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Arsenic Technologies for Drinking and Industrial Water Treatment

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Graham Gagnon. Ken Reimer. Chris Le. William Mohn. William Cullen. 2. Overall Goal. This project will address the development and potential commercialization of ... – PowerPoint PPT presentation

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Title: Arsenic Technologies for Drinking and Industrial Water Treatment


1
Arsenic Technologies for Drinking and Industrial
Water Treatment
Project Team Graham Gagnon Ken Reimer Chris
Le William Mohn William Cullen
  • November 24, 2005
  • Kananaskis Researcher Retreat

2
Overall Goal
  • This project will address the development and
    potential commercialization of innovative
    chemical and biological arsenic treatment
    technologies.
  • End-users
  • Rural communities for drinking water
  • Mining industry

3
Research Team
  • Key Participants

4
Key Challenges/Goals
  • 1. Development of innovative chemical treatment
    technologies to remove arsenic from water
  • 2. Advancement of the understanding of
    biological treatment systems in order to provide
    recommendations for optimization
  • 3. Advancement and applicability of analytical
    speciation methods for arsenic in liquids and
    solids.
  • (a) Field speciation of arsenate and
    arsenite that can be translated to the water
    industry
  • 4. Characterization of the environmental fate of
    the resulting sludge and recommendations for
    disposal

5
Relevant State-of-The-Research
  • Drinking Water Treatment
  • Several new adsorbents have been developed for
    use in arsenic adsorption systems (i.e., GFH, AA,
    greensand)
  • The goal is to develop and evaluate a new
    adsorbent mediasuitable for small-scale arsenic
    treatment
  • Wastewater Treatment
  • Developing a molecular understanding of
    biological treatment process in Trail, BC
  • This will enable future method development work
    with PCR and enable the removal technology to be
    more robust

6
Approach
  • Combination of bench- and field-scale trials
  • Field-scale bioreactor optimization
  • Microbial analysis with molecular techniques
  • As speciation and detection
  • Bench-scale adsorprtion
  • Rapid small-scale column tests (RSSCTs)
  • XRF, SEM autopsy analysis

7
Stage of Research
  • Drinking Water Treatment
  • Project has been commenced and initial batch
    adsorption results are promising
  • Student recruitment has been completed
  • Laboratory methods have been developed and
    analytical methods development is in progress
  • Wastewater Treatment
  • Optimized DNA extraction and PCR amplification of
    DNA from biomass samples from pilot-scale
    bioreactor in Trail. BC.
  • Identified that the bacterial community varies in
    a gradient from bottom to top of the reactor.

8
Key Findings/Observations
  • Drinking Water Treatment
  • Preliminary results show that the adsorptive
    media (WTRS) is capable of removing As (III) -
    usually very challenging without an oxidation
    step
  • RSSCTs will compare arsenic adsorption between
    new and established materials
  • Key questions
  • Suitability of adobent material as a drinking
    water treatment material?
  • Chemistry of adsorption process?
  • Will the residuals from this treatment process be
    classified as hazardous waste?

9
Key Findings/Observations
  • Wastewater Treatment
  • Using universal bacterial primers for our
    microbiasl analysis, which could ultimately
    identify populations of interest that would be
    worth monitoring with Q-PCR
  • Poised to compare bacterial communities in
    further samples from pilot- and lab-scale
    systems, to evaluate correspondence between
    bacterial populations and arsenic transformations
    and to identify key bacterial populations.
  • Aim to use cultures (and ultimately primers) to
    develop a drinking water biofiltration system

10
Insights on Knowledge Transfer
  • At this point KT is occurring within the group
  • As biofiltration
  • As monitoring systems
  • The adsorption media will require thorough
    testing before being marketed to potential
    commercial partners

11
Opportunities
  • Identification of locations with high groundwater
    arsenic concentrations is on-going
  • Sources for real test water, possible locations
    for pilot testing
  • Opportunity for education of rural residents
    about arsenic contamination
  • Widely untested in rural and decentralized
    communities

12
Collaborative Interests
  • Goal would be to be tap into public health
    particularly small-scale systems where arsenic
    may a non-quantified contaminant
  • At International level this is of significant
    importance and the team is very interested in
    playing a larger role
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