Emission pathways consistent with a 2 °C global temperature limit
about
Structure of Benthic Communities along the Taiwan Latitudinal GradientGlobal spatially explicit CO2 emission metrics for forest bioenergyTrading Off Global Fuel Supply, CO2 Emissions and Sustainable Development.Convergence in the temperature response of leaf respiration across biomes and plant functional typesDisentangling the effects of CO2 and short-lived climate forcer mitigationCoverage, diversity, and functionality of a high-latitude coral community (Tatsukushi, Shikoku Island, Japan)Developed and developing world responsibilities for historical climate change and CO2 mitigationA human-scale perspective on global warming: Zero emission year and personal quotasWhy human health and health ethics must be central to climate change deliberations.Which climate change path are we following? Bad news from Scots pine.A critical review of global decarbonization scenarios: what do they tell us about feasibility?Implications of weak near-term climate policies on long-term mitigation pathwaysPost-2020 climate agreements in the major economies assessed in the light of global modelsHarmonization vs. fragmentation: overview of climate policy scenarios in EMF27Importance of food-demand management for climate mitigationThe challenge to keep global warming below 2 °CPolicy trade-offs between climate mitigation and clean cook-stove access in South Asia2020 emissions levels required to limit warming to below 2 °CClimate policies can help resolve energy security and air pollution challengesOrigins of differences in climate sensitivity, forcing and feedback in climate modelsCopenhagen Accord Pledges imply higher costs for staying below 2°C warmingMulti-model comparison of the economic and energy implications for China and India in an international climate regimeEnhanced chemical weathering as a geoengineering strategy to reduce atmospheric carbon dioxide, supply nutrients, and mitigate ocean acidificationPotential contribution of wind energy to climate change mitigationThe impact of technology availability on the timing and costs of emission reductions for achieving long-term climate targetsTowards an Integrated Framework for SDGs: Ultimate and Enabling Goals for the Case of EnergyInaction and climate stabilization uncertainties lead to severe economic risksThe role of short-lived climate pollutants in meeting temperature goalsEmission pathways to achieve 2.0°C and 1.5°C climate targetsBECCS capability of dedicated bioenergy crops under a future land-use scenario targeting net negative carbon emissionsEmission metrics under the 2 °C climate stabilization targetWhat if negative emission technologies fail at scale? Implications of the Paris Agreement for big emitting nationsHeritage, heritage tourism and climate changeChallenges of tourism in a low-carbon economyThe importance of reduced meat and dairy consumption for meeting stringent climate change targetsPotential for Energy Production from Farm Wastes Using Anaerobic Digestion in the UK: An Economic Comparison of Different Size Plants
P2860
Q28597962-DB474ADD-1A7E-4848-B24D-63A11FAF9D39Q28601631-75EFDC93-1E76-47B5-8B01-328324F659D4Q28603045-3862D080-D510-4354-B5F5-5BA3B5D67DB2Q28604191-93C4B87E-C385-4280-A48B-249100A8EA66Q28651152-385433FC-C9E8-4649-9D33-DA9F0BED45A8Q28709991-8EE0E4DA-4585-4946-86E4-B20C26C315F3Q28728403-B77C2CD1-EFAB-44FC-897D-244ACD5E30B3Q33811889-AC652657-DB54-47BB-9B15-4030E325F13FQ34297023-7309DCBD-1386-4DAF-B1F9-ECE3E628AAFDQ46237567-213AFCF2-979C-436A-820F-963225D4AD90Q55871520-1D32F680-BA21-4AB7-A93A-C142A02DC655Q56638953-61B6FBBF-ED91-429C-A121-FD123772CCD9Q56867692-05B0A6B5-C20B-40C9-975A-868C876F805AQ56867696-966CD176-8E07-4275-80C2-08BAE6AA48F7Q57028387-C203AE1B-73BB-4321-8010-23B99765DD8EQ57160589-A5FE260D-4657-4904-9A70-C6E96F2E378BQ57265862-8A9DB8AF-A764-419B-A792-46CB656E137FQ57265892-73F4C75F-9A6F-4FF7-B94E-4F70E8DCAF71Q57265897-1BED8452-FAE2-40A5-A805-72E482773796Q57921247-376B2ADE-FE4E-4C2F-B9EB-879C278305A0Q58058199-C10237B8-5BFB-4913-954E-0148769715C7Q58082374-E14D9D45-D9BD-4A73-BF8C-0D9E8A90D045Q58087555-3B1C5BB8-2005-442F-BCFF-8DF7E29A322DQ58094620-D6779D8C-00FE-41B3-AAFA-3E4F90676C0DQ58094996-D44E41A7-7216-4BC1-9152-F547D9E6998DQ58098297-24B79602-4058-412D-B1D4-EDFF388C3C40Q58213686-7002442A-1DFC-4218-95E8-CC6325173F17Q58267174-FA4500DE-AB1B-4161-8F21-E47D45A40952Q58384512-87FA7777-C7EB-4DED-9388-A4718E8052A8Q58384527-C08EB700-69A6-4A96-8637-F2D0838A8058Q58386595-FE9BC58C-72B1-44C4-ADF7-921F11DB2EAFQ58481622-51CE81F4-54EF-4827-AFA9-1A57D7AA61D8Q58514145-E0D81001-5B21-4DEB-95F1-CE51DE8C53E5Q58805225-6E27375B-C8EE-4A7B-95E0-BE28D9F0022EQ59322385-9F5EAFDC-6DD5-47FA-9D4D-6AC7FE8E7ACCQ59324997-6800EEC1-594C-4A48-8B11-639C758D9ADB
P2860
Emission pathways consistent with a 2 °C global temperature limit
description
article
@en
im Oktober 2011 veröffentlichter wissenschaftlicher Artikel
@de
wetenschappelijk artikel
@nl
наукова стаття, опублікована в жовтні 2011
@uk
name
Emission pathways consistent with a 2 °C global temperature limit
@en
Emission pathways consistent with a 2 °C global temperature limit
@nl
type
label
Emission pathways consistent with a 2 °C global temperature limit
@en
Emission pathways consistent with a 2 °C global temperature limit
@nl
prefLabel
Emission pathways consistent with a 2 °C global temperature limit
@en
Emission pathways consistent with a 2 °C global temperature limit
@nl
P2093
P2860
P50
P356
P1476
Emission pathways consistent with a 2 °C global temperature limit
@en
P2093
Ben Matthews
Jason Lowe
Kejun Jiang
Tatsuya Hanaoka
P2860
P2888
P304
P356
10.1038/NCLIMATE1258
P577
2011-10-23T00:00:00Z