Your search keyword '"Björkman C"' showing total 37 results

1. Experimental and Theoretical Study of Stable and Metastable Phases in Sputtered CuInS2

Author

Larsen, J. K., Sopiha, K. V., Persson, Clas, Platzer-Björkman, C., Edoff, M., Larsen, J. K., Sopiha, K. V., Persson, Clas, Platzer-Björkman, C., and Edoff, M.

Abstract

The chalcopyrite Cu(In,Ga)S2 has gained renewed interest in recent years due to the potential application in tandem solar cells. In this contribution, a combined theoretical and experimental approach is applied to investigate stable and metastable phases forming in CuInS2 (CIS) thin films. Ab initio calculations are performed to obtain formation energies, X-ray diffraction (XRD) patterns, and Raman spectra of CIS polytypes and related compounds. Multiple CIS structures with zinc-blende and wurtzite-derived lattices are identified and their XRD/Raman patterns are shown to contain overlapping features, which could lead to misidentification. Thin films with compositions from Cu-rich to Cu-poor are synthesized via a two-step approach based on sputtering from binary targets followed by high-temperature sulfurization. It is discovered that several CIS polymorphs are formed when growing the material with this approach. In the Cu-poor material, wurtzite CIS is observed for the first time in sputtered thin films along with chalcopyrite CIS and CuAu-ordered CIS. Once the wurtzite CIS phase has formed, it is difficult to convert into the stable chalcopyrite polymorph. CuIn5S8 and NaInS2 accommodating In-excess are found alongside the CIS polymorphs. It is argued that the metastable polymorphs are stabilized by off-stoichiometry of the precursors, hence tight composition control is required., QC 20230327

Published

2022

2. Healthy ecosystems for human and animal health : Science diplomacy for responsible development in the Arctic

Author

Evengård, Birgitta, Destouni, G., Kalantari, Z., Albihn, A., Björkman, C., Bylund, H., Jenkins, E., Koch, A., Kukarenko, N., Leibovici, D., Lemmityinen, J., Menshakova, M., Mulvad, G., Nilsson, Lena Maria, Omazic, A., Pshenichnaya, N., Quegan, S., Rautio, A., Revich, B., Rydén, Patrik, Sjöstedt, Anders, Tokarevich, N., Thierfelder, T., Orlov, D., Evengård, Birgitta, Destouni, G., Kalantari, Z., Albihn, A., Björkman, C., Bylund, H., Jenkins, E., Koch, A., Kukarenko, N., Leibovici, D., Lemmityinen, J., Menshakova, M., Mulvad, G., Nilsson, Lena Maria, Omazic, A., Pshenichnaya, N., Quegan, S., Rautio, A., Revich, B., Rydén, Patrik, Sjöstedt, Anders, Tokarevich, N., Thierfelder, T., and Orlov, D.

Abstract

Climate warming is occurring most rapidly in the Arctic, which is both a sentinel and a driver of further global change. Ecosystems and human societies are already affected by warming. Permafrost thaws and species are on the move, bringing pathogens and vectors to virgin areas. During a five-year project, the CLINF - a Nordic Center of Excellence, funded by the Nordic Council of Ministers, has worked with the One Health concept, integrating environmental data with human and animal disease data in predictive models and creating maps of dynamic processes affecting the spread of infectious diseases. It is shown that tularemia outbreaks can be predicted even at a regional level with a manageable level of uncertainty. To decrease uncertainty, rapid development of new and harmonised technologies and databases is needed from currently highly heterogeneous data sources. A major source of uncertainty for the future of contaminants and infectious diseases in the Arctic, however, is associated with which paths the majority of the globe chooses to follow in the future. Diplomacy is one of the most powerful tools Arctic nations have to influence these choices of other nations, supported by Arctic science and One Health approaches that recognise the interconnection between people, animals, plants and their shared environment at the local, regional, national and global levels as essential for achieving a sustainable development for both the Arctic and the globe.

Published

2021

3. Healthy ecosystems for human and animal health : Science diplomacy for responsible development in the Arctic

Author

Evengård, Birgitta, Destouni, G., Kalantari, Z., Albihn, A., Björkman, C., Bylund, H., Jenkins, E., Koch, A., Kukarenko, N., Leibovici, D., Lemmityinen, J., Menshakova, M., Mulvad, G., Nilsson, Lena Maria, Omazic, A., Pshenichnaya, N., Quegan, S., Rautio, A., Revich, B., Rydén, Patrik, Sjöstedt, Anders, Tokarevich, N., Thierfelder, T., Orlov, D., Evengård, Birgitta, Destouni, G., Kalantari, Z., Albihn, A., Björkman, C., Bylund, H., Jenkins, E., Koch, A., Kukarenko, N., Leibovici, D., Lemmityinen, J., Menshakova, M., Mulvad, G., Nilsson, Lena Maria, Omazic, A., Pshenichnaya, N., Quegan, S., Rautio, A., Revich, B., Rydén, Patrik, Sjöstedt, Anders, Tokarevich, N., Thierfelder, T., and Orlov, D.

Abstract

Climate warming is occurring most rapidly in the Arctic, which is both a sentinel and a driver of further global change. Ecosystems and human societies are already affected by warming. Permafrost thaws and species are on the move, bringing pathogens and vectors to virgin areas. During a five-year project, the CLINF - a Nordic Center of Excellence, funded by the Nordic Council of Ministers, has worked with the One Health concept, integrating environmental data with human and animal disease data in predictive models and creating maps of dynamic processes affecting the spread of infectious diseases. It is shown that tularemia outbreaks can be predicted even at a regional level with a manageable level of uncertainty. To decrease uncertainty, rapid development of new and harmonised technologies and databases is needed from currently highly heterogeneous data sources. A major source of uncertainty for the future of contaminants and infectious diseases in the Arctic, however, is associated with which paths the majority of the globe chooses to follow in the future. Diplomacy is one of the most powerful tools Arctic nations have to influence these choices of other nations, supported by Arctic science and One Health approaches that recognise the interconnection between people, animals, plants and their shared environment at the local, regional, national and global levels as essential for achieving a sustainable development for both the Arctic and the globe.

Published

2021

4. Healthy ecosystems for human and animal health : Science diplomacy for responsible development in the Arctic

Author

Evengård, Birgitta, Destouni, G., Kalantari, Z., Albihn, A., Björkman, C., Bylund, H., Jenkins, E., Koch, A., Kukarenko, N., Leibovici, D., Lemmityinen, J., Menshakova, M., Mulvad, G., Nilsson, Lena Maria, Omazic, A., Pshenichnaya, N., Quegan, S., Rautio, A., Revich, B., Rydén, Patrik, Sjöstedt, Anders, Tokarevich, N., Thierfelder, T., Orlov, D., Evengård, Birgitta, Destouni, G., Kalantari, Z., Albihn, A., Björkman, C., Bylund, H., Jenkins, E., Koch, A., Kukarenko, N., Leibovici, D., Lemmityinen, J., Menshakova, M., Mulvad, G., Nilsson, Lena Maria, Omazic, A., Pshenichnaya, N., Quegan, S., Rautio, A., Revich, B., Rydén, Patrik, Sjöstedt, Anders, Tokarevich, N., Thierfelder, T., and Orlov, D.

Abstract

Climate warming is occurring most rapidly in the Arctic, which is both a sentinel and a driver of further global change. Ecosystems and human societies are already affected by warming. Permafrost thaws and species are on the move, bringing pathogens and vectors to virgin areas. During a five-year project, the CLINF - a Nordic Center of Excellence, funded by the Nordic Council of Ministers, has worked with the One Health concept, integrating environmental data with human and animal disease data in predictive models and creating maps of dynamic processes affecting the spread of infectious diseases. It is shown that tularemia outbreaks can be predicted even at a regional level with a manageable level of uncertainty. To decrease uncertainty, rapid development of new and harmonised technologies and databases is needed from currently highly heterogeneous data sources. A major source of uncertainty for the future of contaminants and infectious diseases in the Arctic, however, is associated with which paths the majority of the globe chooses to follow in the future. Diplomacy is one of the most powerful tools Arctic nations have to influence these choices of other nations, supported by Arctic science and One Health approaches that recognise the interconnection between people, animals, plants and their shared environment at the local, regional, national and global levels as essential for achieving a sustainable development for both the Arctic and the globe.

Published

2021

5. Healthy ecosystems for human and animal health : Science diplomacy for responsible development in the Arctic. The Nordic Centre of Excellence, Clinf.org (Climate-change effects on the epidemiology of infectious diseases and the impacts on Northern societies)

Author

Evengård, B., Destouni, Georgia, Kalantari, Zahra, Albihn, A., Björkman, C., Bylund, H., Jenkins, E., Koch, A., Kukarenko, N., Leibovici, D., Lemmityinen, J., Menshakova, M., Mulvad, G., Nilsson, L. M., Omazic, A., Pshenichnaya, N., Quegan, S., Rautio, A., Revich, B., Rydén, P., Sjöstedt, A., Tokarevich, N., Thierfelder, T., Orlov, D., Evengård, B., Destouni, Georgia, Kalantari, Zahra, Albihn, A., Björkman, C., Bylund, H., Jenkins, E., Koch, A., Kukarenko, N., Leibovici, D., Lemmityinen, J., Menshakova, M., Mulvad, G., Nilsson, L. M., Omazic, A., Pshenichnaya, N., Quegan, S., Rautio, A., Revich, B., Rydén, P., Sjöstedt, A., Tokarevich, N., Thierfelder, T., and Orlov, D.

Abstract

Climate warming is occurring most rapidly in the Arctic, which is both a sentinel and a driver of further global change. Ecosystems and human societies are already affected by warming. Permafrost thaws and species are on the move, bringing pathogens and vectors to virgin areas. During a five-year project, the CLINF – a Nordic Center of Excellence, funded by the Nordic Council of Ministers, has worked with the One Health concept, integrating environmental data with human and animal disease data in predictive models and creating maps of dynamic processes affecting the spread of infectious diseases. It is shown that tularemia outbreaks can be predicted even at a regional level with a manageable level of uncertainty. To decrease uncertainty, rapid development of new and harmonised technologies and databases is needed from currently highly heterogeneous data sources. A major source of uncertainty for the future of contaminants and infectious diseases in the Arctic, however, is associated with which paths the majority of the globe chooses to follow in the future. Diplomacy is one of the most powerful tools Arctic nations have to influence these choices of other nations, supported by Arctic science and One Health approaches that recognise the interconnection between people, animals, plants and their shared environment at the local, regional, national and global levels as essential for achieving a sustainable development for both the Arctic and the globe.

Published

2021

6. Healthy ecosystems for human and animal health:science diplomacy for responsible development in the Arctic

Author

Evengård, B. (B.), Destouni, G. (G.), Kalantari, Z. (Z.), Albihn, A. (A.), Björkman, C. (C.), Bylund, H. (H.), Jenkins, E. (E.), Koch, A. (A.), Kukarenko, N. (N.), Leibovici, D. (D.), Lemmityinen, J. (J.), Menshakova, M. (M.), Mulvad, G. (G.), Nilsson, L. M. (L. M.), Omazic, A. (A.), Pshenichnaya, N. (N.), Quegan, S. (S.), Rautio, A. (A.), Revich, B. (B.), Rydén, P. (P.), Sjöstedt, A. (A.), Tokarevich, N. (N.), Thierfelder, T. (T.), Orlov, D. (D.), Evengård, B. (B.), Destouni, G. (G.), Kalantari, Z. (Z.), Albihn, A. (A.), Björkman, C. (C.), Bylund, H. (H.), Jenkins, E. (E.), Koch, A. (A.), Kukarenko, N. (N.), Leibovici, D. (D.), Lemmityinen, J. (J.), Menshakova, M. (M.), Mulvad, G. (G.), Nilsson, L. M. (L. M.), Omazic, A. (A.), Pshenichnaya, N. (N.), Quegan, S. (S.), Rautio, A. (A.), Revich, B. (B.), Rydén, P. (P.), Sjöstedt, A. (A.), Tokarevich, N. (N.), Thierfelder, T. (T.), and Orlov, D. (D.)

Abstract

Climate warming is occurring most rapidly in the Arctic, which is both a sentinel and a driver of further global change. Ecosystems and human societies are already affected by warming. Permafrost thaws and species are on the move, bringing pathogens and vectors to virgin areas. During a five-year project, the CLINF — a Nordic Center of Excellence, funded by the Nordic Council of Ministers, has worked with the One Health concept, integrating environmental data with human and animal disease data in predictive models and creating maps of dynamic processes affecting the spread of infectious diseases. It is shown that tularemia outbreaks can be predicted even at a regional level with a manageable level of uncertainty. To decrease uncertainty, rapid development of new and harmonised technologies and databases is needed from currently highly heterogeneous data sources. A major source of uncertainty for the future of contaminants and infectious diseases in the Arctic, however, is associated with which paths the majority of the globe chooses to follow in the future. Diplomacy is one of the most powerful tools Arctic nations have to influence these choices of other nations, supported by Arctic science and One Health approaches that recognise the interconnection between people, animals, plants and their shared environment at the local, regional, national and global levels as essential for achieving a sustainable development for both the Arctic and the globe.

Published

2021

7. Healthy ecosystems for human and animal health : Science diplomacy for responsible development in the Arctic

Author

Evengård, Birgitta, Destouni, G., Kalantari, Z., Albihn, A., Björkman, C., Bylund, H., Jenkins, E., Koch, A., Kukarenko, N., Leibovici, D., Lemmityinen, J., Menshakova, M., Mulvad, G., Nilsson, Lena Maria, Omazic, A., Pshenichnaya, N., Quegan, S., Rautio, A., Revich, B., Rydén, Patrik, Sjöstedt, Anders, Tokarevich, N., Thierfelder, T., Orlov, D., Evengård, Birgitta, Destouni, G., Kalantari, Z., Albihn, A., Björkman, C., Bylund, H., Jenkins, E., Koch, A., Kukarenko, N., Leibovici, D., Lemmityinen, J., Menshakova, M., Mulvad, G., Nilsson, Lena Maria, Omazic, A., Pshenichnaya, N., Quegan, S., Rautio, A., Revich, B., Rydén, Patrik, Sjöstedt, Anders, Tokarevich, N., Thierfelder, T., and Orlov, D.

Abstract

Climate warming is occurring most rapidly in the Arctic, which is both a sentinel and a driver of further global change. Ecosystems and human societies are already affected by warming. Permafrost thaws and species are on the move, bringing pathogens and vectors to virgin areas. During a five-year project, the CLINF - a Nordic Center of Excellence, funded by the Nordic Council of Ministers, has worked with the One Health concept, integrating environmental data with human and animal disease data in predictive models and creating maps of dynamic processes affecting the spread of infectious diseases. It is shown that tularemia outbreaks can be predicted even at a regional level with a manageable level of uncertainty. To decrease uncertainty, rapid development of new and harmonised technologies and databases is needed from currently highly heterogeneous data sources. A major source of uncertainty for the future of contaminants and infectious diseases in the Arctic, however, is associated with which paths the majority of the globe chooses to follow in the future. Diplomacy is one of the most powerful tools Arctic nations have to influence these choices of other nations, supported by Arctic science and One Health approaches that recognise the interconnection between people, animals, plants and their shared environment at the local, regional, national and global levels as essential for achieving a sustainable development for both the Arctic and the globe.

Published

2021

8. Healthy ecosystems for human and animal health : Science diplomacy for responsible development in the Arctic

Author

Evengård, Birgitta, Destouni, G., Kalantari, Z., Albihn, A., Björkman, C., Bylund, H., Jenkins, E., Koch, A., Kukarenko, N., Leibovici, D., Lemmityinen, J., Menshakova, M., Mulvad, G., Nilsson, Lena Maria, Omazic, A., Pshenichnaya, N., Quegan, S., Rautio, A., Revich, B., Rydén, Patrik, Sjöstedt, Anders, Tokarevich, N., Thierfelder, T., Orlov, D., Evengård, Birgitta, Destouni, G., Kalantari, Z., Albihn, A., Björkman, C., Bylund, H., Jenkins, E., Koch, A., Kukarenko, N., Leibovici, D., Lemmityinen, J., Menshakova, M., Mulvad, G., Nilsson, Lena Maria, Omazic, A., Pshenichnaya, N., Quegan, S., Rautio, A., Revich, B., Rydén, Patrik, Sjöstedt, Anders, Tokarevich, N., Thierfelder, T., and Orlov, D.

Abstract

Climate warming is occurring most rapidly in the Arctic, which is both a sentinel and a driver of further global change. Ecosystems and human societies are already affected by warming. Permafrost thaws and species are on the move, bringing pathogens and vectors to virgin areas. During a five-year project, the CLINF - a Nordic Center of Excellence, funded by the Nordic Council of Ministers, has worked with the One Health concept, integrating environmental data with human and animal disease data in predictive models and creating maps of dynamic processes affecting the spread of infectious diseases. It is shown that tularemia outbreaks can be predicted even at a regional level with a manageable level of uncertainty. To decrease uncertainty, rapid development of new and harmonised technologies and databases is needed from currently highly heterogeneous data sources. A major source of uncertainty for the future of contaminants and infectious diseases in the Arctic, however, is associated with which paths the majority of the globe chooses to follow in the future. Diplomacy is one of the most powerful tools Arctic nations have to influence these choices of other nations, supported by Arctic science and One Health approaches that recognise the interconnection between people, animals, plants and their shared environment at the local, regional, national and global levels as essential for achieving a sustainable development for both the Arctic and the globe.

Published

2021

9. Dynamic Impurity Redistributions in Kesterite Absorbers

Author

Grini, S., Aboulfadl, H., Ross, N., Persson, Clas, Platzer-Björkman, C., Thuvander, M., Vines, L., Grini, S., Aboulfadl, H., Ross, N., Persson, Clas, Platzer-Björkman, C., Thuvander, M., and Vines, L.

Abstract

Cu2ZnSn(S,Se)4 is a promising nontoxic earth-abundant solar cell absorber. To optimize the thin films for solar cell device performance, postdeposition treatments at temperatures below the crystallization temperature are normally performed, which alter the surface and bulk properties. The polycrystalline thin films contain relatively high concentrations of impurities, such as sodium, oxygen and hydrogen. During the treatments, these impurities migrate and likely agglomerate at lattice defects or interfaces. Herein, impurity redistribution after air annealing for temperatures up to 200 °C and short heavy water treatments are studied. In addition, nonuniformities of the sodium distribution on a nanometer and micrometer scale are characterized by atom probe tomography and secondary ion mass spectrometry, respectively. Sodium and oxygen correlate to a greater extent after heat treatments, supporting strong binding between the two impurities. Redistributions of these impurities occur even at room temperature over longer time periods. Heavy water treatments confirm out-diffusion of sodium with more incorporation of oxygen and hydrogen. It is observed that the increased hydrogen content does not originate from the heavy water. The existence of an “ice-like” layer on top of the Cu2ZnSnS4 layer is proposed., QC 20200629

Published

2020

10. Extreme radiation hard thin film CZTSSe solar cell

Author

Suvanam, S. S., Larsen, J., Ross, N., Kosyak, V., Hallén, Anders, Björkman, C. P., Suvanam, S. S., Larsen, J., Ross, N., Kosyak, V., Hallén, Anders, and Björkman, C. P.

Abstract

In this work, we have demonstrated the extreme radiation hardness of thin film CZTSSe solar cells. Thin film solar cells with CZTSSe, CZTS and CIGS absorber layers were irradiated with 3 MeV protons. No degradation in device parameters was observed until a displacement damage dose of 2 × 1010 MeV/g for CZTS and CZTSSe. CIGS solar cells degraded by 13% at the same dose. For the highest proton dose both the CZTSSe and CZTS degraded by 16% while CIGS suffered from 34% degradation in efficiency. The degradation in efficiency maybe attributed to the reduction in the minority carrier lifetime due to radiation induced lattice defects. Comparisons with previously available literature show that our CZTS technology has superior radiation hardness by about two orders of magnitude compared to existing state of the art Si and GaAs technology., QC 20180530

Published

2018

11. Capturing complexity : Forests, decision-making and climate change mitigation action

Author

Klapwijk, M. J., Boberg, J., Bergh, J., Bishop, K., Björkman, C., Ellison, D., Felton, A., Lidskog, R., Lundmark, T., Keskitalo, E. Carina H., Sonesson, J., Nordin, A., Nordström, E.-M., Stenlid, J., Mårald, Erland, Klapwijk, M. J., Boberg, J., Bergh, J., Bishop, K., Björkman, C., Ellison, D., Felton, A., Lidskog, R., Lundmark, T., Keskitalo, E. Carina H., Sonesson, J., Nordin, A., Nordström, E.-M., Stenlid, J., and Mårald, Erland

Abstract

Managed forests can play an important role in climate change mitigation due to their capacity to sequester carbon. However, it has proven difficult to harness their full potential for climate change mitigation. Managed forests are often referred to as socio-ecological systems as the human dimension is an integral part of the system. When attempting to change systems that are influenced by factors such as collective knowledge, social organization, understanding of the situation and values represented in society, initial intentions often shift due to the complexity of political, social and scientific interactions. Currently, the scientific literature is dispersed over the differentfactorsrelated tothe socio-ecological system. Toexamine thelevelofdispersion andtoobtainaholistic view, we review climate change mitigation in the context of Swedish forest research. We introduce a heuristic framework to understand decision-making connected to climate change mitigation. We apply our framework to two themes which span different dimensions in the socio-ecological system: carbon accounting and bioenergy. A key finding in the literature was the perception that current uncertainties regarding the reliability of different methods of carbon accounting inhibits international agreement on the use of forests for climate change mitigation. This feeds into a strategic obstacle affecting the willingness of individual countries to implement forestrelated carbon emission reduction policies. Decisions on the utilization of forests for bioenergy are impeded by a lack of knowledge regarding the resultant biophysical and social consequences. This interacts negatively with the development of institutional incentives regarding the production of bioenergy using forest products. Normative disagreement about acceptable forest use further affects these scientific discussions and therefore is an over-arching influence on decision-making. With our framework, we capture this complexity and make obstacles to decisio

Published

2018

12. Capturing complexity : Forests, decision-making and climate change mitigation action

Author

Klapwijk, M. J., Boberg, J., Bergh, J., Bishop, K., Björkman, C., Ellison, D., Felton, A., Lidskog, R., Lundmark, T., Keskitalo, E. Carina H., Sonesson, J., Nordin, A., Nordström, E.-M., Stenlid, J., Mårald, Erland, Klapwijk, M. J., Boberg, J., Bergh, J., Bishop, K., Björkman, C., Ellison, D., Felton, A., Lidskog, R., Lundmark, T., Keskitalo, E. Carina H., Sonesson, J., Nordin, A., Nordström, E.-M., Stenlid, J., and Mårald, Erland

Abstract

Managed forests can play an important role in climate change mitigation due to their capacity to sequester carbon. However, it has proven difficult to harness their full potential for climate change mitigation. Managed forests are often referred to as socio-ecological systems as the human dimension is an integral part of the system. When attempting to change systems that are influenced by factors such as collective knowledge, social organization, understanding of the situation and values represented in society, initial intentions often shift due to the complexity of political, social and scientific interactions. Currently, the scientific literature is dispersed over the differentfactorsrelated tothe socio-ecological system. Toexamine thelevelofdispersion andtoobtainaholistic view, we review climate change mitigation in the context of Swedish forest research. We introduce a heuristic framework to understand decision-making connected to climate change mitigation. We apply our framework to two themes which span different dimensions in the socio-ecological system: carbon accounting and bioenergy. A key finding in the literature was the perception that current uncertainties regarding the reliability of different methods of carbon accounting inhibits international agreement on the use of forests for climate change mitigation. This feeds into a strategic obstacle affecting the willingness of individual countries to implement forestrelated carbon emission reduction policies. Decisions on the utilization of forests for bioenergy are impeded by a lack of knowledge regarding the resultant biophysical and social consequences. This interacts negatively with the development of institutional incentives regarding the production of bioenergy using forest products. Normative disagreement about acceptable forest use further affects these scientific discussions and therefore is an over-arching influence on decision-making. With our framework, we capture this complexity and make obstacles to decisio

Published

2018

13. Capturing complexity : Forests, decision-making and climate change mitigation action

Author

Klapwijk, M. J., Boberg, J., Bergh, J., Bishop, K., Björkman, C., Ellison, D., Felton, A., Lidskog, R., Lundmark, T., Keskitalo, E. Carina H., Sonesson, J., Nordin, A., Nordström, E.-M., Stenlid, J., Mårald, Erland, Klapwijk, M. J., Boberg, J., Bergh, J., Bishop, K., Björkman, C., Ellison, D., Felton, A., Lidskog, R., Lundmark, T., Keskitalo, E. Carina H., Sonesson, J., Nordin, A., Nordström, E.-M., Stenlid, J., and Mårald, Erland

Abstract

Managed forests can play an important role in climate change mitigation due to their capacity to sequester carbon. However, it has proven difficult to harness their full potential for climate change mitigation. Managed forests are often referred to as socio-ecological systems as the human dimension is an integral part of the system. When attempting to change systems that are influenced by factors such as collective knowledge, social organization, understanding of the situation and values represented in society, initial intentions often shift due to the complexity of political, social and scientific interactions. Currently, the scientific literature is dispersed over the differentfactorsrelated tothe socio-ecological system. Toexamine thelevelofdispersion andtoobtainaholistic view, we review climate change mitigation in the context of Swedish forest research. We introduce a heuristic framework to understand decision-making connected to climate change mitigation. We apply our framework to two themes which span different dimensions in the socio-ecological system: carbon accounting and bioenergy. A key finding in the literature was the perception that current uncertainties regarding the reliability of different methods of carbon accounting inhibits international agreement on the use of forests for climate change mitigation. This feeds into a strategic obstacle affecting the willingness of individual countries to implement forestrelated carbon emission reduction policies. Decisions on the utilization of forests for bioenergy are impeded by a lack of knowledge regarding the resultant biophysical and social consequences. This interacts negatively with the development of institutional incentives regarding the production of bioenergy using forest products. Normative disagreement about acceptable forest use further affects these scientific discussions and therefore is an over-arching influence on decision-making. With our framework, we capture this complexity and make obstacles to decisio

Published

2018

14. Capturing complexity : Forests, decision-making and climate change mitigation action

Author

Klapwijk, M. J., Boberg, J., Bergh, J., Bishop, K., Björkman, C., Ellison, D., Felton, A., Lidskog, Rolf, Lundmark, T., Keskitalo, E. C. H., Sonesson, J., Nordin, A., Nordström, E. -M, Stenlid, J., Mårald, E., Klapwijk, M. J., Boberg, J., Bergh, J., Bishop, K., Björkman, C., Ellison, D., Felton, A., Lidskog, Rolf, Lundmark, T., Keskitalo, E. C. H., Sonesson, J., Nordin, A., Nordström, E. -M, Stenlid, J., and Mårald, E.

Abstract

Managed forests can play an important role in climate change mitigation due to their capacity to sequester carbon. However, it has proven difficult to harness their full potential for climate change mitigation. Managed forests are often referred to as socio-ecological systems as the human dimension is an integral part of the system. When attempting to change systems that are influenced by factors such as collective knowledge, social organization, understanding of the situation and values represented in society, initial intentions often shift due to the complexity of political, social and scientific interactions. Currently, the scientific literature is dispersed over the different factors related to the socio-ecological system. To examine the level of dispersion and to obtain a holistic view, we review climate change mitigation in the context of Swedish forest research. We introduce a heuristic framework to understand decision-making connected to climate change mitigation. We apply our framework to two themes which span different dimensions in the socio-ecological system: carbon accounting and bioenergy. A key finding in the literature was the perception that current uncertainties regarding the reliability of different methods of carbon accounting inhibits international agreement on the use of forests for climate change mitigation. This feeds into a strategic obstacle affecting the willingness of individual countries to implement forest-related carbon emission reduction policies. Decisions on the utilization of forests for bioenergy are impeded by a lack of knowledge regarding the resultant biophysical and social consequences. This interacts negatively with the development of institutional incentives regarding the production of bioenergy using forest products. Normative disagreement about acceptable forest use further affects these scientific discussions and therefore is an over-arching influence on decision-making. With our framework, we capture this complexity and, Funding Agencies:Swedish Forestry Industry Swedish University of Agricultural Sciences (SLU) Umeå University Forestry Research Institute of Sweden

Published

2018

15. Capturing complexity : Forests, decision-making and climate change mitigation action

Author

Klapwijk, M. J., Boberg, J., Bergh, J., Bishop, K., Björkman, C., Ellison, D., Felton, A., Lidskog, Rolf, Lundmark, T., Keskitalo, E. C. H., Sonesson, J., Nordin, A., Nordström, E. -M, Stenlid, J., Mårald, E., Klapwijk, M. J., Boberg, J., Bergh, J., Bishop, K., Björkman, C., Ellison, D., Felton, A., Lidskog, Rolf, Lundmark, T., Keskitalo, E. C. H., Sonesson, J., Nordin, A., Nordström, E. -M, Stenlid, J., and Mårald, E.

Abstract

Managed forests can play an important role in climate change mitigation due to their capacity to sequester carbon. However, it has proven difficult to harness their full potential for climate change mitigation. Managed forests are often referred to as socio-ecological systems as the human dimension is an integral part of the system. When attempting to change systems that are influenced by factors such as collective knowledge, social organization, understanding of the situation and values represented in society, initial intentions often shift due to the complexity of political, social and scientific interactions. Currently, the scientific literature is dispersed over the different factors related to the socio-ecological system. To examine the level of dispersion and to obtain a holistic view, we review climate change mitigation in the context of Swedish forest research. We introduce a heuristic framework to understand decision-making connected to climate change mitigation. We apply our framework to two themes which span different dimensions in the socio-ecological system: carbon accounting and bioenergy. A key finding in the literature was the perception that current uncertainties regarding the reliability of different methods of carbon accounting inhibits international agreement on the use of forests for climate change mitigation. This feeds into a strategic obstacle affecting the willingness of individual countries to implement forest-related carbon emission reduction policies. Decisions on the utilization of forests for bioenergy are impeded by a lack of knowledge regarding the resultant biophysical and social consequences. This interacts negatively with the development of institutional incentives regarding the production of bioenergy using forest products. Normative disagreement about acceptable forest use further affects these scientific discussions and therefore is an over-arching influence on decision-making. With our framework, we capture this complexity and, Funding Agencies:Swedish Forestry Industry Swedish University of Agricultural Sciences (SLU) Umeå University Forestry Research Institute of Sweden

Published

2018

16. Absorption Coefficient of a Semiconductor Thin Film from Photoluminescence

Author

Rey, Germain, Spindler, Conrad, Rachad, Wafae, Siebentritt, Susanne, Babbe, Finn, Nuys, M., Carius, R., Li, S., Platzer-Björkman, C., Rey, Germain, Spindler, Conrad, Rachad, Wafae, Siebentritt, Susanne, Babbe, Finn, Nuys, M., Carius, R., Li, S., and Platzer-Björkman, C.

Published

2018

17. Absorption Coefficient of a Semiconductor Thin Film from Photoluminescence

Author

Rey, Germain, Spindler, Conrad, Rachad, Wafae, Siebentritt, Susanne, Babbe, Finn, Nuys, M., Carius, R., Li, S., Platzer-Björkman, C., Rey, Germain, Spindler, Conrad, Rachad, Wafae, Siebentritt, Susanne, Babbe, Finn, Nuys, M., Carius, R., Li, S., and Platzer-Björkman, C.

Published

2018

18. Capturing complexity : Forests, decision-making and climate change mitigation action

Author

Klapwijk, M. J., Boberg, J., Bergh, J., Bishop, K., Björkman, C., Ellison, D., Felton, A., Lidskog, Rolf, Lundmark, T., Keskitalo, E. C. H., Sonesson, J., Nordin, A., Nordström, E. -M, Stenlid, J., Mårald, E., Klapwijk, M. J., Boberg, J., Bergh, J., Bishop, K., Björkman, C., Ellison, D., Felton, A., Lidskog, Rolf, Lundmark, T., Keskitalo, E. C. H., Sonesson, J., Nordin, A., Nordström, E. -M, Stenlid, J., and Mårald, E.

Abstract

Managed forests can play an important role in climate change mitigation due to their capacity to sequester carbon. However, it has proven difficult to harness their full potential for climate change mitigation. Managed forests are often referred to as socio-ecological systems as the human dimension is an integral part of the system. When attempting to change systems that are influenced by factors such as collective knowledge, social organization, understanding of the situation and values represented in society, initial intentions often shift due to the complexity of political, social and scientific interactions. Currently, the scientific literature is dispersed over the different factors related to the socio-ecological system. To examine the level of dispersion and to obtain a holistic view, we review climate change mitigation in the context of Swedish forest research. We introduce a heuristic framework to understand decision-making connected to climate change mitigation. We apply our framework to two themes which span different dimensions in the socio-ecological system: carbon accounting and bioenergy. A key finding in the literature was the perception that current uncertainties regarding the reliability of different methods of carbon accounting inhibits international agreement on the use of forests for climate change mitigation. This feeds into a strategic obstacle affecting the willingness of individual countries to implement forest-related carbon emission reduction policies. Decisions on the utilization of forests for bioenergy are impeded by a lack of knowledge regarding the resultant biophysical and social consequences. This interacts negatively with the development of institutional incentives regarding the production of bioenergy using forest products. Normative disagreement about acceptable forest use further affects these scientific discussions and therefore is an over-arching influence on decision-making. With our framework, we capture this complexity and, Funding Agencies:Swedish Forestry Industry Swedish University of Agricultural Sciences (SLU) Umeå University Forestry Research Institute of Sweden

Published

2018

19. Capturing complexity : Forests, decision-making and climate change mitigation action

Author

Klapwijk, M. J., Boberg, J., Bergh, Johan, Bishop, K., Björkman, C., Ellison, D., Felton, A., Lidskog, R., Lundmark, T., Keskitalo, E. C. H., Sonesson, J., Nordin, A., Nordström, E-M, Stenlid, J., Marald, E., Klapwijk, M. J., Boberg, J., Bergh, Johan, Bishop, K., Björkman, C., Ellison, D., Felton, A., Lidskog, R., Lundmark, T., Keskitalo, E. C. H., Sonesson, J., Nordin, A., Nordström, E-M, Stenlid, J., and Marald, E.

Abstract

Managed forests can play an important role in climate change mitigation due to their capacity to sequester carbon. However, it has proven difficult to harness their full potential for climate change mitigation. Managed forests are often referred to as socio-ecological systems as the human dimension is an integral part of the system. When attempting to change systems that are influenced by factors such as collective knowledge, social organization, understanding of the situation and values represented in society, initial intentions often shift due to the complexity of political, social and scientific interactions. Currently, the scientific literature is dispersed over the different factors related to the socio-ecological system. To examine the level of dispersion and to obtain a holistic view, we review climate change mitigation in the context of Swedish forest research. We introduce a heuristic framework to understand decision-making connected to climate change mitigation. We apply our framework to two themes which span different dimensions in the socio-ecological system: carbon accounting and bioenergy. A key finding in the literature was the perception that current uncertainties regarding the reliability of different methods of carbon accounting inhibits international agreement on the use of forests for climate change mitigation. This feeds into a strategic obstacle affecting the willingness of individual countries to implement forest related carbon emission reduction policies. Decisions on the utilization of forests for bioenergy are impeded by a lack of knowledge regarding the resultant biophysical and social consequences. This interacts negatively with the development of institutional incentives regarding the production of bioenergy using forest products. Normative disagreement about acceptable forest use further affects these scientific discussions and therefore is an over-arching influence on decision-making. With our framework, we capture this complexity and

Published

2018

20. Capturing complexity : Forests, decision-making and climate change mitigation action

Author

Klapwijk, M. J., Boberg, J., Bergh, J., Bishop, K., Björkman, C., Ellison, D., Felton, A., Lidskog, R., Lundmark, T., Keskitalo, E. Carina H., Sonesson, J., Nordin, A., Nordström, E.-M., Stenlid, J., Mårald, Erland, Klapwijk, M. J., Boberg, J., Bergh, J., Bishop, K., Björkman, C., Ellison, D., Felton, A., Lidskog, R., Lundmark, T., Keskitalo, E. Carina H., Sonesson, J., Nordin, A., Nordström, E.-M., Stenlid, J., and Mårald, Erland

Abstract

Managed forests can play an important role in climate change mitigation due to their capacity to sequester carbon. However, it has proven difficult to harness their full potential for climate change mitigation. Managed forests are often referred to as socio-ecological systems as the human dimension is an integral part of the system. When attempting to change systems that are influenced by factors such as collective knowledge, social organization, understanding of the situation and values represented in society, initial intentions often shift due to the complexity of political, social and scientific interactions. Currently, the scientific literature is dispersed over the differentfactorsrelated tothe socio-ecological system. Toexamine thelevelofdispersion andtoobtainaholistic view, we review climate change mitigation in the context of Swedish forest research. We introduce a heuristic framework to understand decision-making connected to climate change mitigation. We apply our framework to two themes which span different dimensions in the socio-ecological system: carbon accounting and bioenergy. A key finding in the literature was the perception that current uncertainties regarding the reliability of different methods of carbon accounting inhibits international agreement on the use of forests for climate change mitigation. This feeds into a strategic obstacle affecting the willingness of individual countries to implement forestrelated carbon emission reduction policies. Decisions on the utilization of forests for bioenergy are impeded by a lack of knowledge regarding the resultant biophysical and social consequences. This interacts negatively with the development of institutional incentives regarding the production of bioenergy using forest products. Normative disagreement about acceptable forest use further affects these scientific discussions and therefore is an over-arching influence on decision-making. With our framework, we capture this complexity and make obstacles to decisio

Published

2018

21. Capturing complexity : Forests, decision-making and climate change mitigation action

Author

Klapwijk, M. J., Boberg, J., Bergh, J., Bishop, K., Björkman, C., Ellison, D., Felton, A., Lidskog, Rolf, Lundmark, T., Keskitalo, E. C. H., Sonesson, J., Nordin, A., Nordström, E. -M, Stenlid, J., Mårald, E., Klapwijk, M. J., Boberg, J., Bergh, J., Bishop, K., Björkman, C., Ellison, D., Felton, A., Lidskog, Rolf, Lundmark, T., Keskitalo, E. C. H., Sonesson, J., Nordin, A., Nordström, E. -M, Stenlid, J., and Mårald, E.

Abstract

Managed forests can play an important role in climate change mitigation due to their capacity to sequester carbon. However, it has proven difficult to harness their full potential for climate change mitigation. Managed forests are often referred to as socio-ecological systems as the human dimension is an integral part of the system. When attempting to change systems that are influenced by factors such as collective knowledge, social organization, understanding of the situation and values represented in society, initial intentions often shift due to the complexity of political, social and scientific interactions. Currently, the scientific literature is dispersed over the different factors related to the socio-ecological system. To examine the level of dispersion and to obtain a holistic view, we review climate change mitigation in the context of Swedish forest research. We introduce a heuristic framework to understand decision-making connected to climate change mitigation. We apply our framework to two themes which span different dimensions in the socio-ecological system: carbon accounting and bioenergy. A key finding in the literature was the perception that current uncertainties regarding the reliability of different methods of carbon accounting inhibits international agreement on the use of forests for climate change mitigation. This feeds into a strategic obstacle affecting the willingness of individual countries to implement forest-related carbon emission reduction policies. Decisions on the utilization of forests for bioenergy are impeded by a lack of knowledge regarding the resultant biophysical and social consequences. This interacts negatively with the development of institutional incentives regarding the production of bioenergy using forest products. Normative disagreement about acceptable forest use further affects these scientific discussions and therefore is an over-arching influence on decision-making. With our framework, we capture this complexity and, Funding Agencies:Swedish Forestry Industry Swedish University of Agricultural Sciences (SLU) Umeå University Forestry Research Institute of Sweden

Published

2018

22. Capturing complexity : Forests, decision-making and climate change mitigation action

Author

Klapwijk, M. J., Boberg, J., Bergh, J., Bishop, K., Björkman, C., Ellison, D., Felton, A., Lidskog, Rolf, Lundmark, T., Keskitalo, E. C. H., Sonesson, J., Nordin, A., Nordström, E. -M, Stenlid, J., Mårald, E., Klapwijk, M. J., Boberg, J., Bergh, J., Bishop, K., Björkman, C., Ellison, D., Felton, A., Lidskog, Rolf, Lundmark, T., Keskitalo, E. C. H., Sonesson, J., Nordin, A., Nordström, E. -M, Stenlid, J., and Mårald, E.

Abstract

Managed forests can play an important role in climate change mitigation due to their capacity to sequester carbon. However, it has proven difficult to harness their full potential for climate change mitigation. Managed forests are often referred to as socio-ecological systems as the human dimension is an integral part of the system. When attempting to change systems that are influenced by factors such as collective knowledge, social organization, understanding of the situation and values represented in society, initial intentions often shift due to the complexity of political, social and scientific interactions. Currently, the scientific literature is dispersed over the different factors related to the socio-ecological system. To examine the level of dispersion and to obtain a holistic view, we review climate change mitigation in the context of Swedish forest research. We introduce a heuristic framework to understand decision-making connected to climate change mitigation. We apply our framework to two themes which span different dimensions in the socio-ecological system: carbon accounting and bioenergy. A key finding in the literature was the perception that current uncertainties regarding the reliability of different methods of carbon accounting inhibits international agreement on the use of forests for climate change mitigation. This feeds into a strategic obstacle affecting the willingness of individual countries to implement forest-related carbon emission reduction policies. Decisions on the utilization of forests for bioenergy are impeded by a lack of knowledge regarding the resultant biophysical and social consequences. This interacts negatively with the development of institutional incentives regarding the production of bioenergy using forest products. Normative disagreement about acceptable forest use further affects these scientific discussions and therefore is an over-arching influence on decision-making. With our framework, we capture this complexity and, Funding Agencies:Swedish Forestry Industry Swedish University of Agricultural Sciences (SLU) Umeå University Forestry Research Institute of Sweden

Published

2018

23. Capturing complexity : Forests, decision-making and climate change mitigation action

Author

Klapwijk, M. J., Boberg, J., Bergh, J., Bishop, K., Björkman, C., Ellison, D., Felton, A., Lidskog, R., Lundmark, T., Keskitalo, E. Carina H., Sonesson, J., Nordin, A., Nordström, E.-M., Stenlid, J., Mårald, Erland, Klapwijk, M. J., Boberg, J., Bergh, J., Bishop, K., Björkman, C., Ellison, D., Felton, A., Lidskog, R., Lundmark, T., Keskitalo, E. Carina H., Sonesson, J., Nordin, A., Nordström, E.-M., Stenlid, J., and Mårald, Erland

Abstract

Managed forests can play an important role in climate change mitigation due to their capacity to sequester carbon. However, it has proven difficult to harness their full potential for climate change mitigation. Managed forests are often referred to as socio-ecological systems as the human dimension is an integral part of the system. When attempting to change systems that are influenced by factors such as collective knowledge, social organization, understanding of the situation and values represented in society, initial intentions often shift due to the complexity of political, social and scientific interactions. Currently, the scientific literature is dispersed over the differentfactorsrelated tothe socio-ecological system. Toexamine thelevelofdispersion andtoobtainaholistic view, we review climate change mitigation in the context of Swedish forest research. We introduce a heuristic framework to understand decision-making connected to climate change mitigation. We apply our framework to two themes which span different dimensions in the socio-ecological system: carbon accounting and bioenergy. A key finding in the literature was the perception that current uncertainties regarding the reliability of different methods of carbon accounting inhibits international agreement on the use of forests for climate change mitigation. This feeds into a strategic obstacle affecting the willingness of individual countries to implement forestrelated carbon emission reduction policies. Decisions on the utilization of forests for bioenergy are impeded by a lack of knowledge regarding the resultant biophysical and social consequences. This interacts negatively with the development of institutional incentives regarding the production of bioenergy using forest products. Normative disagreement about acceptable forest use further affects these scientific discussions and therefore is an over-arching influence on decision-making. With our framework, we capture this complexity and make obstacles to decisio

Published

2018

24. CuS Cap to Prevent Decomposition of Cu2ZnSnS4 Precursors during Annealing

Author

Larsen, Jes K, Scragg, J. J., Frisk, C, Ren, Y., Platzer-Björkman, C., Larsen, Jes K, Scragg, J. J., Frisk, C, Ren, Y., and Platzer-Björkman, C.

Abstract

Chemical decomposition of the CZTS surface during annealing is detrimental to device performance. Aiming to obtain more flexibility in the annealing process the surface is protected by a thin CuS cap.

Published

2015

25. Temperature affects insect outbreak risk through tritrophic interactions mediated by plant secondary compounds

Author

Kollberg, Ida, Bylund, H., Jonsson, Tomas, Schmidt, A., Gershenzon, J., Björkman, C., Kollberg, Ida, Bylund, H., Jonsson, Tomas, Schmidt, A., Gershenzon, J., and Björkman, C.

Published

2015

26. HIKE experiments at KMC-1: Studies of Solar Cell Materials

Author

Johansson, E, Platzer-Björkman, C, Rensmo, H, Sandell, A, Siegbahn, Hans, Stolt, Lars, Gorgoi, M, Svensson, S, Lewin, Erik, Schäfers, F, Braun, W, Eberhardt, W, Johansson, E, Platzer-Björkman, C, Rensmo, H, Sandell, A, Siegbahn, Hans, Stolt, Lars, Gorgoi, M, Svensson, S, Lewin, Erik, Schäfers, F, Braun, W, and Eberhardt, W

Published

2007

27. Immunization of cattle with live tachyzoites of Neospora caninum confers protection against fetal death

Author

Williams, DJL, Guy, CS, Smith, RF, Ellis, J, Björkman, C, Reichel, MP, Trees, AJ, Williams, DJL, Guy, CS, Smith, RF, Ellis, J, Björkman, C, Reichel, MP, and Trees, AJ

Abstract

Neospora caninum is an obligate intracellular protozoan parasite that causes abortion in cattle. It is normally found as a latent infection controlled by a T-helper-cell type 1 response involving CD4+ cytotoxic T cells and gamma interferon. Cattle may be infected by two different routes: transplacentally as a result of activation of the latent infection in the mother causing congenital infection or abortion and by ingestion of oocysts, which, if it occurs during gestation, can also result in abortion. Here, for the first time, we establish proof that live vaccination protects against fetal death, whereas immunization using whole-tachyzoite lysate in different adjuvants fails to protect against fetal death. Strong antibody responses were induced in all the vaccinated groups, and the quality and magnitude of these responses were similar in the live- and the lysate-vaccinated groups. In contrast, only the group immunized with live tachyzoites had strong cellular and gamma interferon responses prior to challenge, and these responses correlated with protection against fetopathy. These results suggest that a cellular immune response may be important in the mechanisms involved in protection against N. caninum-associated abortions. Copyright © 2007, American Society for Microbiology. All Rights Reserved.

Published

2007

28. Immunization of cattle with live tachyzoites of Neospora caninum confers protection against fetal death

Author

Williams, DJL, Guy, CS, Smith, RF, Ellis, J, Björkman, C, Reichel, MP, Trees, AJ, Williams, DJL, Guy, CS, Smith, RF, Ellis, J, Björkman, C, Reichel, MP, and Trees, AJ

Abstract

Neospora caninum is an obligate intracellular protozoan parasite that causes abortion in cattle. It is normally found as a latent infection controlled by a T-helper-cell type 1 response involving CD4+ cytotoxic T cells and gamma interferon. Cattle may be infected by two different routes: transplacentally as a result of activation of the latent infection in the mother causing congenital infection or abortion and by ingestion of oocysts, which, if it occurs during gestation, can also result in abortion. Here, for the first time, we establish proof that live vaccination protects against fetal death, whereas immunization using whole-tachyzoite lysate in different adjuvants fails to protect against fetal death. Strong antibody responses were induced in all the vaccinated groups, and the quality and magnitude of these responses were similar in the live- and the lysate-vaccinated groups. In contrast, only the group immunized with live tachyzoites had strong cellular and gamma interferon responses prior to challenge, and these responses correlated with protection against fetopathy. These results suggest that a cellular immune response may be important in the mechanisms involved in protection against N. caninum-associated abortions. Copyright © 2007, American Society for Microbiology. All Rights Reserved.

Published

2007

29. Qualitative descriptions of capacity building in schools - two Swedish cases. : Paper presented at the NFPF/NERA Conference in Örebro, Sweden, 2006-03-09-11.

Author

Björkman, C, Olofsson, Anders, Björkman, C, and Olofsson, Anders

Published

2006

30. Redescription of Neospora caninum and its differentiation from related coccidia

Author

Dubey, JP, Barr, BC, Barta, JR, Bjerkås, I, Björkman, C, Blagburn, BL, Bowman, DD, Buxton, D, Ellis, JT, Gottstein, B, Hemphill, A, Hill, DE, Howe, DK, Jenkins, MC, Kobayashi, Y, Koudela, B, Marsh, AE, Mattsson, JG, McAllister, MM, Modrý, D, Omata, Y, Sibley, LD, Speer, CA, Trees, AJ, Uggla, A, Upton, SJ, Williams, DJL, Lindsay, DS, Dubey, JP, Barr, BC, Barta, JR, Bjerkås, I, Björkman, C, Blagburn, BL, Bowman, DD, Buxton, D, Ellis, JT, Gottstein, B, Hemphill, A, Hill, DE, Howe, DK, Jenkins, MC, Kobayashi, Y, Koudela, B, Marsh, AE, Mattsson, JG, McAllister, MM, Modrý, D, Omata, Y, Sibley, LD, Speer, CA, Trees, AJ, Uggla, A, Upton, SJ, Williams, DJL, and Lindsay, DS

Abstract

Neospora caninum is a protozoan parasite of animals, which before 1984 was misidentified as Toxoplasma gondii. Infection by this parasite is a major cause of abortion in cattle and causes paralysis in dogs. Since the original description of N. caninum in 1988, considerable progress has been made in the understanding of its life cycle, biology, genetics and diagnosis. In this article, the authors redescribe the parasite, distinguish it from related coccidia, and provide accession numbers to its type specimens deposited in museums. Published by Elsevier Science Ltd. on behalf of Australian Society for Parasitology Inc.

Published

2002

31. Redescription of Neospora caninum and its differentiation from related coccidia

Author

Dubey, JP, Barr, BC, Barta, JR, Bjerkås, I, Björkman, C, Blagburn, BL, Bowman, DD, Buxton, D, Ellis, JT, Gottstein, B, Hemphill, A, Hill, DE, Howe, DK, Jenkins, MC, Kobayashi, Y, Koudela, B, Marsh, AE, Mattsson, JG, McAllister, MM, Modrý, D, Omata, Y, Sibley, LD, Speer, CA, Trees, AJ, Uggla, A, Upton, SJ, Williams, DJL, Lindsay, DS, Dubey, JP, Barr, BC, Barta, JR, Bjerkås, I, Björkman, C, Blagburn, BL, Bowman, DD, Buxton, D, Ellis, JT, Gottstein, B, Hemphill, A, Hill, DE, Howe, DK, Jenkins, MC, Kobayashi, Y, Koudela, B, Marsh, AE, Mattsson, JG, McAllister, MM, Modrý, D, Omata, Y, Sibley, LD, Speer, CA, Trees, AJ, Uggla, A, Upton, SJ, Williams, DJL, and Lindsay, DS

Abstract

Neospora caninum is a protozoan parasite of animals, which before 1984 was misidentified as Toxoplasma gondii. Infection by this parasite is a major cause of abortion in cattle and causes paralysis in dogs. Since the original description of N. caninum in 1988, considerable progress has been made in the understanding of its life cycle, biology, genetics and diagnosis. In this article, the authors redescribe the parasite, distinguish it from related coccidia, and provide accession numbers to its type specimens deposited in museums. Published by Elsevier Science Ltd. on behalf of Australian Society for Parasitology Inc.

Published

2002

32. XPS/UPS monitoring of ALCVD ZnO growth on Cu(In,Ga)Se2 absorbers

Author

Sterner, J, Platzer-Björkman, C, Stolt, L, Sterner, J, Platzer-Björkman, C, and Stolt, L

Published

2001

33. Associations of Neospora caninum seropositivity with environment and management in Danish dairy herds

Author

Agger, Jens Frederik Gramstrup, Willadsen, C. M., Lind, P., Mikél Jensen, A., Björkman, C., Agger, Jens Frederik Gramstrup, Willadsen, C. M., Lind, P., Mikél Jensen, A., and Björkman, C.

Published

2000

34. Associations of Neospora caninum seropositivity with environment and management in Danish dairy herds

Author

Agger, Jens Frederik Gramstrup, Willadsen, C. M., Lind, P., Mikél Jensen, A., Björkman, C., Agger, Jens Frederik Gramstrup, Willadsen, C. M., Lind, P., Mikél Jensen, A., and Björkman, C.

Published

2000

35. Auditory inspection time: on the importance of selecting the appropriate sensory continuum

Author

Olsson, Henrik, Björkman, C, Haag, K, Juslin, Peter, Olsson, Henrik, Björkman, C, Haag, K, and Juslin, Peter

Abstract

Auditory Inspection Time (AIT) is an index of mental speed which correlates moderately with measures of intelligence. This study shows that a loudness version (APT-L) of an AIT task correlated higher with Raven's Advanced Progressive Matrices (RAPM) than, Addresses: Olsson H, Uppsala Univ, Dept Psychol, Box 1225, SE-75142 Uppsala, Sweden. Uppsala Univ, Dept Psychol, SE-75142 Uppsala, Sweden.

Published

1998

36. Auditory inspection time: on the importance of selecting the appropriate sensory continuum

Author

Olsson, Henrik, Björkman, C, Haag, K, Juslin, Peter, Olsson, Henrik, Björkman, C, Haag, K, and Juslin, Peter

Abstract

Auditory Inspection Time (AIT) is an index of mental speed which correlates moderately with measures of intelligence. This study shows that a loudness version (APT-L) of an AIT task correlated higher with Raven's Advanced Progressive Matrices (RAPM) than, Addresses: Olsson H, Uppsala Univ, Dept Psychol, Box 1225, SE-75142 Uppsala, Sweden. Uppsala Univ, Dept Psychol, SE-75142 Uppsala, Sweden.

Published

1998

37. Conduction through corrosion films on silver plated copper in power contacts

Author

Kassman Rudolphi, Åsa, Imrell, T, Björkman, C, Jacobson, S, Kassman Rudolphi, Åsa, Imrell, T, Björkman, C, and Jacobson, S

Published

1995