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SV0062

Broadleaves - History, Ecology and Management

Ädellövskog - historia, ekologi och skötsel

How have temperate broadleaf forests in northern and central Europe developed, and how can we manage them sustainably for the future? This course offers a comprehensive understanding of these ecosystems, focusing on forest history, ecology, biodiversity, and modern management strategies.


You will explore forest dynamics such as disturbances, succession, and the impacts of human activities and climate change. The course covers the role of forestry in biodiversity conservation, habitat restoration, and the transition from conifer to broadleaf forests. Through lectures, field trips, and practical assignments, you’ll analyze current challenges in forest management, climate adaptation, and societal influences.


Ideal for those seeking to understand the complex processes shaping broadleaf forests—past, present, and future.


Course evaluation

Additional course evaluations for SV0062

Academic year 2024/2025

Broadleaves - History, Ecology and Management (SV0062-40161)

2025-03-25 - 2025-06-08

Syllabus and other information


Syllabus

SV0062 Broadleaves - History, Ecology and Management, 15.0 Credits

Ädellövskog - historia, ekologi och skötsel

Subjects

Forestry Science Biology

Education cycle

Master’s level

Modules

Title Credits Code
Single module 15.0 0010

Advanced study in the main field

Second cycle, has only first-cycle course/s as entry requirements
Master’s level (A1N)

Grading scale

5:Pass with Distinction, 4:Pass with Credit, 3:Pass, U:Fail
The grade requirements within the course grading system are set out in specific criteria. These criteria must be available by the course start at the latest.

Language

English

Prior knowledge

The equivalent of

120 credits

60 credits within one of the following subjects/main fields of study

- forestry science
- forest science
- forest management
- biology
- environmental sciences
- natural resource management

English 6.

Objectives

The overall goal of the course is to provide a comprehensive account on the history, ecology, biodiversity, and sustainable governance of temperate broadleaf forest ecosystems in northern and central Europe.

Upon successful completion of the course, students will be able to

  • describe the main dynamic processes influencing temperate broadleaf forests, including natural and management-related disturbances and secondary succession, as well as long-term vegetation history
  • describe the main environmental and compositional characteristics of the major temperate broadleaf forest types
  • identify and discuss the most important challenges with regard to biodiversity conservation and sustainable management in broadleaf forests and describe strategies to address them
  • explain principles of past- and current sustainable silvicutural systems in broadleaf forests
  • explain principles of forest and habitat restoration in managed and protected broadleaf forests
  • summarize, critically evaluate and present scientific studies concerning ecology and dynamics of broadleaf forests both in oral and written form 
  • critically and systematically analyse and discuss complex problems of forest governance
  • write a reflective journal.

Content

During this course, the ecology of temperate broadleaf forests is studied with a focus on forest history, disturbance dynamics, forest succession and vegetation ecology. The study region comprises southern Sweden, Denmark, the Baltic countries, northern Germany and northern Poland.

Patterns of biodiversity are examined for the major species groups in broadleaf forests. The impact of forest management on biodiversity and current approaches to conservation and management for multiple goals are evaluated. Specifically, management alternatives based on historical conservation baselines are compared, including implications of Pleistocene megafauna extinctions. Current threats and challenges to the function and biodiversity of broadleaf forests are studied, with a focus on exotic tree pathogens and effects of ungulate browsing.

The course addresses various aspects of past- and current management models in broadleaf forests for production goals, including management of fast-growing tree species. Traditional silvicultural systems, such as beech shelterwood management, are compared with single tree and group selection approaches. Current concepts of forest management and restoration are evaluated with an emphasis on adaptation to ongoing climate change and on stand conversion from spruce to broadleaf forest. During field trips, reserve management and active habitat restoration are studied.

Throughout the course, the challenges that sustainable governance of broadleaf forest ecosystems meets today with respect to current changes in climate and society are discussed.

The course is divided into several parts where each part typically consists of:

  • introductory lectures
  • an individual or group assignment
  • field excursions
  • a seminar or exercise to discuss and present the assignments.

To further student learning and promote discussion, a variety of methods are used:
Lectures, literature studies, exercises, written exercises, (written) assignments, laboratory sessions, project work, seminars, study visits, study trips, field exercises, excursions, proficiency training, presentations

The course focuses on the following generic competencies:
Information competence, critical thinking and reflection, problem solving, scientific methods, use of technology, oral and written communication, teamwork.

The following course components are compulsory:
The study trip, excursions, individual and group assignments as well as exercises and seminars.

Grading form

The grade requirements within the course grading system are set out in specific criteria. These criteria must be available by the course start at the latest.

Formats and requirements for examination

Passed written examinations.

Approved written exercises.

Completed compulsory components

  • If a student has failed an examination, the examiner has the right to issue supplementary assignments. This applies if it is possible and there are grounds to do so.

  • The examiner can provide an adapted assessment to students entitled to study support for students with disabilities following a decision by the university. Examiners may also issue an adapted examination or provide an alternative way for the students to take the exam.

  • If this syllabus is withdrawn, SLU may introduce transitional provisions for examining students admitted based on this syllabus and who have not yet passed the course.

  • For the assessment of an independent project (degree project), the examiner may also allow a student to add supplemental information after the deadline for submission. Read more in the Education Planning and Administration Handbook.

Other information

  • The right to participate in teaching and/or supervision only applies for the course instance the student was admitted to and registered on.

  • If there are special reasons, students are entitled to participate in components with compulsory attendance when the course is given again. Read more in the Education Planning and Administration Handbook.

Additional information

The course includes a study trip to Bialowieza Primeval Forest in Poland. Travel to and from Warsaw is paid by the students while the other costs are covered by the department: bus to Bialowieza, hotel accommodation and meals.

Responsible department

Department of Southern Swedish Forest Research Centre

Further information

Determined by: Programnämnden för utbildning inom skog
Biology field: Ecology
Forestry science subcategory: Natural processes 15 credits
Replaces: SG0263

Litterature list

Broadleaves - history, ecology and management

Course literature - Spring 2025 - SV0062

Forest history, forest dynamics and biodiversity (module 1, part 1)

  • Brunet et al. 2010. Biodiversity in European beech forests – a review with recommendations for sustainable forest management. Ecological Bulletins 53: 77-94.
  • Larsen et al. 2005. Ecology of tree species and species selection. In: Naturnaer skovdrift (edited by Larsen, J.B.)
  •  Kirby and Watkins (Eds.). 2015. Europe’s changing woods and forests: from wildwood to managed landscapes. CAB International. 393 pp. Chapters 1-4.

Forest history, forest dynamics and biodiversity (module 1, part 2)

  • Bond 2005. Large parts of the world are brown or black: a different view on the ‘Green World’ hypothesis. Journal of Vegetation Science 16: 261–266.
  • Brunet et al. 2010. Biodiversity in European beech forests – a review with recommendations for sustainable forest management. Ecological Bulletins 53: 77-94.
  • Hedin, J., & Ranius, T. (2002). Using radio telemetry to study dispersal of the beetle Osmoderma eremita, an inhabitant of tree hollows. Computers and electronics in Agriculture35(2-3), 171-180.
  • Jansson, N., Ranius, T., Larsson, A., & Milberg, P. (2009). Boxes mimicking tree hollows can help conservation of saproxylic beetles. Biodiversity and Conservation18(14), 3891-3908.
  • Jonsell, M., Weslien, J., & Ehnström, B. (1998). Substrate requirements of red-listed saproxylic invertebrates in Sweden. Biodiversity & Conservation7(6), 749-764.
  • Kirby and Watkins (Eds.). 2015. Europe’s changing woods and forests: from wildwood to managed landscapes. CAB International. 393 pp. Chapters 1-4.
  • Larrieu et al. 2018. Tree related microhabitats in temperate and Mediterranean European forests: A hierarchical typology for inventory standardization. Ecological Indicators 84: 194-207.
  • Larsson, M. C. (2016). Pheromones and other semiochemicals for monitoring rare and endangered species. Journal of Chemical Ecology42(9), 853-868.
  • Larsen et al. 2005. Ecology of tree species and species selection. In: Naturnaer skovdrift (edited by Larsen, J.B.)
  • Mölder et al. 2019. Integrative management to sustain biodiversity and ecological continuity in Central European temperate oak (Quercus robur, Q. petraea) forests: An overview. Forest Ecology and Management 437: 324–339
  • Nilsson, S.G. 1997 Forests in the temperate-boreal transition: natural and man-made features Ecological Bulletins 46:61-71
  • Ranius, T., Niklasson, M., & Berg, N. (2009). Development of tree hollows in pedunculate oak (Quercus robur). Forest Ecology and management257(1), 303-310.
  • White, P. S., & Walker, J. L. (1997). Approximating nature's variation: selecting and using reference information in restoration ecology. Restoration ecology5(4), 338-349.

Forest health (module 2)

  • Hartmann H, Bastos A, Das AJ, Esquivel-Muelbert A, Hammond WM, Martínez-Vilalta J, McDowell NG, Powers JS, Pugh TA, Ruthrof KX, Allen CD. 2022. Climate change risks to global forest health: emergence of unexpected events of elevated tree mortality worldwide. Annual review of plant biology 73: 673-702. 
  • Fernandex-Conradi et al. 2021. Combining phytochemicals and multitrophic interactions to
    control forest insect pests. ScienceDirect 44: 101–106
  • Prospero and Cleary. 2017. Effects of host variability on the spread of invasive forest diseases.
    Forests 8: 80.
  • Roberts et al. 2020. The effect of forest management options on forest resilience to pathogens.
    Frontiers in Forests and Global Change 3: 7.
  • Moreau G, Chagnon C, Achim A, Caspersen J, D’Orangeville L, Sánchez-Pinillos M, Thiffault N. 2022. Opportunities and limitations of thinning to increase resistance and resilience of trees and forests to global change. Forestry 95: 595-615. 

Ungulate ecology (module 3)

  • Felton, A. M., H. K. Wam, Z. Borowski, G. Granhus, L. Juvany, J. Matala, M. Melin, M. Wallgren, and A. Mårell. 2024. Climate change and deer in boreal and temperate regions: from physiology to population dynamics and species distributions. Global Change Biology 30.

  • Faison et al. 2016. Ungulate browsers promote herbaceous layer diversity in logged temperate forests. Ecology and Evolution 6: 4591-4602.

  • Kolstad et al. 2018. Pervasive moose browsing in boreal forests alters successional trajectories by severely suppressing keystone species. Ecosphere 9: e02458.

  • Felton et al. 2020. Varied diets, including broadleaved forage, are important for a large herbivore species inhabiting highly modified landscapes. Scientific Reports 10: 1-13.

Bialowieza forest (module 4)

  • Churski et al. 2017. Brown world forests: increased ungulate browsing keeps temperate trees in
    recruitment bottlenecks in resource hotspots. New Phytologist 214: 158-168.
  • Hofman-Kaminska et al. 2019. Adapt or die—Response of large herbivores to environmental
    changes in Europe during the Holocene. Global Change Biology 25: 2915–2930.
  • Kuijper et al. 2013. Landscape of fear in Europe: wolves affect spatial patterns of ungulate
    browsing in Bialowieza Primeval Forest, Poland. Ecography 36: 1263-1275.
  • Nowacki and Abrams. 2008. The Demise of Fire and “Mesophication” of Forests in the Eastern
    United States. BioScience 58: 123-138.
  • Mikusiński et al. 2018. Is the impact of loggings in the last primeval lowland forest in Europe
    underestimated? The conservation issues of Białowieża Forest. Biological Conservation 227:
    266-274.
  • Spînu et al. 2020. Mesophication in temperate Europe. A dendrochronological reconstruction
    of tree succession and fires in a mixed deciduous stand in Bialowieza forest. Ecology and
    Evolution 10, 1029-1041.

Fast-growing broadleaves (module 5)

  • Svystun, Tetiana & Fahlvik, Nils & Böhlenius, Henrik. (2025). Thinning effects on stand and dominant trees development in a second rotation hybrid poplar plantation. European Journal of Forest Research. 144. 1671-1685.

  • Muraro, Luca & Adler, Anneli & Böhlenius, Henrik. (2025). Effect of Wood Ash, Lime, and Biochar on the Establishment and Early Growth of Poplars on Acidic Soil Conditions. BioEnergy Research. 18.

  • Tetiana Svystun· Henrik Böhlenius (2024) Biomass Production of the Poplar Clone OP42 During the Second Rotation Plantation–The Effects of Four Thinning Treatments. Bioenergy research

  • Bohlenius, Henrik; Ohman, Marcus; Granberg, Fredrik Persson Per-Ove (2022) Biomass production and fuel characteristics from long rotation poplar plantations. Biomass and Energy

  • Böhlenius H, Salk C, Nilsson U. Liming increases early growth of poplars on forest sites with low soil pH. Biomass and energy. 138, 2020.


Forest management and restoration (module 6)

  • Cernansky 2018. How to rebuild a forest. Nature 560: 542-544.
  • Gamfeldt et al. 2013. Higher levels of multiple ecosystem services are found in forests with more
    tree species. Nature Communications 4: 1340.
  • Kelty 2006. The role of species mixtures in plantation forestry. Forest Ecology and Management
    233: 195-204.
  • Kirby and Watkins (Eds.). 2015. Europe’s changing woods and forests: from wildwood to
    managed landscapes. CAB International. 393 pp. Chapters 5-8.
  • Löf et al. 2016. Management of oak forests: striking a balance between timber production,
    biodiversity and cultural services. International Journal of Biodiversity Science, Ecosystem
    Services and Management 12: 59-73.
  • Popkin 2021. Forest fight. Science 374: 1184-1189.
  • Stanturf et al. 2014. Contemporary forest restoration: a review emphasizing function. Forest
    Ecology and Management 331: 292-323.
  • Vollmuth 2022. The changing perception of coppice with standards in German forestry literature
    up to the present day – From a universal solution to a defamed and overcome evil – and back?
    Trees, Forests and People 10: 100338.

Course facts

The course is offered as an independent course: Yes The course is offered as a programme course: Euroforester (MSc) Forest Science - Master's Programme Tuition fee: Tuition fee only for non-EU/EEA/Switzerland citizens: 45010 SEK Cycle: Master’s level (A1N)
Subject: Forestry Science Biology
Course code: SV0062 Application code: SLU-40024 Location: Alnarp Distance course: No Language: English Responsible department: Department of Southern Swedish Forest Research Centre Pace: 100%