Miklas Scholz

Miklas Scholz is a Professor in Water Resources Engineering at Lund University. He holds the Chair in Civil Engineering at University of Salford[1] where he serves as a Professor and the Head of the Civil Engineering Research Group. Scholz is also a Distinguished Professor at Johannesburg University and the Central University of Technology.

Miklas Scholz
Born (1970-09-16) September 16, 1970
OccupationProfessor, editor and researcher
Academic background
EducationMSc in Water Resources Engineering
PhD in Civil Engineering
PgC in Higher Education Practice
DSc in Civil Engineering
Alma materLund University
Academic work
InstitutionsLund University
University of Salford
University of Johannesburg
Central University of Technology

Scholz's main research areas are treatment wetlands, integrated constructed wetlands (ICW), sustainable flood retention basins (SFRB), permeable pavement systems, decision support systems, ponds and capillary suction time. He has published 4 books and over 240 articles in various journals. He has also served as an Editor of several scientific journals. In 2020, his work has been cited over 6800 times according to Google Scholar, with an h-index of 42.[2]

In 2019, Scholz was awarded €7,000,000 for the EU H2020 REA project Water Retention and Nutrient Recycling in Soils and Streams for Improved Agricultural Production (WATERAGRI).[3] He received €1,520,000 in 2018 for the JPI Water Project 2018.[4]

Education

Scholz completed his M.Sc. in Water Resources Engineering from City, University of London in 1995. He did his doctoral studies in Civil Engineering from the University of Birmingham in 1997. He then completed his PgC in Higher Education Practice from the University of Bradford in 2002. Scholz obtained a DSc in Civil Engineering from the University of Salford in 2017.[5]

Career

Academic career

Scholz started his academic career as a lecturer at the University of Bradford. He worked at the University of Edinburgh between 2002 and 2010. He left the University of Edinburgh and joined University of Salford as a full professor. There he was appointed as Chair in Civil Engineering and later as the Director of the Civil Engineering Research Centre (CERC). From 2016 till 2019, he served as a Guest Professor at the University of Electronic Science and Technology of China. He is a Distinguished Professor of Civil Engineering at the Central University of Technology and of Civil Engineering Science at the University of Johannesburg. He is a Professor of Water Resources Engineering at Lund University.[1]

Scholz has served as the Editor of 34 scientific journals. He is the Editor of Exploratory Environmental Science Research[6] and Journal of Environmental and Life Sciences.[7]

Research

Scholz's research is mostly focused on treatment wetlands, integrated constructed wetlands (ICW), sustainable flood retention basins (SFRB), permeable pavement systems, decision support systems, ponds and capillary suction time. He has also conducted research about non-conventional water resources to address the increased demand in clean fresh water.[2]

Scholz's SFRB concept assesses the multi-functionality of all large water bodies with particular reference to their flood and diffuse pollution control potential. The SFRB concept addresses the need to assess the flood control potential of all European water bodies as part of new legislation. He has presented an unbiased classification system, which allows all stakeholders to clearly define the purpose of a water body that can be classed as an SFRB.[8]

Scholz contributed to the design guidelines of wetland systems as a research consultant. These guidelines assist managers in all aspects of ICW planning, design, construction, maintenance and management.[9] His research has led to the incorporation of findings into national and international guidelines on wetland and sustainable drainage systems.[10]

Scholz has conducted research about non-conventional water resources to address the increased demand in clean fresh water. Wastewater is considered an alternative option to overcome the shortage in water supply resulting particularly from population growth. He has identified the application of treated wastewater for agricultural irrigation as having much potential, especially when incorporating the reuse of nutrients like nitrogen and phosphorus, which are essential for plant production.[11]

Among the current treatment technologies applied in urban wastewater reuse for irrigation, Scholz found wetlands to be the one of the most suitable ones in terms of pollutant removal and have advantages due to both low maintenance costs and required energy. His research highlighted that specific wastewater characteristics decide upon the wetland design to be used for treatment.[12] Wetland behavior and efficiency concerning wastewater treatment is mainly linked to macrophyte composition, substrate, hydrology, surface loading rate, influent feeding mode, microorganism availability and temperature.[13] Scholz's research implicated that constructed wetlands are effective in removing organics and suspended solids, whereas the removal of nitrogen is relatively low, but could be improved by using a combination of various types of constructed wetlands.

Bibliography

Books

  • Wetland Systems to Control Urban Runoff (2006)[12]
  • Wetland Systems: Storm Water Management Control (2010)[14]
  • Water Resources and Environment (2015)
  • Sustainable Water Treatment: Engineering Solutions for a Variable Climate (2018)[15]

Selected Articles

  • Carty A., Scholz M., Heal K., Gouriveau F. and Mustafa A. (2008), The Universal Design, Operation and Maintenance Guidelines for Farm Constructed Wetlands (FCW) in Temperate Climates. Bioresource Technology, 99 (15), 6780–6792.
  • Kayranli B., Scholz M., Mustafa A. and Hedmark Å. (2010), Carbon Storage and Fluxes Within Freshwater Wetlands: a Critical Review. Wetlands, 30 (1), 111–124.
  • Lee B.-H. and Scholz M. (2006), Application of the Self-organizing Map (SOM) to assess the Heavy Metal Removal Performance in Experimental Constructed Wetlands. Water Research, 40 (18), 3367–3374.
  • Lee B.-H. and Scholz M. (2007), What is the Role of Phragmites australis in Experimental Constructed Wetland Filters Treating Urban Runoff? Ecological Engineering, 29 (1), 87–95.
  • Meyer D., Chazarenc F., Claveau-Mallet D., Dittmer U., Forquet N., Molle P., Morvannou A., Pálfy T., Petitjean A., Rizzo A., Samsó Campà R., Scholz M., Soric A. and Langergraber G. (2015), Modelling Constructed Wetlands: Scopes and Aims – A Comparative Review. Ecological Engineering, 80, 205-213.
  • Scholz M. (2005), Review of Recent Trends in Capillary Suction Time (CST) Dewaterability Testing Research. Industrial & Engineering Chemistry Research, 44 (22), 8157-8163
  • Scholz M. and Grabowiecki P. (2007), Review of Permeable Pavement Systems. Building and Environment, 42 (11), 3830-3836.
  • Scholz M. and Xu J. (2002), Performance Comparison of Experimental Constructed Wetlands with Different Filter Media and Macrophytes Treating Industrial Wastewater Contaminated with Lead and Copper. Bioresource Technology, 83 (2), 71–79.
  • Scholz M., Harrington R., Carroll P. and Mustafa A. (2007), The Integrated Constructed Wetlands (ICW) Concept. Wetlands, 27 (2), 337-354.
  • Tang X., Huang S., Scholz M. and Li J. (2009) Nutrient Removal in Pilot-scale Constructed Wetlands Treating Eutrophic River Water: Assessment of Plants, Intermittent Artificial Aeration and Polyhedron Hollow Polypropylene Balls. Water, Air and Soil Pollution, 197 (1-4), 61-73.
  • Tang X., Li Q., Wu M., Lin L. and Scholz M. (2016), Review of Remediation Practices Regarding Cadmium-enriched Farmland Soil with Particular Reference to China. Journal of Environmental Management. 181, 646-662.
  • Tota-Maharaj K. and Scholz M. (2010), Efficiency of Permeable Pavement Systems for the Removal of Urban Runoff Pollutants under Varying Environmental Conditions. Environmental Progress & Sustainable Energy, 29 (3), 358–369.
  • Yaseen D. A. and Scholz M. (2019), Textile Dye Wastewater Characteristics and Constituents of Synthetic Effluents: a Critical Review. International Journal of Environmental Science and Technology. 16(2), 1193–1226.

References

This article is issued from Wikipedia. The text is licensed under Creative Commons - Attribution - Sharealike. Additional terms may apply for the media files.