Session II: Environmental Modelling

1. Modelling Training School • Lecture • General Modelling • 2. Application to Nanomaterials • 3. Group Work • Interactive session • 1. Modelling software • 2. Data Manipulation • 3. Model 1: Kinetic • 4. Model 2: Material flow Session II: Environmental Modelling Fate and behaviour of nanoparticles in air, soil, sediment and water Niall O‘Brien NanoImpactNet - QNANO Conference, Modelling Training School, 1 March 2012

2. Lecture • General Modelling • 2. Application to Nanomaterials • 3. Group Work • Interactive session • 1. Modelling software • 2. Data Manipulation • 3. Model 1: Kinetic • 4. Model 2: Material flow Part 1: General Modelling Niall O‘Brien NanoImpactNet - QNANO Conference, Modelling Training School, 1 March 2012

3. What are we modelling? THE Environment Vs AN Environment • Lecture • General Modelling • 2. Application to Nanomaterials • 3. Group Work • Interactive session • 1. Modelling software • 2. Data Manipulation • 3. Model 1: Kinetic • 4. Model 2: Material flow a b c • Gottschalk et al. 2010 • O’Brien and Cummins 2011 • Arvidsson et al. 2011 Niall O‘Brien NanoImpactNet - QNANO Conference, Modelling Training School, 1 March 2012

4. Modelling parameters • Knowns • Material characteristics, environmental characteristics • Unknowns • Transformation, etc. • Simplify • Limited pathways: all reasonably foreseeable pathways, (non-) negligible quantities • Data available? Easily measureable? • Lecture • General Modelling • 2. Application to Nanomaterials • 3. Group Work • Interactive session • 1. Modelling software • 2. Data Manipulation • 3. Model 1: Kinetic • 4. Model 2: Material flow Niall O‘Brien NanoImpactNet - QNANO Conference, Modelling Training School, 1 March 2012

5. Exposure scenarios • All reasonably foreseeable scenarios • Conservative? • Realistic? • Lecture • General Modelling • 2. Application to Nanomaterials • 3. Group Work • Interactive session • 1. Modelling software • 2. Data Manipulation • 3. Model 1: Kinetic • 4. Model 2: Material flow Niall O‘Brien NanoImpactNet - QNANO Conference, Modelling Training School, 1 March 2012

6. Assumptions • Assumptions are a key element in managing uncertainty in modelling processes • Employ ‘best available data’ and logical assumptions • Consider available data • Choose best available solution • Consider actions to validate assumption (reduce uncertainty) • Simplify exposure process to pathways and processes of most influence • Formulate behavioural hypotheses, from available data, in order to predict environmental behaviour and subsequent exposure • Lecture • General Modelling • 2. Application to Nanomaterials • 3. Group Work • Interactive session • 1. Modelling software • 2. Data Manipulation • 3. Model 1: Kinetic • 4. Model 2: Material flow Niall O‘Brien NanoImpactNet - QNANO Conference, Modelling Training School, 1 March 2012

7. Variability • Variability, a effect of chance and a function of a system • Not reducible through either study or further measurement, but may be reduced by changing the physical system • May be managed within an exposure model though a number of methods: • Including data as distributions that describe a factor or function (as best measurement allows) • Modelling scenarios or systems for a number of iterations • Lecture • General Modelling • 2. Application to Nanomaterials • 3. Group Work • Interactive session • 1. Modelling software • 2. Data Manipulation • 3. Model 1: Kinetic • 4. Model 2: Material flow Niall O‘Brien NanoImpactNet - QNANO Conference, Modelling Training School, 1 March 2012

8. Uncertainty • Uncertainty, a measure of our lack of knowledge about the parameters of a system, is an essentially subjective component • Sometimes reducible through further measurement or study (or by consulting more experts) • May be managed within an exposure model though a number of methods : • Logical assessment of the information contained in available data • Assumptions and generalisations (where appropriate) to simplify the system • Use of (appropriate – again subjective) bridging data, adapted with suitable statistical methods • Lecture • General Modelling • 2. Application to Nanomaterials • 3. Group Work • Interactive session • 1. Modelling software • 2. Data Manipulation • 3. Model 1: Kinetic • 4. Model 2: Material flow Niall O‘Brien NanoImpactNet - QNANO Conference, Modelling Training School, 1 March 2012

9. Illustrating variability and uncertainty Figure 1: Binomial distribution Figure 2: Confidence distribution • Keeping variability and uncertainty separate in a model is mathematically more correct • Mixing the two together, i.e. by simulating them together, produces a reasonable estimate of total uncertainty under most conditions • But we cannot then see how much of the total uncertainty comes from variability and how much is from uncertainty • Lecture • General Modelling • 2. Application to Nanomaterials • 3. Group Work • Interactive session • 1. Modelling software • 2. Data Manipulation • 3. Model 1: Kinetic • 4. Model 2: Material flow Niall O‘Brien NanoImpactNet - QNANO Conference, Modelling Training School, 1 March 2012

10. Representation of data • The accuracy and applicability of environmental models is reliant on the quality and responsible use of available data • This data may come from many sources: • Experimental, survey, standard monitoring, historical • Much of this data may be considered a representative, random sample • There are occasions where the observed variability of this data may be applied as a probability distribution in an environmental model • Expert opinion - MCDA • Lecture • General Modelling • 2. Application to Nanomaterials • 3. Group Work • Interactive session • 1. Modelling software • 2. Data Manipulation • 3. Model 1: Kinetic • 4. Model 2: Material flow Niall O‘Brien NanoImpactNet - QNANO Conference, Modelling Training School, 1 March 2012

11. Data quality • Are characteristics used in past/standard environmental models relevant? (not used – not relevant?) • Is parameter independent of others in the model? • Realistic scenarios • Lecture • General Modelling • 2. Application to Nanomaterials • 3. Group Work • Interactive session • 1. Modelling software • 2. Data Manipulation • 3. Model 1: Kinetic • 4. Model 2: Material flow Niall O‘Brien NanoImpactNet - QNANO Conference, Modelling Training School, 1 March 2012

12. Fitting options • First order or second order • Do you need to include uncertainty? (2nd order) • Parametric or non-parametric • Parametric if: • The maths reflects the system being modelled • There is a lot of empirical evidence for a certain distribution • Lots of data, and its convenient • Non-parametric (empirical) if: • Assumption of a specific distribution is not warranted • Thus generally more conservative • Lecture • General Modelling • 2. Application to Nanomaterials • 3. Group Work • Interactive session • 1. Modelling software • 2. Data Manipulation • 3. Model 1: Kinetic • 4. Model 2: Material flow Niall O‘Brien NanoImpactNet - QNANO Conference, Modelling Training School, 1 March 2012

13. Distribution types Frequency distributions - describe variability between individuals Probability distributions - describe randomness Uncertainty distributions - describe our uncertainty about some model parameter • A frequency distribution is used as a probability distribution when we are taking a random sample from a population • We are usually uncertain about the parameters of the frequency and probability distributions, and use uncertainty distributions to describe that uncertainty. • Lecture • General Modelling • 2. Application to Nanomaterials • 3. Group Work • Interactive session • 1. Modelling software • 2. Data Manipulation • 3. Model 1: Kinetic • 4. Model 2: Material flow Niall O‘Brien NanoImpactNet - QNANO Conference, Modelling Training School, 1 March 2012

14. Building the model • Basic stages – Product X fate in WWTP • Model elements: • Fixed (Cnano1 - “nano”-fraction contained within influent) • Variable (Snano – fate/pathway in plant) • Uncertain (Rnanox – removal efficiency) • Lecture • General Modelling • 2. Application to Nanomaterials • 3. Group Work • Interactive session • 1. Modelling software • 2. Data Manipulation • 3. Model 1: Kinetic • 4. Model 2: Material flow Primary treatment Rnano1 Secondary treatment Rnano2 Cnano1 Cnano2 Snano Overflow Rnano3 Niall O‘Brien NanoImpactNet - QNANO Conference, Modelling Training School, 1 March 2012

15. Common modelling errors • Calculating means instead of simulating scenarios • Representing an uncertain variable more than once in a model • Manipulating probability distributions as if they were fixed numbers • Lecture • General Modelling • 2. Application to Nanomaterials • 3. Group Work • Interactive session • 1. Modelling software • 2. Data Manipulation • 3. Model 1: Kinetic • 4. Model 2: Material flow Niall O‘Brien NanoImpactNet - QNANO Conference, Modelling Training School, 1 March 2012

16. Use of simulation • Calculate where possible • More accurate… …but difficult! • Simulate more complex problems • Level of accuracy depends on iterations • Can improve accuracy by mixing calculation and simulation • Have to simulate in second order problems • A mix of the two • Calculate the straightforward parts • Simulate the rest • Lecture • General Modelling • 2. Application to Nanomaterials • 3. Group Work • Interactive session • 1. Modelling software • 2. Data Manipulation • 3. Model 1: Kinetic • 4. Model 2: Material flow Niall O‘Brien NanoImpactNet - QNANO Conference, Modelling Training School, 1 March 2012

17. Simulation methods • Monte Carlo • Random generation of values from probability distributions • Output generated values allow one to calculate approximate expected values of some quantity of interest • Various sampling methods: MC, Latin Hypercube sampling, mid-point LHS • Markov Chain Monte Carlo • Markov chains comprise a number of individuals who begin in certain allowed states of the system and who may or may not randomly change (transition) into other allowed states over time • Lecture • General Modelling • 2. Application to Nanomaterials • 3. Group Work • Interactive session • 1. Modelling software • 2. Data Manipulation • 3. Model 1: Kinetic • 4. Model 2: Material flow Niall O‘Brien NanoImpactNet - QNANO Conference, Modelling Training School, 1 March 2012

18. Interpreting results • Run model/Simulate • Iterations Sample/Iteration 1 Sample/Iteration 2 . . . Sample/Iteration n • Lecture • General Modelling • 2. Application to Nanomaterials • 3. Group Work • Interactive session • 1. Modelling software • 2. Data Manipulation • 3. Model 1: Kinetic • 4. Model 2: Material flow * = 0.38 m2/m3 6.48 mg/m3 58.60 m2/g * = 0.07 m2/m3 1.45 mg/m3 48.78 m2/g * = C m2/m3 A mg/m3 B m2/g Niall O‘Brien NanoImpactNet - QNANO Conference, Modelling Training School, 1 March 2012

19. Interpreting results Output Distribution Regression & Correlation • Lecture • General Modelling • 2. Application to Nanomaterials • 3. Group Work • Interactive session • 1. Modelling software • 2. Data Manipulation • 3. Model 1: Kinetic • 4. Model 2: Material flow Niall O‘Brien NanoImpactNet - QNANO Conference, Modelling Training School, 1 March 2012

20. Applying results • Risk assessment Risk = Exposure X Hazard • Low/no exposure → No risk • Low hazard → No risk But… what if exposure changes → Possible future scenarios • Risk management • Regulation(?) • Definitions (nano-fraction of regulated mat. significant?) • Precautionary principle • Risk-benefit analysis • Relative risk (alternatives/other “traditional” pollutants) • However, exposure models/risk assessments should not be guided by risk management expectations • Lecture • General Modelling • 2. Application to Nanomaterials • 3. Group Work • Interactive session • 1. Modelling software • 2. Data Manipulation • 3. Model 1: Kinetic • 4. Model 2: Material flow Niall O‘Brien NanoImpactNet - QNANO Conference, Modelling Training School, 1 March 2012

21. Lecture • General Modelling • 2. Application to Nanomaterials • 3. Group Work • Interactive session • 1. Modelling software • 2. Data Manipulation • 3. Model 1: Kinetic • 4. Model 2: Material flow Part 2: Application to engineered nanomaterials (ENM) Niall O‘Brien NanoImpactNet - QNANO Conference, Modelling Training School, 1 March 2012

22. Exposure scenario Engineered nanomaterials (ENMs): What is released? • Already present in environment • Macroscale objects representing an incidental source of nps in the environment? (Glover et al. ACS Nano 2011) • Form • Surface bound; suspended in liquid/solid; “free” • Status may (in fact definitely will) change during life cycle • Transformation/aging? • Association with other materials (e.g. colloids, natural organic matter (NOM), cations, etc.), resulting in: • Surface coating • Aggregation/disaggregation • Sorption of contaminants (secondary transport?) • Lecture • General Modelling • 2. Application to Nanomaterials • 3. Group Work • Interactive session • 1. Modelling software • 2. Data Manipulation • 3. Model 1: Kinetic • 4. Model 2: Material flow Niall O‘Brien NanoImpactNet - QNANO Conference, Modelling Training School, 1 March 2012

23. Model boundaries • Defining model environment • Specific research question • Parameters of influence • ENM characteristics • Environ characteristics • Quantitative? Measurable? • Dependencies • First order • Second order • What data do we need? Is it relevant to environment/ENM life cycle stage of interest? “Carbon nanotubes should be shaken not stored” • Lecture • General Modelling • 2. Application to Nanomaterials • 3. Group Work • Interactive session • 1. Modelling software • 2. Data Manipulation • 3. Model 1: Kinetic • 4. Model 2: Material flow Niall O‘Brien NanoImpactNet - QNANO Conference, Modelling Training School, 1 March 2012

24. Model data • Populating model equations • Qualitative/Quantitative influence e.g. O’Brien and Cummins (2010) • Swapping assumptions for likelihood distributions • Subjective vs. objective • No data! Still model… • Bridging data; worst case scenario/precautionary principle • Distributions • Lecture • General Modelling • 2. Application to Nanomaterials • 3. Group Work • Interactive session • 1. Modelling software • 2. Data Manipulation • 3. Model 1: Kinetic • 4. Model 2: Material flow Niall O‘Brien NanoImpactNet - QNANO Conference, Modelling Training School, 1 March 2012

25. Quik et al. 2011 • Different models and frameworks describing the fate and distribution of NMs have been developed: • Incorporating classical knowledge of colloid science • Applying principles used for chemical fate modelling and material flow analysis • Many of the model frameworks available (e.g. Gottschalk et al. (2010a,b)) may prove very valuable once more data become available to populate the probabilistic sub-models included. • Lecture • General Modelling • 2. Application to Nanomaterials • 3. Group Work • Interactive session • 1. Modelling software • 2. Data Manipulation • 3. Model 1: Kinetic • 4. Model 2: Material flow Niall O‘Brien NanoImpactNet - QNANO Conference, Modelling Training School, 1 March 2012

26. Quik et al. 2011 • However, a number of particle-specific fate equations will need to be included to ensure “nano relevance” • Among these are sedimentation, agglomeration, and dissolution; all dynamic, non-equilibrium processes • Future models must therefore focus in kinetics of fate processes • Such a kinetic model for the aquatic environment has been developed based on colloid chemistry principles (Arvidsson et al. 2011)) • Lecture • General Modelling • 2. Application to Nanomaterials • 3. Group Work • Interactive session • 1. Modelling software • 2. Data Manipulation • 3. Model 1: Kinetic • 4. Model 2: Material flow Discussed in more detail later Niall O‘Brien NanoImpactNet - QNANO Conference, Modelling Training School, 1 March 2012

27. Quik et al. 2011 • The main challenge is to use the quantitative knowledge of these processes to turn current models “fit for nano” • Can current water quality models be simply “upgraded” with nano-specific process descriptions? • If NM water column transport can be described sufficiently well by first order kinetics - not difficult • “Just” need to quantify the first order rate constants of the nano-specific processes. • Lecture • General Modelling • 2. Application to Nanomaterials • 3. Group Work • Interactive session • 1. Modelling software • 2. Data Manipulation • 3. Model 1: Kinetic • 4. Model 2: Material flow Niall O‘Brien NanoImpactNet - QNANO Conference, Modelling Training School, 1 March 2012

28. Quik et al. 2011 Sedimentation • Inter particle collision (and aggregation) is second-order in nature • Tend to reduce to pseudo first order as the “amount” of collision capacity in natural waters is expected to remain approximately constant throughout the removal process • Removal of solids from water by sedimentation is entirely first order in relation to the concentration of suspended solids • Therefore, the overall kinetics of water-sediment transport of nanoparticles should be close to first order • “Upgrade” current exposure models of the behaviour of conventional chemicals by simply adding a first order rate constant for transport from water to sediment • Kinetic theory of particle–particle and particle–surface interactions not sufficient to quantitatively predict first order constants, but helps in making order-of-magnitude estimates • Lecture • General Modelling • 2. Application to Nanomaterials • 3. Group Work • Interactive session • 1. Modelling software • 2. Data Manipulation • 3. Model 1: Kinetic • 4. Model 2: Material flow Niall O‘Brien NanoImpactNet - QNANO Conference, Modelling Training School, 1 March 2012

29. Quik et al. 2011 Dissolution • Dissolution may, in principle, be described as a surface controlled process: dM/dt = −kSA • As the rate of dissolution is proportional to the particles' surface area (rather than mass), first order kinetics of dissolution should be expected only when area and mass are proportional • Not the case for NMs • In absence of more adequate data, Quik et al. suggest that using first order kinetics for dissolution of NMs is acceptable, BUT knowledge gap needs to be filled before dissolution can be modelled adequately • First order removal rate constant (measured experimentally) may be used to model removal of nanoparticles from water though dissolution • Lecture • General Modelling • 2. Application to Nanomaterials • 3. Group Work • Interactive session • 1. Modelling software • 2. Data Manipulation • 3. Model 1: Kinetic • 4. Model 2: Material flow Niall O‘Brien NanoImpactNet - QNANO Conference, Modelling Training School, 1 March 2012

30. Quik et al. 2011 • Formulated this way, the challenge of modelling is placed entirely in assigning values to the various rate constants • A weakness fo this approach is that a new removal rate needs to be measured for each individual NM • An advantage is that it provides one single approach to modelling of conventional chemical substances and NMs • This allows quantitative evaluation of the relative importance of the various removal mechanisms, as they act on substances with different properties (e.g. conventional vs. nano-chemicals) in different aquatic environments (e.g. rivers vs. lakes) dC/dt= E−Σk C with Σk = kadv + kvol + kdeg + ksed + kdiss • Lecture • General Modelling • 2. Application to Nanomaterials • 3. Group Work • Interactive session • 1. Modelling software • 2. Data Manipulation • 3. Model 1: Kinetic • 4. Model 2: Material flow Niall O‘Brien NanoImpactNet - QNANO Conference, Modelling Training School, 1 March 2012

31. Arvidsson et al. 2011 • Colloid chemistry kinetic equations describing particle agglomeration and sedimentation applied to the case of titanium dioxide NPs • Limited exposure assessment conducted with particle number concentration as the exposure indicator • Results indicate that sedimentation, shear flows, and settling are of less importance with regard to particle number based predicted environmental concentrations • The inflow of nanoparticles to the water compartment had a significant impact in the model • Collision efficiency (affected by natural organic matter) was shown to greatly affect model output • Lecture • General Modelling • 2. Application to Nanomaterials • 3. Group Work • Interactive session • 1. Modelling software • 2. Data Manipulation • 3. Model 1: Kinetic • 4. Model 2: Material flow Niall O‘Brien NanoImpactNet - QNANO Conference, Modelling Training School, 1 March 2012

32. Gottschalk et al. 2010 • A probabilistic method to compute PECs by means of a stochastic stationary substance/material flow modelling. • Carried out in R • Implemented and validated with ENP TiO2 data in Switzerland • Uncertainties concerning model parameters (e.g. transfer and partitioning coefficients, emission factors) and exposure causal mechanisms (e.g. level of compound production and application) addressed through: • Sensitivity and uncertainty analysis • Monte Carlo simulation • Markov Chain Monte Carlo modelling • Model is basically applicable to any substance with a lack of data concerning environmental fate, exposure, emission and transmission characteristics. • Lecture • General Modelling • 2. Application to Nanomaterials • 3. Group Work • Interactive session • 1. Modelling software • 2. Data Manipulation • 3. Model 1: Kinetic • 4. Model 2: Material flow Niall O‘Brien NanoImpactNet - QNANO Conference, Modelling Training School, 1 March 2012

33. Gottschalk et al. 2010 • Lecture • General Modelling • 2. Application to Nanomaterials • 3. Group Work • Interactive session • 1. Modelling software • 2. Data Manipulation • 3. Model 1: Kinetic • 4. Model 2: Material flow Niall O‘Brien NanoImpactNet - QNANO Conference, Modelling Training School, 1 March 2012

34. Group work 3 products – 3 ENM forms • Suspended in liquid: Paint/coating • Suspended in solids: CNT filler • Surface bound: Antibacterial surface coating • Identify 3 critical exposure points • Identify 3 key questions relating to ENM fate • Discuss strategies/answers to questions posed • Formation of models/model parameters • Lecture • General Modelling • 2. Application to Nanomaterials • 3. Group Work • Interactive session • 1. Modelling software • 2. Data Manipulation • 3. Model 1: Kinetic • 4. Model 2: Material flow Niall O‘Brien NanoImpactNet - QNANO Conference, Modelling Training School, 1 March 2012

35. References A short selection of recent studies relating to ENM environmental fate, behaviour or modelling and modelling reference sources. This area is constantly expanding so it is important check for new studies/data to keep models relevant and applicable. • Arvidsson, R et al. Challenges in Exposure Modeling of Nanoparticles in Aquatic Environments. Hum Ecol Risk Assess. 17, 245–262 (2011). • Blaser, SA et al. Estimation of cumulative aquatic exposure and risk due to silver: Contribution of nano-functionalized plastics and textiles. Sci Total Environ. 390, 396-409 (2008). • Christian, P et al. Nanoparticles: structure, properties, preparation and behaviour in environmental media. Ecotoxicology. 17, 326–343 (2008). • Gottschalk, F et al. 2010. Probabilistic material flow modeling for assessing the environmental exposure to compounds: Methodology and an application to engineered nano-TiO2 particles. Environmental Modelling & Software. 25, 320–332 (2010). • Mueller N, Nowack B. Exposure modeling of engineered nanoparticles in the environment. Environ Sci Technol. 42, 4447–4453 (2009). • O’Brien N, Cummins E. A risk assessment framework for assessing metallic nanomaterials of environmental concern: Aquatic exposure and behaviour. Risk Analysis, DOI: 10.1111/j.1539-6924.2010.01540.x • Tervonen, T et al. Risk-based classification system of nanomaterials. J. Nanopart. Res. 11, 757–766 (2009). • Quik, J et al. How to assess exposure of aquatic organisms to manufacured nanoparticles? Environ Int. 37, 1066-1077 (2011). • Vose, David. Risk Analysis: a quantitative guide (3rd Edition) ISBN 978-0-470-51284-5 • Vose, David. Fitting distributions to data – and why you’re probably doing it wrong. White paper. www.vosesoftware.com • Lecture • General Modelling • 2. Application to Nanomaterials • 3. Group Work • Interactive session • 1. Modelling software • 2. Data Manipulation • 3. Model 1: Kinetic • 4. Model 2: Material flow Niall O‘Brien NanoImpactNet - QNANO Conference, Modelling Training School, 1 March 2012

36. Lecture • General Modelling • 2. Application to Nanomaterials • 3. Group Work • Interactive session • 1. Modelling software • 2. Data Manipulation • 3. Model 1: Kinetic • 4. Model 2: Material flow Interactive Session Niall O‘Brien NanoImpactNet - QNANO Conference, Modelling Training School, 1 March 2012

37. Modelling software Software that allows us to represent the data at hand and recreate desired scenarios Spreadsheets (and VBA) • Number of add-on statistical programs/packages: • @Risk, Crystal Ball, ModelRisk • Easy to pick up • Demonstrate the handling of variable or uncertain data • But, scale badly and limited to 2/3 dimensions • Cannot easily handle the modelling of dynamic systems • Multidimensional problems are more suited to modelling environments such as C++ • Matlab, R, Mathematica and Maple have powerful built-in modelling capabilities that can handle many dimensions • Lecture • General Modelling • 2. Application to Nanomaterials • 3. Group Work • Interactive session • 1. Modelling software • 2. Data Manipulation • 3. Model 1: Kinetic • 4. Model 2: Material flow Niall O‘Brien NanoImpactNet - QNANO Conference, Modelling Training School, 1 March 2012

38. Representing the model system Influence diagrams • A network that shows the relationship between variables • Submodels (lower levels of interaction) within main model • Variables (nodes) represented as graphical objects connected together with arrows (arcs) that show the direction of interaction • Visual, but mathematics and data behind the model are hard to get to • Lecture • General Modelling • 2. Application to Nanomaterials • 3. Group Work • Interactive session • 1. Modelling software • 2. Data Manipulation • 3. Model 1: Kinetic • 4. Model 2: Material flow Volatilisation to air (Kvol) Degradation (Kdeg) Steady-state surface water concentration (Cw) Emission to water body (E) Water body volume (V) Xsc Xsa Xpps Xagg Sedimentation (Ksed) Advection out of system (Kadv) Wnom WpH Kp Niall O‘Brien NanoImpactNet - QNANO Conference, Modelling Training School, 1 March 2012

39. Representing the model system Event trees • Describe a sequence of probalistic events, their probabilities and impacts • Event trees built out of nodes and arcs • Mathematics to combine the probabilities is (relatively) simple and diagram helps ensure the necessary discipline • Lends itself well to probalistic mass flow balancing • Lecture • General Modelling • 2. Application to Nanomaterials • 3. Group Work • Interactive session • 1. Modelling software • 2. Data Manipulation • 3. Model 1: Kinetic • 4. Model 2: Material flow Snapshot from Gottschalk et al. 2010 – Mass flows between environmental compartments for nano-TiO2 Niall O‘Brien NanoImpactNet - QNANO Conference, Modelling Training School, 1 March 2012

40. Representing the model system Discrete event simulation (DES) • DES differs from Monte Carlo simulation in that it models the evolution of a (usually stochastic) system over time • Equations are defined for each model element – its changes, movement and interaction with other model elements • The system is stepped through small time increments and tracks each element throughout • Allows the modelling of extremely complicated systems by defining how elements interact and letting the model simulate what might happen • Lecture • General Modelling • 2. Application to Nanomaterials • 3. Group Work • Interactive session • 1. Modelling software • 2. Data Manipulation • 3. Model 1: Kinetic • 4. Model 2: Material flow Niall O‘Brien NanoImpactNet - QNANO Conference, Modelling Training School, 1 March 2012

41. Data manipulation • Applying distributions to data • Example 1: ENM WWTP removal efficiencies • Data quality check • Parametric (model-based) or non-parametric (empirical) distribution? • First or second order distribution? • Example 2: Ca2+ concentrations in Irish surface waters • Applying a correlation to two variables • Example: pH and Ca2+ • Rank order correlation & Copulas • Correlation coefficient • Guidelines • Lecture • General Modelling • 2. Application to Nanomaterials • 3. Group Work • Interactive session • 1. Modelling software • 2. Data Manipulation • 3. Model 1: Kinetic • 4. Model 2: Material flow Niall O‘Brien NanoImpactNet - QNANO Conference, Modelling Training School, 1 March 2012

42. Material flow analysis Min * Kdeg Kadv Madv Ksed Surface water (Mwat) Sediment (Msed) Example: Water partitioning • Limited model environment • Defined parameters • Defined influences • Handling input data • Uncertainty and variability • Interpreting results • Lecture • General Modelling • 2. Application to Nanomaterials • 3. Group Work • Interactive session • 1. Modelling software • 2. Data Manipulation • 3. Model 1: Kinetic • 4. Model 2: Material flow Niall O‘Brien NanoImpactNet - QNANO Conference, Modelling Training School, 1 March 2012