Introduction

The ultimate purpose of science is establishing how the Earth system works – concepts that are based on evidence we all can agree on regardless of our religious believes or personal opinions. This typically does not happen in a short time and needs continuous ongoing efforts of dedicated researchers. The 50-year global CO2 record [1, 2] resulted in established scientific fact: modern civilization is changing the concentration of atmospheric CO2 significantly. Other evidence shows the world has not experienced this for a million years, and probably for much longer. It is also well known that the planetary heat budget is significantly changed as a result.

Discussion

This scientific fact is based on the range of empirical findings. Each of them may need further refinement, and so we listed some of them below to display the current state of knowledge and horizons for further research.

  1. 1.

    The increase of CO2 in the atmosphere and in the oceans add up to, within uncertainty, almost the total production of CO2 from the burning of fossil fuels [3], showing that enhanced terrestrial biospheric activity has compensated CO2 release from anthropogenic land-use changes, such as large scale deforestation. Net terrestrial sources from pre-industrial times showed net emission before 1940, and a small net sink since then [3].

  2. 2.

    The airborne fraction of CO2 emission, defined as the observed atmospheric increase divided by emissions of fossil CO2, has been remarkably constant over the last 50 years [6]. This is not a fundamental property of the carbon cycle, however [4]. The past record is not sufficient on its own to determine how the airborne fraction will evolve in the future.

  3. 3.

    The inter-annual variations of the growth rate of atmospheric CO2 are controlled by the terrestrial biosphere, which exhibits a delayed response to anomalies of both global temperature and precipitation [3]. This provides us with evidence of natural carbon cycle sensitivity to climate, and may provide constraints on future feedbacks in response to long-term climate change.

  4. 4.

    The long-term increase of the amplitude of the seasonal cycle and its interannual variations displays a response of the northern hemisphere terrestrial biosphere to climate variations and trends [5].

  5. 5.

    Based on coupled carbon cycle – climate model simulations, climate feedbacks are expected to amplify global warming over the next hundred years [6, 7]. Continued long term monitoring of CO2 at Mauna Loa and at other sites is required to uncover more information about the carbon cycle and to reduce the uncertainty in climate feedbacks [4, 6, 8, 9].

  6. 6.

    The observed history of the global carbon cycle together with fundamental process understanding of carbon uptake in the ocean and on land imply that over the next decades emissions have to be reduced to levels less than 50% than today, if atmospheric concentrations are to be stabilized below 550 ppm by the end of this century. Possible positive climate feedbacks imply even stronger emission reductions for CO2 concentration stabilization.

Conclusion

The next generation of scientists will live in a world that is aware of its responsibility for planetary change and will demand globally concerted actions [10, 11]. Revealing the effectiveness of these actions in changing the conditions of the disturbed Earth system is one of the things the world community is likely to expect from scientists. Young scientists must be prepared to meet this challenge, which has to take shape in new institutional frameworks [12].