This proposal (Bleeker, 2004) aims to provide a comprehensive and multiparameter knowledge base of the complete record of mafic magmatism in and around Canada, and through international collaborations, around the world.

A complete record of mafic magmatism through time and space (spatial distribution, ages, periodicities, rates, volume estimates, estimated geochemical fluxes to atmosphere and hydrosphere, tectonic settings, sequence stratigraphic framework, structural trends, evolving major and trace element compositions, evolving isotopic ratios, paleomagnetic information, paleo-intensities, associated ore deposits, etc.) provides critical constraints on numerous first-order questions about the past and present evolution of our planet. ("Mafic magmatism" is used as a shorthand here, meaning to include all mantle-derived magmatic activity other than steady-state arc magmatism, i.e., all basalt (± komatiite)-dominated and (or) bimodal magmatism associated with divergent margins, or more generally extensional regimes, intraplate magmatic provinces, mantle plumes, anorogenic provinces, kimberlite and alkaline provinces; i.e., products of mantle processes other than steady-state subduction.) Many of such questions relate directly or indirectly to issues that are currently a focus of attention: global change, past climate extremes, complex Earth systems, geochemical fluxes, planetary evolution, geodynamics, core and mantle evolution, the geodynamo, mantle plumes, flood volcanism, extinction events, potential relationships with large impacts, and discovery of new strategic mineral resources.

At its core, the proposed project would have a large dating program, aiming to provide ca. 200-300 new high-precision ages of mafic magmatic events across Canada, adjacent regions, and landmasses suspected of being formerly connected to Canada and North America. As more precise and accurate ages are critical to virually every geoscientific question, this project should not only focus on just new dates but also on the development and application of new dating methods, e.g., accurate and precise dating of very young events, and the dating of associated sedimentary rocks. Canada has several well-regarded TIMS and LA-ICPMS labs, and one SHRIMP lab (at the Geological Survey of Canada) that could be fully engaged in this activity.

A Supporting Geoscience grant system, perhaps modeled on that of LITHOPROBE, will ensure that other aspects of the magmatic record receive equal attention (e.g., sequence stratigraphy, paleomagnetism, geochemistry, paleo-intensity studies, geophysical and geodynamic studies). Together, these data would trigger a quantum leap advance in paleogeographic reconstructions and, thus, in the understanding of the first-order rhythm of Earth evolution— the supercontinent cycle through time.

At a modest cost and building on many of our traditional strengths, from geochronology to geodynamics, and from igneous petrology and isotope geochemistry to Precambrian geology, this project could provide a central theme for the Solid Earth Sciences. Key innovations would be the scale and scope of investigations, integrating data from a large number of disciplines and around the globe into a holistic model of Earth evolution. The project would be timely in making optimum use of the next generation of analytical equipment now being acquired through CFI and other programs at various earth science departments across Canada. More so than LITHOPROBE, this project would look into the mantle and even the core, while trying to relate surface processes (e.g., basin development, geochemical signals, extinctions, etc.) to mantle-driven tectonic rhythms. There are clear synergies between this proposed project for the traditional continental realm and some of the other projects summarized below (e.g., the Sudbury deep hole, POLARIS, IODP, NEPTUNE, planetary science).

An initiative is underway to launch a major new project in the Sudbury area, to be carried out by a partnership of academic, industry, and government researchers. The goal of the project is to develop a holistic understanding of the formation and modification of one of Earth's largest impact basins, its differentiated melt sheet, and the associated mineral deposits (Therriault et al., 2002). A focus of the project will be a ca. 6-km-deep drillhole and associated multi-disciplinary probing studies, funded in part by the International Continental Scientific Drilling Program (ICDP). The project group, called the Sudbury Integrated Geoscience Network (SIGNet), is being coordinated by James Mungall of the University of Toronto, and is currently preparing funding requests to NSERC, CFI, and ICDP. The primary product will be a state-of-the-art 3D model of the Sudbury Structure and its environs, containing data on composition, structure, age, mineral assemblages, and texture from within and around the Sudbury Basin. Secondary products will be detailed models of heat flow, impact crater dynamics, magma chamber dynamics, hydrothermal fluid flow, tectonic modification, and contemporary fluxes of heat and fluid flow within the Sudbury Structure.

POLARIS (Portable Observatories for Lithospheric Analysis and Research Investigating Seismicity) is a national research consortium using various geophysical instrument deployments (seismic, GPS and MT) to address longstanding geoscientific problems. POLARIS has a broad geographical base and has active participation and steering committee representation from six universities, two offices of the Geological Survey of Canada, and the power-generation and diamond-exploration industries. Currently, 71 observatories are deployed on the Slave craton, atop the Cascadia subduction zone around Vancouver Island, and across the Grenville orogen and Superior craton. Installation of the initial POLARIS infrastructure, including field instruments and two satellite communication hubs, has been completed, and additions will be made over time from new funding sources.

Funding for POLARIS has been obtained from different sources. The first 4-year phase of the consortium (2001-2005) has been funded through CFI, with matching provincial contributions from Ontario and British Columbia and substantial industry support. Through its Major Facilities Access program, NSERC is providing partial support for operations over the next two years. The Ontario Research and Development Challenge Fund has provided bridge funding for four new faculty positions at Ontario universities. Natural Resources Canada, the province of British Columbia and industry are also providing substantial support for the project.

Over the next few years the original scientific goals will be met. Episodic Tremor and Slip (ETS) on the Cascadia subduction zone beneath Vancouver Island is recorded by monitoring both small transient changes in surface displacements using continuous GPS measurements and the occurrence of distinct, non-earthquake-like tremors that accompany the transient displacements. These displacements and tremors occur surprisingly regularly beneath southern Vancouver Island and are thought to reflect the repeated relief of stress on the deep subducting plate interface. Seismometers in the southwestern B.C. POLARIS transect help to locate tremor sources with greater precision than previously possible. Eruptions of diamond-bearing kimberlite volcanoes 50-100 million years ago, in a region 250 km north of Yellowknife, originated at 200-500 km depths and plucked diamonds and other rock fragments out of the mantle during their ascent. These eruptions are thought to rise first as vertical sheets of magma, before separating into individual pipes. Precise age dating of clusters of eruptions, and structural fabric orientations derived from new seismic anisotropy estimates from POLARIS observatories, now substantiate these eruptive models and suggest that such eruptions may be triggered by changes in North American plate motion (e.g., Snyder et al., 2004). The third POLARIS array, located in southern Ontario, has resulted in more accurate "shake maps" that document the small magnitude (M<4) earthquakes that have been recorded by the enlarged array of sensors, but also provide better predictive tools for potentially larger earthquakes in this most densely populated part of Canada (Atkinson and Sonley, 2003).

Responses to the first request for proposals to redeploy the observatories, as described on the POLARIS website (www.polarisnet.ca) are being evaluated. Some observatories are expected to follow the similar USArray studies south of the border as they move from west to east across the continent.

Canada's marine territory includes accessible natural laboratories for significantly advancing our understanding of:

• Earth processes associated with the creation and destruction of lithospheric plates;

• sedimentary basins and their mineral deposits that form at, or close to, plate margins;

• earthquake risk evaluation at the active plate margin on Canada's west coast;

• hydrocarbon potential and hazards posed by gas hydrates at shallow depth below the seabed along the continental edges; and

• paleoclimate and climate dynamics, derived from proxy data from ocean sediments.

These are substantial issues of science and economics, derivative from a huge area of Canadian territory. Canada's offshore, if we include the Great Lakes, is two-thirds the size of its landmass. Canada has the world's longest coastline. Our marine activities account for 5% of GDP. It is arguable that the provisions of Article 76 of the United Nations Convention of the Law of the Sea (UNCLOS) could permit Canada to extend seabed jurisdiction over additional regions of the Atlantic and Arctic Oceans equalling the area of the three prairie provinces.

Canadian marine geoscientists— distributed among academia and government— are addressing all the research themes listed, but with enhanced resources so much more momentum could be built. The total amount of ship time funding distributed by NSERC for all Canadian marine sciences is in the ball park of $3 million per year, enough for around 300 days (varies widely depending on vessel size, etc.). Recent investments by CFI have added strength to our research vessel fleet, including icebreaking capability for work in the Arctic and new capabilities for the remotely operated vehicle ROPOS. Active experiments conducted from ships are a vital part of marine research, and Canadians are now using international collaborations to access resources needed to pursue research on (i) Earth system interactions, involving exchanges between oceans and atmosphere, and oceans and lithosphere, with implications for climate change; (ii) subduction zone structure and gas hydrates on the west coast; and (iii) the development of rifted margins and their sedimentary basins on the east coast.

Recently, the value of continuous recording of long time series of various ocean and seafloor characteristics has been recognised in awards from CFI for seabed observatories (Bonne Bay, Newfoundland; VENUS, in the Straits of Georgia; NEPTUNE, covering the whole of the Juan de Fuca plate, see below). New technologies drive innovation, and we can expect new discoveries from the operations of such seafloor observatories and the wider development of seabed imaging technologies (some of which may be funded to assist Canada's development of sovereignty under UNCLOS).

The NEPTUNE project will lay a 3,000 km network of powered fibre optic cable on the seabed over the Juan de Fuca tectonic plate, a 200,000 km² region in the northeast Pacific off the coasts of British Columbia, Washington and Oregon. This tectonic plate is the smallest of the dozen major plates that make up the planet's surface and through NEPTUNE offers real-time observations on a full range of Earth and ocean processes. The NEPTUNE cable network will feature 30 or more seafloor "laboratories," or nodes, spaced about 100 km apart. From these nodes, land-based scientists will control and monitor sampling instruments, video cameras and remotely operated vehicles as they collect data from the ocean surface to below the seafloor. Instruments will be interactive - scientists will instruct them to respond to events such as storms, plankton blooms, fish migrations, earthquakes, tsunamis, and underwater volcanic eruptions, as they happen.

In October 2003, full Canadian funding of $62.4 million for NEPTUNE Canada was awarded by CFI ($31.9M) and the British Columbia Knowledge Development Fund ($30.5M) to the University of Victoria (UVic), which leads a consortium of 12 Canadian universities from coast to coast. The United States will provide the other 70% of the NEPTUNE facility budget. Core staff based at UVic are being recruited, others under contract will be based elsewhere. NEPTUNE Canada funding includes a total of $13 million for an initial suite of observing systems to support the proposed Canadian research. These will be chosen through a new process involving competitive, peer-reviewed proposals, which are currently being evaluated. A report, describing recent workshops to review community experiments and propose specific systems and sites, is available on the web (www.neptunecanada.ca). UVic and NSF staff are developing a Memorandum of Understanding. NEPTUNE Canada is particularly interested in developing partnerships, including those with industry, which can attract additional funding and/or in-kind support.

Thus, with the receipt of funding for NEPTUNE Canada, a range of activities will occur over the next year: the NEPTUNE Canada office will be staffed; science workshops will consider the precise location of the observatory nodes, the detailed science experiments, sensor packages, and the needs for sensor/vehicle development; initial work on the location of a shore station, concurrent with the issuance of Requests for Qualifications and Proposals for the "wet plant" (cable/nodes); learning from the ongoing developments in the VENUS (www.venus.uvic.ca) and MARS test beds; and the initial design of the Data Management and Archive System. All of these require considerable dialogue with the scientific, engineering and local communities and with funding agencies, partners and industry.

The Integrated Ocean Drilling Program (IODP) is a multi-year, multidisciplinary international program aimed at understanding the Earth systems that make up our planet. IODP is the advanced successor to the Deep Sea Drilling Project and the Ocean Drilling Program, funded by the US, Japan, and a European consortium (ECORD), which includes 14 European nations and Canada. IODP differs from its predecessors in that it will identify and support whatever type of drilling platform is required to best address highly ranked scientific questions. Platforms include an improved version of ODP's JOIDES Resolution ; a riser-equipped drill-ship, under construction in Japan, with the ability to reach targets in deep water, on continental margins, and gas-prone regions; and mission-specific platforms such as jack-up rigs and ice-breakers.

Within the three broad IODP science themes of the Deep Biosphere, Environmental Change, and Solid Earth Cycles, the topics of particular interest to Canadian researchers include: climate dynamics; gas hydrates; seismogenic zones and seismic hazards; sedimentary basin formation; the deep biosphere and biotechnology; formation and evolution of the oceanic lithosphere; hydrothermal ore deposits; and mantle dynamics, the origin of mantle plumes and the formation of large igneous provinces. IODP will play a key role in observatory projects such as NEPTUNE, and has strong links with the International Continental Scientific Drilling Program.

In the first year of operations (June 2004– April 2005), IODP will recover critical cores for understanding global climate change from the Arctic (Eocene to present) and North Atlantic (Late Neogene-Quaternary), establish bore hole observatories in the Juan de Fuca plate to monitor plate-scale deformation, earthquakes and fluid flow, and examine the formation of oceanic core complexes. More information for these and future expeditions can be found on the ECORD website:(http://www.ecord.org/).

The current status and future plans for Canadian participation in IODP are as follows: Canada has recently joined IODP, in partnership with the European consortium. Our participation is currently limited to one year (2004/2005) and is funded through the NSERC– MFA program. Our contribution to IODP ($200,000) is modest, representing ~2 % of ECORD's participation fee. At this time there is no clear path to obtain longer term stable funding for participation in IODP. NSERC has stipulated that future proposals must show broader financial commitment from the community (e.g., government agencies, universities). Toward this end, the Canadian Consortium for Ocean Drilling (CCOD) has been established to facilitate participation in IODP and planning for long-term, stable funding. Membership in the CCOD is open to all Canadian universities, government agencies and industry groups with a commitment to Canada's participation in the IODP. More information about IODP or the CCOD is available from the Canadian IODP secretariat at the University of Victoria: CanIODP@uvic.ca.

Canada has a small but diverse group of planetary scientists with expertise in meteoritics, impact processes, small bodies, planetary geology and astrobiology (www.unb.ca/passc/CSSC/index.html). The CSA supports and helps coordinate much of the planetary research. The CSA is a federal organization with a mandate to promote the use and development of space to meet Canada's social and economic needs. To achieve its goals, the CSA cooperates with other government departments, industries, universities, and international partners, particularly the United States National Aeronautics and Space Administration and the European Space Agency.

A dialogue is needed between planetary and earth scientists to determine how best to develop common research partnerships. One area with outstanding potential is Mars exploration, including preparation for a Mars sample return, a major focus of Canada's Space Plan. With tremendous ongoing international interest in Mars, fuelled by current and planned missions to the planet over the next decade, Canada's planetary science community has a wonderful opportunity to carve out a distinctly Canadian agenda for Mars research. The earth science community in Canada can help develop the Mars research agenda by bringing particular expertise to targeted areas of study. Developing these linkages is timely from a programmatic standpoint in that the funding of the planetary and solid earth science programs at NSERC will soon be administered by a common grant selection committee.

Perhaps the most fundamental Mars-related research question is whether, and if so when and how, life developed on the red planet. The same "when-and-how" questions remain unanswered for life on Earth, providing a common focus for study of the two planets. The answers to questions about early life on Earth are preserved in the oldest rocks, and Canadian earth scientists include some of the world's best Archean geologists and laboratories equipped to study Archean rocks. Mineralogical, chemical and isotopic fingerprinting of primitive biogenic activity on Earth could be developed in Canadian laboratories, and applied to early Archean rocks that have been well-mapped and described by Canadian geologists. Canada's geology includes some locations distinctly suited for such studies including the recently discovered Nuvvuagittuq sequence exposed in a relatively continuous outcrop on the east shore of Hudson Bay. Field tests of primitive biogenic signatures could also be undertaken in Canada's Far North, such as Devon Island, where the combination of cold and aridity mimics Mars-like conditions. This could build on existing, international bio-geologic research programs such as the NASA Haughton-Mars Project (www.marson-earth.org).

Canadian expertise in meteorite research, impact processes and robotics technology is related directly to early life questions. Meteorites derived from Mars and small bodies in the solar system may preserve distinctive biochemical signatures of early life. Impact events may initiate subsurface hydrothermal cycling necessary for critical biogenic processes. Development of a new generation of miniaturized instrumentation for chemical analysis and geochronology by robotic vehicles will be critical to the success of future missions to Mars.