. J. Mercury transfer from soil to olive trees. A comparison of three different contaminated sites – Environmental Science and Pollution Research., 23, 2016, – 6055-6061.
10. Hernández, A., Jébrak, M., Higueras, P., Oyarzun, R., Morata, D., Munhá, J. The Almaden mercury mining district, Spain – Mineralium Deposita., 34, 1999, – 539–548.
11. Ortego de la Fuente, A.I. El Mercurio en Chile: Andacollo y Punitaqui – Degree dissertation. Almadén School of Mines, UCLM, 2001.
12. Sánchez-Pizarroso, A.B. Investigación sobre presencia de mercurio en aguas superficiales de Almadén – Degree dissertation. Almadén School of Mines, UCLM, 2004.

1. Amankawah, H. Mathematical Optimiza-tion Models and Methods for Open-Pit Mining. 2011.
2. Eldert, J. v. Stochastic Open Pit Design with a Network Flow Algorithm: Application at Escondida Norte, Chile, Master of Science Thesis, 2011.

1. Raghavan R, Mohanan P K, Pastnaik S C. Hydrometallurgical processing of lead-bearing materials for the recovery of lead and silver as lead concentrate and lead metal, Hydrometallurgy, 2000, 58(2): 103−116.
2. Turan M D, Altundoğan H S, Tümen F. Recovery of zinc and lead from zinc plant residue, Hydrometallurgy, 2004, 75(1/4): 169−176.
3. Abdollahi P, Moradkhani D, Behnian D. Lead recovery from Iranian zinc plant residue using brine leaching method, XXIII International Mineral Processing Congress (IMPC). Istanbul, Turkey, 2006: 1515−1520.
4. Ruşen A, Sunkar A S, Topkaya Y A. Zinc and lead extraction from Çinkur leach residues by using hydrometallurgical method, Hydrometallurgy, 2008, 93(1/2): 45−50.
5. Moradkhani D, Farahmand F, Safarzadeh M S. Brine leaching of lead-bearing zinc plant residues: Process optimization using orthogonal array design methodology, Hydrometallurgy, 2009, 95(3/4): 316−324.
6. Stanojević, Dušan D.; Rajković, Miloš B.; Tošković, Dragan V.; Tomić, Milana A., Lead and silver extraction from waste cake from hydrometallurgical zinc production, Journal of the Serbian Chemical Society . May2008, Vol. 73 Issue 5, p585-593.
7. Vesna T. Conić, Branka D. Pešovski, Vladimir B. Cvetkovski, Zdenka S. Stanojević Šimsić, Suzana S. Dragulović, Danijela B. Simonović, Silvana B. Dimitrijević, Lead sulphate leaching by sodium chloride solution, Hem. Ind. 67 (3) 485–494 (2013)
8. Patent WO 2014/053705A1, Method for recovery of silver from Sulphur-containing zink leach residues, 2014.