Water plays a crucial role in geological processes which operate on planetary bodies such as our own Earth. Water affects physical properties of magmas, thermal stabilities of minerals and melts, and control magma eruptive processes. In addition, water is one of the key components influencing the habitability of a planetary body and in the context of in-situ resource utilization on other planetary bodies, such as the Moon, it will be an invaluable resource for life-support, and a key resource for generating rocket fuel. Since the Apollo era, the Moon has always been considered bone dry, especially with respect to water in lunar magmas. Amongst the most exciting recent discoveries is the presence of significant quantities of water on the lunar surface at lower latitudes as confirmed by a number of spacecraft missions (India's Chandrayaan-1 and NASA's LRO and LCROSS). These findings have been corroborated by recent, earth-based, laboratory analysis of lunar samples which suggest significant quantities of indigenous water in lunar magmas. Although the first demonstration of water in lunar magmas came from direct measurement of volcanic glasses, since they formed in violent, 'fire-fountain' eruptions, they possibly degassed losing much of lunar magmatic water upon eruption. The new detections of water have come from apatite crystals found in mare basalts. Because the basalt came from quieter eruptions than the fire fountains that formed the glasses, the apatite crystals are better repository of lunar water and may provide better constraints on the original water content of the lunar magmas and by proxy the water content of the lunar mantle. Chronological studies of mare-basalts returned by Apollo and Luna missions have revealed that the basaltic volcanism on the Moon occurred between 3.9 Ga and 3.1 Ga ago, leading to the hypothesis that mare volcanism occurred mainly after the late heavy bombardment around 3.8-3.9 Ga. However, recent chronological studies of lunar basalts have significantly expanded our knowledge of the duration of basaltic volcanism on the Moon extending the age range from 2.9 to 4.35 Ga, leading to speculation that basaltic volcanism on the Moon began within the first 150 Ma of Solar System formation, much earlier than previously thought. This hypothesis may be tested by examining examples of mare-basalts suspected to be older than 3.9 Ga, notably as clasts in breccias from Apollo site 14. Therefore, one of the aims of this proposal is to carry out age dating of mare-basalts to determine the total range of ages recorded in lunar basalts to place limits on the duration of mare volcanism. Crucially, basalts are the dominant products of planetary melting providing a window into planetary interiors by which we can understand the physical and chemical makeup and evolution of planetary bodies after accretion. Since the Moon is the only planetary body, apart from Earth, from which we have rock-samples (including basalts from known locations), lunar sample studies can provide an unrivalled dataset with which we can understand the mechanisms of planetary formation and subsequent evolution during that critical time period not recorded in terrestrial samples. We propose to carry out a coupled study of determining the volcanic history of the Moon along with measuring and assessing water contents in lunar basalts and their source regions. We will target apatites which are shown to be the main repository of water in lunar basalts while being amenable to in-situ radiometric age dating, giving crystallization ages for mare magma, sourced from the lunar mantle. Therefore, our proposed work will provide a comprehensive dataset with which we will be able to investigate the secular variation of water in the lunar mantle, thereby, providing a ground-breaking research output with far-reaching implications for our understanding of the structure and evolution of the Moon and other similar terrestrial bodies in our Solar System.

The air we breathe is teaming with microorganisms, with air currents transporting microbes globally. The earliest efforts to describe the distribution of airborne microbes were carried out by the founding father of microbiology, Louis Pasteur, over 125 years ago; but since then airborne microbes have been largely ignored. One reasons for this is that there are significant technical challenges in collecting airborne microorganisms,and thus microbial ecologists have focused on the low hanging fruit of soil and waterborne microorganisms. Even when efforts have been made to study airborne microorganisms, the research has been largely focused at a local/national level, but air pollution does not respect national boarders. Therefore, we have assembled a new network of world-leading experts in bioaerosols biomonitoring to take a global perspective on the ecology and human and environmental health effects of airborne microorganisms. Collectively, airborne microorganisms are referred to as bioaerosols, which is simply the fraction of air particles that are from a biological origin. Exposure to poor air quality is a major global driver of poor health, killing 1 in 8 people. Pollen is probably the best known example of a bioaerosol, which as an allogen, has a direct impact on public health. However, live bacteria, fungi, and viruses in the air pose a significant health risk through infectious respiratory diseases such as Legionellosis and Aspergillosis. The negative public health risks in themselves makes research into bioaerosols worthwhile. However, bioaerosols also play central roles in the life cycles of microorganisms, global ecology, and climate patterns. Analysis of bioaerosols at landscape scales has shown that even marine and terrestrial environments are connected over vast distances by exchange of bioaerosols. Indeed, it is well known that bioaerosols can be transported between continents on 'microbial motorways' in the sky (e.g. Saharan dust). Further to this, bioaerosols influence the climate by acting as nucleation forming particles and promoting precipitation. Due to the vast distances involved it is not possible to get the full picture from studies carried out at a local or national level, instead a global perspective is required to study these processes. A major recent methodological advancement in microbial ecology is the application of 'next generation sequencing' technology. Isolation of DNA from the environment and its analysis with high throughput sequencing has been a key tool in revolutionizing our understanding of the ecology of microbes from soil and water environments. Due to the lower concentrations of microorganisms in air samples this is technically challenging for bioaerosols. Consequently molecular methods are underutilised in bioaerosols research. Nevertheless a number of research groups across the globe have developed methods for molecular (DNA based) analysis of bioaerosols. However, a lack of standardisation between these methods makes it challenging to compare results and draw conclusions from combined datasets. This new network brings these experts together for the first time in order to standardise and further improve these methods. However, a key objective of this network is to make these methods more widely available. The largest burden of air pollution is in lower and middle income countries, where access to advanced molecular methods is limited. Through the network, researchers in lower and middle income countries can access these tools, pushing research forward where the need is greatest.