CitationResourcesExamples: Difference between revisions

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* type = article | journal-article
* type = article | journal-article
* Required fields: author, title, journal, year.  
* Required fields: author, title, journal, year.  
* Optional fields: volume, number, pages, month, note.  
* Optional fields: volume, number, pages, month, doi, note.  


{{#scite: |reference=van vuuren2013a  
{{#scite: |reference=van vuuren2013a  
Line 58: Line 58:
}}
}}


{{#scite:
@Article{vanVuuren2007,
|bibtex=@ARTICLE{vanVuuren2013,
author="van Vuuren, Detlef P.
author="van Vuuren, Detlef P. and Kriegler, Elmar and O'Neill, Brian C.",
and den Elzen, Michel J. G.
title="A new scenario wiki",
and Lucas, Paul L.
and Eickhout, Bas
and Strengers, Bart J.
and van Ruijven, Bas
and Wonink, Steven
and van Houdt, Roy",
title="Stabilizing greenhouse gas concentrations at low levels: an assessment of reduction strategies and costs",
journal="Climatic Change",
journal="Climatic Change",
year="2014",
year="2007",
volume="122",
volume="81",
number="3",
number="2",
pages="373--386",
pages="119--159",
abstract="This paper describes the scenario matrix architecture that underlies a framework for developing new scenarios for climate change research. The matrix architecture facilitates addressing key questions related to current climate research and policy-making: identifying the effectiveness of different adaptation and mitigation strategies (in terms of their costs, risks and other consequences) and the possible trade-offs and synergies. The two main axes of the matrix are: 1) the level of radiative forcing of the climate system (as characterised by the representative concentration pathways) and 2) a set of alternative plausible trajectories of future global development (described as shared socio-economic pathways). The matrix can be used to guide scenario development at different scales. It can also be used as a heuristic tool for classifying new and existing scenarios for assessment. Key elements of the architecture, in particular the shared socio-economic pathways and shared policy assumptions (devices for incorporating explicit mitigation and adaptation policies), are elaborated in other papers in this special issue.",
abstract="On the basis of the IPCC B2, A1b and B1 baseline scenarios, mitigation scenarios were developed that stabilize greenhouse gas concentrations at 650, 550 and 450 and -- subject to specific assumptions -- 400 ppm CO2-eq. The analysis takes into account a large number of reduction options, such as reductions of non-CO2 gases, carbon plantations and measures in the energy system. The study shows stabilization as low as 450 ppm CO2-eq. to be technically feasible, even given relatively high baseline scenarios. To achieve these lower concentration levels, global emissions need to peak within the first two decades. The net present value of abatement costs for the B2 baseline scenario (a medium scenario) increases from 0.2{\%} of cumulative GDP to 1.1{\%} as the shift is made from 650 to 450 ppm. On the other hand, the probability of meeting a two-degree target increases from 0{\%}--10{\%} to 20{\%}--70{\%}. The mitigation scenarios lead to lower emissions of regional air pollutants but also to increased land use. The uncertainty in the cost estimates is at least in the order of 50{\%}, with the most important uncertainties including land-use emissions, the potential for bio-energy and the contribution of energy efficiency. Furthermore, creating the right socio-economic and political conditions for mitigation is more important than any of the technical constraints.",
issn="1573-1480",
issn="1573-1480",
doi="10.1007/s10584-013-0906-2",
doi="10.1007/s10584-006-9172-9",
url="http://dx.doi.org/10.1007/s10584-013-0906-1"
url="http://dx.doi.org/10.1007/s10584-006-9172-9"
}
}
}}
}}
<!-- type (book) A book with an explicit publisher. Required fields: author or editor, title, publisher, year. Optional fields: volume or number, series, address, edition, month, note. -->
<!-- type (book) A book with an explicit publisher. Required fields: author or editor, title, publisher, year. Optional fields: volume or number, series, address, edition, month, note. -->

Revision as of 14:58, 1 August 2016

{{#referencelist: 

|references=van vuuren2013a;

vanVuuren2013; Denning:1991:CUA:102616; Zhai:2016:TDM:2915031; vanVuuren2014; Hof2012; APAexample1;|+sep=; 

|listtype=ol
|browselinks=yes
|columns=1
|toc=yes

}}

Intro

A citation may be defined by bibtex exports or a set of property-value pairs. Surrounding the definition with:

{{#scite: ... }}

will interpret the definition into an citation text. The format depends on the type of the citation.

The examples below show the different types and their definitions and fields

Article definition

  • An article from a journal or magazine.
  • type = article | journal-article
  • Required fields: author, title, journal, year.
  • Optional fields: volume, number, pages, month, doi, note.

{{#scite: |reference=van vuuren2013a |type=Journal-article |title=A new scenario framework for Climate Change Research: scenario matrix architecture |author=Detlef P. van Vuuren;Elmar Kriegler;Brian C. O’Neill;Kristie L. Ebi;Keywan Riahi;Timothy R. Carter;Jae Edmonds;Stephane Hallegatte;Tom Kram;Ritu Mathur;Harald Winkler|+sep=; |journal=Climatic Change |publisher=Springer Science + Business Media |year=2013 |volume=122 |number=3 |pages=373-386 |doi=10.1007/s10584-013-0906-1 |subject=Atmospheric Science;Global and Planetary Change|+sep=; |issn=0165-0009;1573-1480|+sep=; }} 

{{#scite: |reference=van vuuren2013a 
|type=Journal-article 
|title=A new scenario framework for Climate Change Research: scenario matrix architecture |author=Detlef P. van Vuuren;Elmar Kriegler;Brian C. O’Neill;Kristie L. Ebi;Keywan Riahi;Timothy R. Carter;Jae Edmonds;Stephane Hallegatte;Tom Kram;Ritu Mathur;Harald Winkler|+sep=; 
|journal=Climatic Change 
|publisher=Springer Science + Business Media 
|year=2013 
|volume=122 
|number=3 
|pages=373-386 
|doi=10.1007/s10584-013-0906-1 
|subject=Atmospheric Science;Global and Planetary Change|+sep=; 
|issn=0165-0009;1573-1480|+sep=; 
}}

{{#referencelist: 

|references=van vuuren2013a
|browselinks=no
|columns=1

}}

@Article{vanVuuren2007, author="van Vuuren, Detlef P. and den Elzen, Michel J. G. and Lucas, Paul L. and Eickhout, Bas and Strengers, Bart J. and van Ruijven, Bas and Wonink, Steven and van Houdt, Roy", title="Stabilizing greenhouse gas concentrations at low levels: an assessment of reduction strategies and costs", journal="Climatic Change", year="2007", volume="81", number="2", pages="119--159", abstract="On the basis of the IPCC B2, A1b and B1 baseline scenarios, mitigation scenarios were developed that stabilize greenhouse gas concentrations at 650, 550 and 450 and -- subject to specific assumptions -- 400 ppm CO2-eq. The analysis takes into account a large number of reduction options, such as reductions of non-CO2 gases, carbon plantations and measures in the energy system. The study shows stabilization as low as 450 ppm CO2-eq. to be technically feasible, even given relatively high baseline scenarios. To achieve these lower concentration levels, global emissions need to peak within the first two decades. The net present value of abatement costs for the B2 baseline scenario (a medium scenario) increases from 0.2{\%} of cumulative GDP to 1.1{\%} as the shift is made from 650 to 450 ppm. On the other hand, the probability of meeting a two-degree target increases from 0{\%}--10{\%} to 20{\%}--70{\%}. The mitigation scenarios lead to lower emissions of regional air pollutants but also to increased land use. The uncertainty in the cost estimates is at least in the order of 50{\%}, with the most important uncertainties including land-use emissions, the potential for bio-energy and the contribution of energy efficiency. Furthermore, creating the right socio-economic and political conditions for mitigation is more important than any of the technical constraints.", issn="1573-1480", doi="10.1007/s10584-006-9172-9", url="http://dx.doi.org/10.1007/s10584-006-9172-9" }


}} {{#scite: |bibtex= @book{Denning:1991:CUA:102616, editor = {Peter J. Denning}, title = {Computers Under Attack: Intruders, Worms, and Viruses}, year = {1990}, isbn = {0-201-53067-8}, source = {ACM member price \$21.50, order number 706900}, publisher = {ACM}, address = {New York, NY, USA}, } }}

{{#scite: |bibtex= @book{Zhai:2016:TDM:2915031, 

author = {Zhai, ChengXiang and Massung, Sean},
title = {Text Data Management and Analysis: A Practical Introduction to Information Retrieval and Text Mining},
year = {2016},
isbn = {978-1-97000-117-4},
publisher = {Association for Computing Machinery and Morgan & Claypool},
address = {New York, NY, USA},

} }} {{#scite:vanVuuren2014 |type=incollection |author=Detlef P. van Vuuren; Bas van Ruijven; David Gernaat; Harmen-Sytze de Boer|+sep=; |title=Energy conversion |year=2014 |chapter=4.1.2 |pages=89-98 |booktitle=Integrated assessment of global change with IMAGE 3.0 |editor=Elke Stehfest; Detlef van Vuuren;Tom Kram;Lex Bouwman|+sep=; |publisher=PBL Netherlands Environmental Assessment Agency |address=The Hague, Netherlands }}

{{#scite:Hof2012 

|type=report
|author=A. F. Hof; C. Brink;A. Mendoza Beltrán; M. G. J. Den Elzen|+sep=;
|year=2012
|title=Greenhouse gas emission reduction targets for 2030: Conditions for a EU target of 40%
|institution=PBL Netherlands Environmental Assessment Agency
|address=The Hague, Netherlands

}}

{{#scite:APAexample1 |type=webpage |title=APA Citation Examples |year=2016 |url=http://www.umuc.edu/library/libhow/apa_examples.cfm |accessyear=2016 |accessdate=August 1 }}

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