The Great Barrier Reef (GBR) is founded on reef-building corals. Corals build their exoskeleton with aragonite, but ocean acidification is lowering the aragonite saturation state of seawater (Ωa). The downscaling of ocean acidification projections from global to GBR scales requires the set of regional drivers controlling Ωa to be resolved.

We present the first, to our knowledge, estimate of global sea-level (GSL) change over the last ∼3,000 years that is based upon statistical synthesis of a global database of regional sea-level reconstructions. GSL varied by ∼±8 cm over the pre-Industrial Common Era, with a notable decline over 1000–1400 CE coinciding with ∼0.2 °C of global cooling. The 20th century rise was extremely likely faster than during any of the 27 previous centuries.

Recent research has shown evidence of a linear climate response to cumulative CO2 emissions, which implies that the source, timing, and amount of emissions does not significantly influence the climate response per unit emission. Furthermore, these analyses have generally assumed that the climate response to land-use CO2 emissions is equivalent to that of fossil fuels under the assumption that, once in the atmosphere, the radiative forcing induced by CO2 is not sensitive to the emissions source.

A time series of organic carbon export from Gulf of Maine (GoM) watersheds was compared to a time series of biological, chemical, bio-optical, and hydrographic properties, measured across the GoM between Yarmouth, NS, Canada, and Portland, ME, U.S. Optical proxies were used to quantify the dissolved organic carbon (DOC) and particulate organic carbon in the GoM. The Load Estimator regression model applied to river discharge data demonstrated that riverine DOC export (and its decadal variance) has increased over the last 80 years.

The article sheds light on the Adi Ganga, one of the most significant streams of the Ganges in its lower course, and narrates how the stream (later Tolly’s Canal) which was once the life line of Kolkata transformed into a mere sewer and was ruthlessly slaughtered with the changing politicoeconomic interests of the state.

Serious epidemics after the December 2015 floods in Chennai were averted by prompt preventive action initiated by the government which was supported by NGOs and citizen groups. This article highlights areas for improvement and initiates a dialogue around the theme of disaster preparedness and better coordinated relief efforts.

Contemporary debates on Indian agriculture need to shift from the traditional focus on physical productivity targets towards smart policies, strengthened and relevant institutions, and an enabling environment, all of which are needed to foster a more profitable, sustainable and resilient agricultural sector capable of ending poverty and boosting shared prosperity.

Water management requires multiple levels of policy action. The problem is not a shortage of water, but the absence of proper mechanisms for its augmentation, conservation, distribution, and effi cient use. Water management should be given number one priority in agricultural policy, particularly to prevent drought, minimise the risks due to drought and build a climate-resilient agriculture.

India's track record of forming robust, self-sustaining farmer cooperatives has been poor ever since the early 1900s when the movement began. For long, restrictive laws were blamed for their failure. But most of the 2,000 farmer producer companies registered under a new amendment to the Companies Act 1956 appear like old wine in a new bottle. This article explores why, and argues for the need to focus on the logic and process of promoting new farmer cooperatives to improve their success rate.

Indian agriculture is once again in a slowdown. After the spurt of 2004–05—2011–12 when growth accelerated and the variability of production declined, in recent years growth has slowed and volatility has risen. Given weak world economic prospects and looming climate change, the main objectives of agricultural policy should now be to (i) enhance effi ciency of production and natural resource use, and (ii) devise appropriate safety nets to cope with risks whether from markets or climate.

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