The number of applications the Powder Diffraction beamline receives each round always exceeds the amount able to be accepted. For your proposal to be competitive, it is important to follow the guidelines below.
✅ General Hints
Understand what you want to measure and what you want to obtain from the data.
Prepare proposals early to allow enough time to complete it properly, and to also have time to make enquiries, and receive a response.
Students cannot be the principal investigator on a proposal.
Take care to describe the synchrotron-relevant aspects of your experiment and describe them in sufficient detail.
Consider the skills needed to successfully carry out the experiment. If you do not know how to process the data is there someone you could collaborate with?
Plan your experiment so you maximise your beamtime. We recommend preparing your samples before your arrival.
🛠 Technical Feasibility
Proposals will be initially assessed by the beamline staff for technical feasibility. It is highly recommended to confirm the feasibility of your proposal before submitting. Typical reasons why proposals are marked unfeasible include:
Safety procedures are not adequately described – All experiments need to be carried out in a safe manner at all times. It is extremely important that the researchers have considered strategies to minimise hazard exposure as well as not damage our equipment. For example, consider what will happen if there is a spill? Experiments with radioactive materials should consider secondary containment.
Sample composition – Sometimes based on the composition of your sample, an energy that avoids absorption edges and minimises micro-absorption (from high Z elements) cannot be selected. The energy range of the PD beamline is 8-22 keV. Please talk to a Beamline Scientist to check.
Insufficient or confusing information – The experiment is not explained in enough detail, or is not explained clearly, therefore we are unsure what you want to do and what resources you need.
Researchers haven’t discussed the experiment with beamline staff prior to proposal submission –This is mandatory for non-standard setups (i.e. radioactive flow through experiments) and if you are bringing your own sample environment/equipment as we need to know that it will work on the beamline. Also, this is mandatory for all experiments using flammable gases or those needing a pressure higher than atmospheric.
Generation of toxic gases – The beamline currently does not have an extraction system in the hutch to remove toxic gases such as CO or H2S. Proposals cannot be accepted if toxic gases will be generated.
📝 Writing the Proposal
All proposals will be evaluated by external reviewers and members of the Proposal Advisory Committee (PAC). There are three evaluation categories to consider when preparing proposals with reference to the evaluation categories:
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Further details to address these criteria are below
Tips on completing the proposal
Scientific relevance and merit – Ensure that reviewers can easily determine the scientific value of the synchrotron experiment you are seeking to undertake and how it will contribute to the relevant field of research or application.
National benefit and applications of the proposed research – It is extremely important to demonstrate why this research is important to Australia and what are potential long term outcomes for the nation. Does your research align with an Australian Government Science and Research Priority? The application of this work needs to be described and how it will contribute to advancing Australia’s scientific knowledge. One sentence is not enough for this section. Also, include where you plan to publish your synchrotron data? If you are an international researcher, the opportunity to collaborate is considered a national benefit to Australia so please include this.
Track record of applicants, particularly publications resulting from prior Australian Synchrotron beamtime – It is now necessary to upload prior publication(s) resulting from use of ANSTO facilities to the online proposal system. This listing will be used to evaluate the likelihood of a publication arising from the proposed experiment, based on previous history. For new users, their publication history and laboratory experience will be evaluated. For all researchers, include their title, institution, research interests, their number of publications, powder diffraction workshops and conferences attended, and describe their powder diffraction expertise in the laboratory and at synchrotron facilities. Include what each participant will contribute to the experiment, and detail who has expertise in the materials used, and who has expertise in diffraction data analysis. Be aware that a track record of conducting experiments at the Australian Synchrotron without subsequent publication or explanation will not be well regarded. This is particularly true if time has been awarded twice or more.
Need for synchrotron radiation – This aspect is a valuable tool in gauging whether it is understood what a synchrotron experiment will contribute to the research. There are many reasons why a synchrotron experiment is sought and may include: the properties of the radiation, the time scale of the experiment, the resolution of the data, the experiment set-up that is achievable, etc. Application need to show proof of concept of why the experiment cannot be carried out in the laboratory. All proposals should contain laboratory powder diffraction data with areas of interest highlighted and easily visible. Also, if the beamtime proposal relates to ‘nano-sized’ crystallites, representative laboratory data MUST accompany the proposal to demonstrate the sample has sufficient long-range order. Data from other techniques can also be included if it will assist in assessing the feasibility of the experiment.
⚗ Tips on completing the 'proposed experiment' section
Details of a typical experiment need to be described. Sufficient detail needs to be included for the proposal to be accurately assessed. When submitting proposals, users should take care to address the following experimental and technical aspects:
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