Your search keyword '"G. Abramowitz"' showing total 60 results

1. An ensemble estimate of Australian soil organic carbon using machine learning and process-based modelling

Author

L. Wang, G. Abramowitz, Y.-P. Wang, A. Pitman, and R. A. Viscarra Rossel

Subjects

Environmental sciences, GE1-350, Geology, QE1-996.5

Abstract

Spatially explicit prediction of soil organic carbon (SOC) serves as a crucial foundation for effective land management strategies aimed at mitigating soil degradation and assessing carbon sequestration potential. Here, using more than 1000 in situ observations, we trained two machine learning models (a random forest model and a k-means coupled with multiple linear regression model) and one process-based model (the vertically resolved MIcrobial-MIneral Carbon Stabilization, MIMICS, model) to predict the SOC stocks of the top 30 cm of soil in Australia. Parameters of MIMICS were optimised for different site groupings using two distinct approaches: plant functional types (MIMICS-PFT) and the most influential environmental factors (MIMICS-ENV). All models showed good performance with respect to SOC predictions, with an R2 value greater than 0.8 during out-of-sample validation, with random forest being the most accurate; moreover, it was found that SOC in forests is more predictable than that in non-forest soils excluding croplands. The performance of continental-scale SOC predictions by MIMICS-ENV is better than that by MIMICS-PFT especially in non-forest soils. Digital maps of terrestrial SOC stocks generated using all of the models showed a similar spatial distribution, with higher values in south-eastern and south-western Australia, but the magnitude of the estimated SOC stocks varied. The mean ensemble estimate of SOC stocks was 30.3 t ha−1, with k-means coupled with multiple linear regression generating the highest estimate (mean SOC stocks of 38.15 t ha−1) and MIMICS-PFT generating the lowest estimate (mean SOC stocks of 24.29 t ha−1). We suggest that enhancing process-based models to incorporate newly identified drivers that significantly influence SOC variation in different environments could be the key to reducing the discrepancies in these estimates. Our findings underscore the considerable uncertainty in SOC estimates derived from different modelling approaches and emphasise the importance of rigorous out-of-sample validation before applying any one approach in Australia.

Published

2024

2. Time Variability Correction of CMIP6 Climate Change Projections

Author

Y. Shao, C. H. Bishop, S. Hobeichi, N. Nishant, G. Abramowitz, and S. Sherwood

Subjects

time variability correction, statistical post‐processing, climate change projection, Physical geography, GB3-5030, Oceanography, GC1-1581

Abstract

Abstract Accurate projections of climate change and associated extreme events under differing emission scenarios are linked to realistic representations of the temporal variability of the atmosphere at a variety of time scales, for example, annual, seasonal, synoptic, and daily. Here a new method is employed to explicitly quantify a model's ability to accurately represent covariance at and between differing time scales. From our global‐scale analysis, on average, raw Coupled Model Intercomparison Project Phase 6 (CMIP6) models misrepresent temporal variances at differing time scales for maximum temperature (tasmax) by a considerable margin, particularly at 183‐, 92‐ and 46‐day time scales. To ameliorate such variability errors, we propose a novel Time Variability Correction (TVC) method that corrects temporal covariances while preserving the essential time‐event sequence of the model simulations. We adopt a model‐as‐truth framework to evaluate the effectiveness of the TVC method under future forcing conditions when applied to daily tasmax simulations from 23 CMIP6 models for 1% of the global grid cells. TVC‐corrected temperatures generally show improved matching of temporal variance and lag correlations in the out‐of‐sample projection period compared to simple mean‐corrected projections. By imparting more realistic temporal‐correlations to model series, TVC is expected to improve the projections of extreme events associated with persistent heat, such as heatwaves. Applying TVC to future temperature projections using actual observations significantly increases the temperature variance in most middle to high latitude land regions in the Northern Hemisphere, while decreasing it in most low to middle latitude land regions, compared to simple mean‐corrected projections.

Published

2024

3. Opening Pandora's box: reducing global circulation model uncertainty in Australian simulations of the carbon cycle

Author

L. Teckentrup, M. G. De Kauwe, G. Abramowitz, A. J. Pitman, A. M. Ukkola, S. Hobeichi, B. François, and B. Smith

Subjects

Science, Geology, QE1-996.5, Dynamic and structural geology, QE500-639.5

Abstract

Climate projections from global circulation models (GCMs), part of the Coupled Model Intercomparison Project 6 (CMIP6), are often employed to study the impact of future climate on ecosystems. However, especially at regional scales, climate projections display large biases in key forcing variables such as temperature and precipitation. These biases have been identified as a major source of uncertainty in carbon cycle projections, hampering predictive capacity. In this study, we open the proverbial Pandora's box and peer under the lid of strategies to tackle climate model ensemble uncertainty. We employ a dynamic global vegetation model (LPJ-GUESS) and force it with raw output from CMIP6 to assess the uncertainty associated with the choice of climate forcing. We then test different methods to either bias-correct or calculate ensemble averages over the original forcing data to reduce the climate-driven uncertainty in the regional projection of the Australian carbon cycle. We find that all bias correction methods reduce the bias of continental averages of steady-state carbon variables. Bias correction can improve model carbon outputs, but carbon pools are insensitive to the type of bias correction method applied for both individual GCMs and the arithmetic ensemble average across all corrected models. None of the bias correction methods consistently improve the change in simulated carbon over time compared to the target dataset, highlighting the need to account for temporal properties in correction or ensemble-averaging methods. Multivariate bias correction methods tend to reduce the uncertainty more than univariate approaches, although the overall magnitude is similar. Even after correcting the bias in the meteorological forcing dataset, the simulated vegetation distribution presents different patterns when different GCMs are used to drive LPJ-GUESS. Additionally, we found that both the weighted ensemble-averaging and random forest approach reduce the bias in total ecosystem carbon to almost zero, clearly outperforming the arithmetic ensemble-averaging method. The random forest approach also produces the results closest to the target dataset for the change in the total carbon pool, seasonal carbon fluxes, emphasizing that machine learning approaches are promising tools for future studies. This highlights that, where possible, an arithmetic ensemble average should be avoided. However, potential target datasets that would facilitate the application of machine learning approaches, i.e., that cover both the spatial and temporal domain required to derive a robust informed ensemble average, are sparse for ecosystem variables.

Published

2023

4. Examining the role of environmental memory in the predictability of carbon and water fluxes across Australian ecosystems

Author

J. Cranko Page, M. G. De Kauwe, G. Abramowitz, J. Cleverly, N. Hinko-Najera, M. J. Hovenden, Y. Liu, A. J. Pitman, and K. Ogle

Subjects

Ecology, QH540-549.5, Life, QH501-531, Geology, QE1-996.5

Abstract

The vegetation's response to climate change is a significant source of uncertainty in future terrestrial biosphere model projections. Constraining climate–carbon cycle feedbacks requires improving our understanding of both the immediate and long-term plant physiological responses to climate. In particular, the timescales and strength of memory effects arising from both extreme events (i.e. droughts and heatwaves) and structural lags in the systems (such as delays between rainfall and peak plant water content or between a precipitation deficit and down-regulation of productivity) have largely been overlooked in the development of terrestrial biosphere models. This is despite the knowledge that plant responses to climatic drivers occur across multiple timescales (seconds to decades), with the impact of climate extremes resonating for many years. Using data from 12 eddy covariance sites, covering two rainfall gradients (256 to 1491 mm yr−1) in Australia, in combination with a hierarchical Bayesian model, we characterised the timescales and magnitude of influence of antecedent drivers on daily net ecosystem exchange (NEE) and latent heat flux (λE). By focussing our analysis on a single continent (and predominately on a single genus), we reduced the degrees of variation between each site, providing a novel chance to explore the unique characteristics that might drive the importance of memory. Model fit varied considerably across sites when modelling NEE, with R2 values of between 0.30 and 0.83. λE was considerably more predictable across sites, with R2 values ranging from 0.56 to 0.93. When considered at a continental scale, both fluxes were more predictable when memory effects (expressed as lagged climate predictors) were included in the model. These memory effects accounted for an average of 17 % of the NEE predictability and 15 % for λE. Consistent with prior studies, the importance of environmental memory in predicting fluxes increased as site water availability declined (ρ=-0.73, p for NEE, ρ=-0.67, p for λE). However, these relationships did not necessarily hold when sites were grouped by vegetation type. We also tested a model of k-means clustering plus regression to confirm the suitability of the Bayesian model for modelling these sites. The k-means approach performed similarly to the Bayesian model in terms of model fit, demonstrating the robustness of the Bayesian framework for exploring the role of environmental memory. Our results underline the importance of capturing memory effects in models used to project future responses to climate change, especially in water-limited ecosystems. Finally, we demonstrate a considerable variation in individual-site predictability, driven to a notable degree by environmental memory, and this should be considered when evaluating model performance across ecosystems.

Published

2022

5. A flux tower dataset tailored for land model evaluation

Author

A. M. Ukkola, G. Abramowitz, and M. G. De Kauwe

Subjects

Environmental sciences, GE1-350, Geology, QE1-996.5

Abstract

Eddy covariance flux towers measure the exchange of water, energy, and carbon fluxes between the land and atmosphere. They have become invaluable for theory development and evaluating land models. However, flux tower data as measured (even after site post-processing) are not directly suitable for land surface modelling due to data gaps in model forcing variables, inappropriate gap-filling, formatting, and varying data quality. Here we present a quality-control and data-formatting pipeline for tower data from FLUXNET2015, La Thuile, and OzFlux syntheses and the resultant 170-site globally distributed flux tower dataset specifically designed for use in land modelling. The dataset underpins the second phase of the Protocol for the Analysis of Land Surface Models (PALS) Land Surface Model Benchmarking Evaluation Project (PLUMBER), an international model intercomparison project encompassing >20 land surface and biosphere models. The dataset is provided in the Assistance for Land-surface Modelling Activities (ALMA) NetCDF format and is CF-NetCDF compliant. For forcing land surface models, the dataset provides fully gap-filled meteorological data that have had periods of low data quality removed. Additional constraints required for land models, such as reference measurement heights, vegetation types, and satellite-based monthly leaf area index estimates, are also included. For model evaluation, the dataset provides estimates of key water, carbon, and energy variables, with the latent and sensible heat fluxes additionally corrected for energy balance closure. The dataset provides a total of 1040 site years covering the period 1992–2018, with individual sites spanning from 1 to 21 years. The dataset is available at http://doi.org/10.25914/5fdb0902607e1 (Ukkola et al., 2021).

Published

2022

6. Robust historical evapotranspiration trends across climate regimes

Author

S. Hobeichi, G. Abramowitz, and J. P. Evans

Subjects

Technology, Environmental technology. Sanitary engineering, TD1-1066, Geography. Anthropology. Recreation, Environmental sciences, GE1-350

Abstract

Evapotranspiration (ET) links the hydrological, energy and carbon cycles on the land surface. Quantifying ET and its spatio-temporal changes is also key to understanding climate extremes such as droughts, heatwaves and flooding. Regional ET estimates require reliable observation-based gridded ET datasets, and while many have been developed using physically based, empirically based and hybrid techniques, their efficacy, and particularly the efficacy of their uncertainty estimates, is difficult to verify. In this work, we extend the methodology used in Hobeichi et al. (2018) to derive two new versions of the Derived Optimal Linear Combination Evapotranspiration (DOLCE) product, with observationally constrained spatio-temporally varying uncertainty estimates, higher spatial resolution, more constituent products and extended temporal coverage (1980–2018). After demonstrating the efficacy of these uncertainty estimates with out-of-sample testing, we derive novel ET climatology clusters for the land surface, based on the magnitude and variability of ET at each location on land. The new clusters include three wet and three dry regimes and provide an approximation of Köppen–Geiger climate classes. The verified uncertainty estimates and extended time period then allow us to examine the robustness of historical trends spatially and in each of these six ET climatology clusters. We find that despite robust decreasing ET trends in some regions these do not correlate with behavioural ET clusters. Each cluster, and the majority of the Earth's surface, shows clear robust increases in ET over the recent historical period. The new datasets DOLCE V2.1 and DOLCE V3 can be used for benchmarking global ET estimates and for examining ET trends respectively.

Published

2021

7. A daily 25 km short-latency rainfall product for data-scarce regions based on the integration of the Global Precipitation Measurement mission rainfall and multiple-satellite soil moisture products

Author

C. Massari, L. Brocca, T. Pellarin, G. Abramowitz, P. Filippucci, L. Ciabatta, V. Maggioni, Y. Kerr, and D. Fernandez Prieto

Subjects

Technology, Environmental technology. Sanitary engineering, TD1-1066, Geography. Anthropology. Recreation, Environmental sciences, GE1-350

Abstract

Rain gauges are unevenly spaced around the world with extremely low gauge density over developing countries. For instance, in some regions in Africa the gauge density is often less than one station per 10 000 km2. The availability of rainfall data provided by gauges is also not always guaranteed in near real time or with a timeliness suited for agricultural and water resource management applications, as gauges are also subject to malfunctions and regulations imposed by national authorities. A potential alternative is satellite-based rainfall estimates, yet comparisons with in situ data suggest they are often not optimal. In this study, we developed a short-latency (i.e. 2–3 d) rainfall product derived from the combination of the Integrated Multi-Satellite Retrievals for GPM (Global Precipitation Measurement) Early Run (IMERG-ER) with multiple-satellite soil-moisture-based rainfall products derived from ASCAT (Advanced Scatterometer), SMOS (Soil Moisture and Ocean Salinity) and SMAP (Soil Moisture Active and Passive) L3 (Level 3) satellite soil moisture (SM) retrievals. We tested the performance of this product over four regions characterized by high-quality ground-based rainfall datasets (India, the conterminous United States, Australia and Europe) and over data-scarce regions in Africa and South America by using triple-collocation (TC) analysis. We found that the integration of satellite SM observations with in situ rainfall observations is very beneficial with improvements of IMERG-ER up to 20 % and 40 % in terms of correlation and error, respectively, and a generalized enhancement in terms of categorical scores with the integrated product often outperforming reanalysis and ground-based long-latency datasets. We also found a relevant overestimation of the rainfall variability of GPM-based products (up to twice the reference value), which was significantly reduced after the integration with satellite soil-moisture-based rainfall estimates. Given the importance of a reliable and readily available rainfall product for water resource management and agricultural applications over data-scarce regions, the developed product can provide a valuable and unique source of rainfall information for these regions.

Published

2020

8. How representative are FLUXNET measurements of surface fluxes during temperature extremes?

Author

S. V. J. van der Horst, A. J. Pitman, M. G. De Kauwe, A. Ukkola, G. Abramowitz, and P. Isaac

Subjects

Ecology, QH540-549.5, Life, QH501-531, Geology, QE1-996.5

Abstract

In response to a warming climate, temperature extremes are changing in many regions of the world. Therefore, understanding how the fluxes of sensible heat, latent heat and net ecosystem exchange respond and contribute to these changes is important. We examined 216 sites from the open access Tier 1 FLUXNET2015 and free fair-use La Thuile data sets, focussing only on observed (non-gap-filled) data periods. We examined the availability of sensible heat, latent heat and net ecosystem exchange observations coincident in time with measured temperature for all temperatures, and separately for the upper and lower tail of the temperature distribution, and expressed this availability as a measurement ratio. We showed that the measurement ratios for both sensible and latent heat fluxes are generally lower (0.79 and 0.73 respectively) than for temperature measurements, and the measurement ratio of net ecosystem exchange measurements are appreciably lower (0.42). However, sites do exist with a high proportion of measured sensible and latent heat fluxes, mostly over the United States, Europe and Australia. Few sites have a high proportion of measured fluxes at the lower tail of the temperature distribution over very cold regions (e.g. Alaska, Russia) or at the upper tail in many warm regions (e.g. Central America and the majority of the Mediterranean region), and many of the world's coldest and hottest regions are not represented in the freely available FLUXNET data at all (e.g. India, the Gulf States, Greenland and Antarctica). However, some sites do provide measured fluxes at extreme temperatures, suggesting an opportunity for the FLUXNET community to share strategies to increase measurement availability at the tails of the temperature distribution. We also highlight a wide discrepancy between the measurement ratios across FLUXNET sites that is not related to the actual temperature or rainfall regimes at the site, which we cannot explain. Our analysis provides guidance to help select eddy covariance sites for researchers interested in understanding and/or modelling responses to temperature extremes.

Published

2019

9. ESD Reviews: Model dependence in multi-model climate ensembles: weighting, sub-selection and out-of-sample testing

Author

G. Abramowitz, N. Herger, E. Gutmann, D. Hammerling, R. Knutti, M. Leduc, R. Lorenz, R. Pincus, and G. A. Schmidt

Subjects

Science, Geology, QE1-996.5, Dynamic and structural geology, QE500-639.5

Abstract

The rationale for using multi-model ensembles in climate change projections and impacts research is often based on the expectation that different models constitute independent estimates; therefore, a range of models allows a better characterisation of the uncertainties in the representation of the climate system than a single model. However, it is known that research groups share literature, ideas for representations of processes, parameterisations, evaluation data sets and even sections of model code. Thus, nominally different models might have similar biases because of similarities in the way they represent a subset of processes, or even be near-duplicates of others, weakening the assumption that they constitute independent estimates. If there are near-replicates of some models, then treating all models equally is likely to bias the inferences made using these ensembles. The challenge is to establish the degree to which this might be true for any given application. While this issue is recognised by many in the community, quantifying and accounting for model dependence in anything other than an ad-hoc way is challenging. Here we present a synthesis of the range of disparate attempts to define, quantify and address model dependence in multi-model climate ensembles in a common conceptual framework, and provide guidance on how users can test the efficacy of approaches that move beyond the equally weighted ensemble. In the upcoming Coupled Model Intercomparison Project phase 6 (CMIP6), several new models that are closely related to existing models are anticipated, as well as large ensembles from some models. We argue that quantitatively accounting for dependence in addition to model performance, and thoroughly testing the effectiveness of the approach used will be key to a sound interpretation of the CMIP ensembles in future scientific studies.

Published

2019

10. Linear Optimal Runoff Aggregate (LORA): a global gridded synthesis runoff product

Author

S. Hobeichi, G. Abramowitz, J. Evans, and H. E. Beck

Subjects

Technology, Environmental technology. Sanitary engineering, TD1-1066, Geography. Anthropology. Recreation, Environmental sciences, GE1-350

Abstract

No synthesized global gridded runoff product, derived from multiple sources, is available, despite such a product being useful for meeting the needs of many global water initiatives. We apply an optimal weighting approach to merge runoff estimates from hydrological models constrained with observational streamflow records. The weighting method is based on the ability of the models to match observed streamflow data while accounting for error covariance between the participating products. To address the lack of observed streamflow for many regions, a dissimilarity method was applied to transfer the weights of the participating products to the ungauged basins from the closest gauged basins using dissimilarity between basins in physiographic and climatic characteristics as a proxy for distance. We perform out-of-sample tests to examine the success of the dissimilarity approach, and we confirm that the weighted product performs better than its 11 constituent products in a range of metrics. Our resulting synthesized global gridded runoff product is available at monthly timescales, and includes time-variant uncertainty, for the period 1980–2012 on a 0.5∘ grid. The synthesized global gridded runoff product broadly agrees with published runoff estimates at many river basins, and represents the seasonal runoff cycle for most of the globe well. The new product, called Linear Optimal Runoff Aggregate (LORA), is a valuable synthesis of existing runoff products and will be freely available for download on https://geonetwork.nci.org.au/geonetwork/srv/eng/catalog.search#/metadata/f9617_9854_8096_5291 (last access: 31 January 2019).

Published

2019

11. Does predictability of fluxes vary between FLUXNET sites?

Author

N. Haughton, G. Abramowitz, M. G. De Kauwe, and A. J. Pitman

Subjects

Ecology, QH540-549.5, Life, QH501-531, Geology, QE1-996.5

Abstract

The FLUXNET dataset contains eddy covariance measurements from across the globe and represents an invaluable estimate of the fluxes of energy, water, and carbon between the land surface and the atmosphere. While there is an expectation that the broad range of site characteristics in FLUXNET result in a diversity of flux behaviour, there has been little exploration of how predictable site behaviour is across the network. Here, 155 datasets with 30 min temporal resolution from the Tier 1 of FLUXNET 2015 were analysed in a first attempt to assess individual site predictability. We defined site uniqueness as the disparity in performance between multiple empirical models trained globally and locally for each site and used this along with the mean performance as measures of predictability. We then tested how strongly uniqueness was determined by various site characteristics, including climatology, vegetation type, and data quality. The strongest determinant of predictability appeared to be that drier sites tended to be more unique. We found very few other clear predictors of uniqueness across different sites, in particular little evidence that flux behaviour was well discretised by vegetation type. Data length and quality also appeared to have little impact on uniqueness. While this result might relate to our definition of uniqueness, we argue that our approach provides a useful basis for site selection in LSM evaluation, and we invite critique and development of the methodology.

Published

2018

12. Derived Optimal Linear Combination Evapotranspiration (DOLCE): a global gridded synthesis ET estimate

Author

S. Hobeichi, G. Abramowitz, J. Evans, and A. Ukkola

Subjects

Technology, Environmental technology. Sanitary engineering, TD1-1066, Geography. Anthropology. Recreation, Environmental sciences, GE1-350

Abstract

Accurate global gridded estimates of evapotranspiration (ET) are key to understanding water and energy budgets, in addition to being required for model evaluation. Several gridded ET products have already been developed which differ in their data requirements, the approaches used to derive them and their estimates, yet it is not clear which provides the most reliable estimates. This paper presents a new global ET dataset and associated uncertainty with monthly temporal resolution for 2000–2009. Six existing gridded ET products are combined using a weighting approach trained by observational datasets from 159 FLUXNET sites. The weighting method is based on a technique that provides an analytically optimal linear combination of ET products compared to site data and accounts for both the performance differences and error covariance between the participating ET products. We examine the performance of the weighting approach in several in-sample and out-of-sample tests that confirm that point-based estimates of flux towers provide information on the grid scale of these products. We also provide evidence that the weighted product performs better than its six constituent ET product members in four common metrics. Uncertainty in the ET estimate is derived by rescaling the spread of participating ET products so that their spread reflects the ability of the weighted mean estimate to match flux tower data. While issues in observational data and any common biases in participating ET datasets are limitations to the success of this approach, future datasets can easily be incorporated and enhance the derived product.

Published

2018

13. Selecting a climate model subset to optimise key ensemble properties

Author

N. Herger, G. Abramowitz, R. Knutti, O. Angélil, K. Lehmann, and B. M. Sanderson

Subjects

Science, Geology, QE1-996.5, Dynamic and structural geology, QE500-639.5

Abstract

End users studying impacts and risks caused by human-induced climate change are often presented with large multi-model ensembles of climate projections whose composition and size are arbitrarily determined. An efficient and versatile method that finds a subset which maintains certain key properties from the full ensemble is needed, but very little work has been done in this area. Therefore, users typically make their own somewhat subjective subset choices and commonly use the equally weighted model mean as a best estimate. However, different climate model simulations cannot necessarily be regarded as independent estimates due to the presence of duplicated code and shared development history. Here, we present an efficient and flexible tool that makes better use of the ensemble as a whole by finding a subset with improved mean performance compared to the multi-model mean while at the same time maintaining the spread and addressing the problem of model interdependence. Out-of-sample skill and reliability are demonstrated using model-as-truth experiments. This approach is illustrated with one set of optimisation criteria but we also highlight the flexibility of cost functions, depending on the focus of different users. The technique is useful for a range of applications that, for example, minimise present-day bias to obtain an accurate ensemble mean, reduce dependence in ensemble spread, maximise future spread, ensure good performance of individual models in an ensemble, reduce the ensemble size while maintaining important ensemble characteristics, or optimise several of these at the same time. As in any calibration exercise, the final ensemble is sensitive to the metric, observational product, and pre-processing steps used.

Published

2018

14. On the predictability of land surface fluxes from meteorological variables

Author

N. Haughton, G. Abramowitz, and A. J. Pitman

Subjects

Geology, QE1-996.5

Abstract

Previous research has shown that land surface models (LSMs) are performing poorly when compared with relatively simple empirical models over a wide range of metrics and environments. Atmospheric driving data appear to provide information about land surface fluxes that LSMs are not fully utilising. Here, we further quantify the information available in the meteorological forcing data that are used by LSMs for predicting land surface fluxes, by interrogating FLUXNET data, and extending the benchmarking methodology used in previous experiments. We show that substantial performance improvement is possible for empirical models using meteorological data alone, with no explicit vegetation or soil properties, thus setting lower bounds on a priori expectations on LSM performance. The process also identifies key meteorological variables that provide predictive power. We provide an ensemble of empirical benchmarks that are simple to reproduce and provide a range of behaviours and predictive performance, acting as a baseline benchmark set for future studies. We reanalyse previously published LSM simulations and show that there is more diversity between LSMs than previously indicated, although it remains unclear why LSMs are broadly performing so much worse than simple empirical models.

Published

2018

15. Challenges and opportunities in land surface modelling of savanna ecosystems

Author

R. Whitley, J. Beringer, L. B. Hutley, G. Abramowitz, M. G. De Kauwe, B. Evans, V. Haverd, L. Li, C. Moore, Y. Ryu, S. Scheiter, S. J. Schymanski, B. Smith, Y.-P. Wang, M. Williams, and Q. Yu

Subjects

Ecology, QH540-549.5, Life, QH501-531, Geology, QE1-996.5

Abstract

The savanna complex is a highly diverse global biome that occurs within the seasonally dry tropical to sub-tropical equatorial latitudes and are structurally and functionally distinct from grasslands and forests. Savannas are open-canopy environments that encompass a broad demographic continuum, often characterised by a changing dominance between C3-tree and C4-grass vegetation, where frequent environmental disturbances such as fire modulates the balance between ephemeral and perennial life forms. Climate change is projected to result in significant changes to the savanna floristic structure, with increases to woody biomass expected through CO2 fertilisation in mesic savannas and increased tree mortality expected through increased rainfall interannual variability in xeric savannas. The complex interaction between vegetation and climate that occurs in savannas has traditionally challenged terrestrial biosphere models (TBMs), which aim to simulate the interaction between the atmosphere and the land surface to predict responses of vegetation to changing in environmental forcing. In this review, we examine whether TBMs are able to adequately represent savanna fluxes and what implications potential deficiencies may have for climate change projection scenarios that rely on these models. We start by highlighting the defining characteristic traits and behaviours of savannas, how these differ across continents and how this information is (or is not) represented in the structural framework of many TBMs. We highlight three dynamic processes that we believe directly affect the water use and productivity of the savanna system: phenology, root-water access and fire dynamics. Following this, we discuss how these processes are represented in many current-generation TBMs and whether they are suitable for simulating savanna fluxes.Finally, we give an overview of how eddy-covariance observations in combination with other data sources can be used in model benchmarking and intercomparison frameworks to diagnose the performance of TBMs in this environment and formulate road maps for future development. Our investigation reveals that many TBMs systematically misrepresent phenology, the effects of fire and root-water access (if they are considered at all) and that these should be critical areas for future development. Furthermore, such processes must not be static (i.e. prescribed behaviour) but be capable of responding to the changing environmental conditions in order to emulate the dynamic behaviour of savannas. Without such developments, however, TBMs will have limited predictive capability in making the critical projections needed to understand how savannas will respond to future global change.

Published

2017

16. FluxnetLSM R package (v1.0): a community tool for processing FLUXNET data for use in land surface modelling

Author

A. M. Ukkola, N. Haughton, M. G. De Kauwe, G. Abramowitz, and A. J. Pitman

Subjects

Geology, QE1-996.5

Abstract

Flux towers measure ecosystem-scale surface–atmosphere exchanges of energy, carbon dioxide and water vapour. The network of flux towers now encompasses ∼ 900 sites, spread across every continent. Consequently, these data have become an essential benchmarking tool for land surface models (LSMs). However, these data as released are not immediately usable for driving, evaluating and benchmarking LSMs. Flux tower data must first be transformed into a LSM-readable file format, a process which involves changing units, screening missing data and varying degrees of additional gap-filling. All of this often leads to an under-utilisation of these data in model benchmarking. To resolve some of these issues, and to help make flux tower measurements more widely used, we present a reproducible, open-source R package that transforms the FLUXNET2015 and La Thuile data releases into community standard NetCDF files that are directly usable by LSMs. We note that these data would also be useful for any other user or community seeking to independently quality control, gap-fill or use the FLUXNET data.

Published

2017

17. A model inter-comparison study to examine limiting factors in modelling Australian tropical savannas

Author

R. Whitley, J. Beringer, L. B. Hutley, G. Abramowitz, M. G. De Kauwe, R. Duursma, B. Evans, V. Haverd, L. Li, Y. Ryu, B. Smith, Y.-P. Wang, M. Williams, and Q. Yu

Subjects

Ecology, QH540-549.5, Life, QH501-531, Geology, QE1-996.5

Abstract

The savanna ecosystem is one of the most dominant and complex terrestrial biomes, deriving from a distinct vegetative surface comprised of co-dominant tree and grass populations. While these two vegetation types co-exist functionally, demographically they are not static but are dynamically changing in response to environmental forces such as annual fire events and rainfall variability. Modelling savanna environments with the current generation of terrestrial biosphere models (TBMs) has presented many problems, particularly describing fire frequency and intensity, phenology, leaf biochemistry of C3 and C4 photosynthesis vegetation, and root-water uptake. In order to better understand why TBMs perform so poorly in savannas, we conducted a model inter-comparison of six TBMs and assessed their performance at simulating latent energy (LE) and gross primary productivity (GPP) for five savanna sites along a rainfall gradient in northern Australia. Performance in predicting LE and GPP was measured using an empirical benchmarking system, which ranks models by their ability to utilise meteorological driving information to predict the fluxes. On average, the TBMs performed as well as a multi-linear regression of the fluxes against solar radiation, temperature and vapour pressure deficit but were outperformed by a more complicated nonlinear response model that also included the leaf area index (LAI). This identified that the TBMs are not fully utilising their input information effectively in determining savanna LE and GPP and highlights that savanna dynamics cannot be calibrated into models and that there are problems in underlying model processes. We identified key weaknesses in a model's ability to simulate savanna fluxes and their seasonal variation, related to the representation of vegetation by the models and root-water uptake. We underline these weaknesses in terms of three critical areas for development. First, prescribed tree-rooting depths must be deep enough, enabling the extraction of deep soil-water stores to maintain photosynthesis and transpiration during the dry season. Second, models must treat grasses as a co-dominant interface for water and carbon exchange rather than a secondary one to trees. Third, models need a dynamic representation of LAI that encompasses the dynamic phenology of savanna vegetation and its response to rainfall interannual variability. We believe that this study is the first to assess how well TBMs simulate savanna ecosystems and that these results will be used to improve the representation of savannas ecosystems in future global climate model studies.

Published

2016

18. Modelling evapotranspiration during precipitation deficits: identifying critical processes in a land surface model

Author

A. M. Ukkola, A. J. Pitman, M. Decker, M. G. De Kauwe, G. Abramowitz, J. Kala, and Y.-P. Wang

Subjects

Technology, Environmental technology. Sanitary engineering, TD1-1066, Geography. Anthropology. Recreation, Environmental sciences, GE1-350

Abstract

Surface fluxes from land surface models (LSMs) have traditionally been evaluated against monthly, seasonal or annual mean states. The limited ability of LSMs to reproduce observed evaporative fluxes under water-stressed conditions has been previously noted, but very few studies have systematically evaluated these models during rainfall deficits. We evaluated latent heat fluxes simulated by the Community Atmosphere Biosphere Land Exchange (CABLE) LSM across 20 flux tower sites at sub-annual to inter-annual timescales, in particular focusing on model performance during seasonal-scale rainfall deficits. The importance of key model processes in capturing the latent heat flux was explored by employing alternative representations of hydrology, leaf area index, soil properties and stomatal conductance. We found that the representation of hydrological processes was critical for capturing observed declines in latent heat during rainfall deficits. By contrast, the effects of soil properties, LAI and stomatal conductance were highly site-specific. Whilst the standard model performs reasonably well at annual scales as measured by common metrics, it grossly underestimates latent heat during rainfall deficits. A new version of CABLE, with a more physically consistent representation of hydrology, captures the variation in the latent heat flux during seasonal-scale rainfall deficits better than earlier versions, but remaining biases point to future research needs. Our results highlight the importance of evaluating LSMs under water-stressed conditions and across multiple plant functional types and climate regimes.

Published

2016

19. Implementation of an optimal stomatal conductance scheme in the Australian Community Climate Earth Systems Simulator (ACCESS1.3b)

Author

J. Kala, M. G. De Kauwe, A. J. Pitman, R. Lorenz, B. E. Medlyn, Y.-P Wang, Y.-S Lin, and G. Abramowitz

Subjects

Geology, QE1-996.5

Abstract

We implement a new stomatal conductance scheme, based on the optimality approach, within the Community Atmosphere Biosphere Land Exchange (CABLEv2.0.1) land surface model. Coupled land–atmosphere simulations are then performed using CABLEv2.0.1 within the Australian Community Climate and Earth Systems Simulator (ACCESSv1.3b) with prescribed sea surface temperatures. As in most land surface models, the default stomatal conductance scheme only accounts for differences in model parameters in relation to the photosynthetic pathway but not in relation to plant functional types. The new scheme allows model parameters to vary by plant functional type, based on a global synthesis of observations of stomatal conductance under different climate regimes over a wide range of species. We show that the new scheme reduces the latent heat flux from the land surface over the boreal forests during the Northern Hemisphere summer by 0.5–1.0 mm day−1. This leads to warmer daily maximum and minimum temperatures by up to 1.0 °C and warmer extreme maximum temperatures by up to 1.5 °C. These changes generally improve the climate model's climatology of warm extremes and improve existing biases by 10–20 %. The bias in minimum temperatures is however degraded but, overall, this is outweighed by the improvement in maximum temperatures as there is a net improvement in the diurnal temperature range in this region. In other regions such as parts of South and North America where ACCESSv1.3b has known large positive biases in both maximum and minimum temperatures (~ 5 to 10 °C), the new scheme degrades this bias by up to 1 °C. We conclude that, although several large biases remain in ACCESSv1.3b for temperature extremes, the improvements in the global climate model over large parts of the boreal forests during the Northern Hemisphere summer which result from the new stomatal scheme, constrained by a global synthesis of experimental data, provide a valuable advance in the long-term development of the ACCESS modelling system.

Published

2015

20. A test of an optimal stomatal conductance scheme within the CABLE land surface model

Author

M. G. De Kauwe, J. Kala, Y.-S. Lin, A. J. Pitman, B. E. Medlyn, R. A. Duursma, G. Abramowitz, Y.-P. Wang, and D. G. Miralles

Subjects

Geology, QE1-996.5

Abstract

Stomatal conductance (gs) affects the fluxes of carbon, energy and water between the vegetated land surface and the atmosphere. We test an implementation of an optimal stomatal conductance model within the Community Atmosphere Biosphere Land Exchange (CABLE) land surface model (LSM). In common with many LSMs, CABLE does not differentiate between gs model parameters in relation to plant functional type (PFT), but instead only in relation to photosynthetic pathway. We constrained the key model parameter "g1", which represents plant water use strategy, by PFT, based on a global synthesis of stomatal behaviour. As proof of concept, we also demonstrate that the g1 parameter can be estimated using two long-term average (1960–1990) bioclimatic variables: (i) temperature and (ii) an indirect estimate of annual plant water availability. The new stomatal model, in conjunction with PFT parameterisations, resulted in a large reduction in annual fluxes of transpiration (~ 30% compared to the standard CABLE simulations) across evergreen needleleaf, tundra and C4 grass regions. Differences in other regions of the globe were typically small. Model performance against upscaled data products was not degraded, but did not noticeably reduce existing model–data biases. We identified assumptions relating to the coupling of the vegetation to the atmosphere and the parameterisation of the minimum stomatal conductance as areas requiring further investigation in both CABLE and potentially other LSMs. We conclude that optimisation theory can yield a simple and tractable approach to predicting stomatal conductance in LSMs.

Published

2015

21. Disentangling residence time and temperature sensitivity of microbial decomposition in a global soil carbon model

Author

J.-F. Exbrayat, A. J. Pitman, and G. Abramowitz

Subjects

Ecology, QH540-549.5, Life, QH501-531, Geology, QE1-996.5

Abstract

Recent studies have identified the first-order representation of microbial decomposition as a major source of uncertainty in simulations and projections of the terrestrial carbon balance. Here, we use a reduced complexity model representative of current state-of-the-art models of soil organic carbon decomposition. We undertake a systematic sensitivity analysis to disentangle the effect of the time-invariant baseline residence time (k) and the sensitivity of microbial decomposition to temperature (Q10) on soil carbon dynamics at regional and global scales. Our simulations produce a range in total soil carbon at equilibrium of ~ 592 to 2745 Pg C, which is similar to the ~ 561 to 2938 Pg C range in pre-industrial soil carbon in models used in the fifth phase of the Coupled Model Intercomparison Project (CMIP5). This range depends primarily on the value of k, although the impact of Q10 is not trivial at regional scales. As climate changes through the historical period, and into the future, k is primarily responsible for the magnitude of the response in soil carbon, whereas Q10 determines whether the soil remains a sink, or becomes a source in the future mostly by its effect on mid-latitude carbon balance. If we restrict our simulations to those simulating total soil carbon stocks consistent with observations of current stocks, the projected range in total soil carbon change is reduced by 42% for the historical simulations and 45% for the future projections. However, while this observation-based selection dismisses outliers, it does not increase confidence in the future sign of the soil carbon feedback. We conclude that despite this result, future estimates of soil carbon and how soil carbon responds to climate change should be more constrained by available data sets of carbon stocks.

Published

2014

22. Response of microbial decomposition to spin-up explains CMIP5 soil carbon range until 2100

Author

J.-F. Exbrayat, A. J. Pitman, and G. Abramowitz

Subjects

Geology, QE1-996.5

Abstract

Soil carbon storage simulated by the Coupled Model Intercomparison Project (CMIP5) models varies 6-fold for the present day. Here, we confirm earlier work showing that this range already exists at the beginning of the CMIP5 historical simulations. We additionally show that this range is largely determined by the response of microbial decomposition during each model's spin-up procedure from initialization to equilibration. The 6-fold range in soil carbon, once established prior to the beginning of the historical period (and prior to the beginning of a CMIP5 simulation), is then maintained through the present and to 2100 almost unchanged even under a strong business-as-usual emissions scenario. We therefore highlight that a commonly ignored part of CMIP5 analyses – the land surface state achieved through the spin-up procedure – can be important for determining future carbon storage and land surface fluxes. We identify the need to better constrain the outcome of the spin-up procedure as an important step in reducing uncertainty in both projected soil carbon and land surface fluxes in CMIP5 transient simulations.

Published

2014

23. Examining soil carbon uncertainty in a global model: response of microbial decomposition to temperature, moisture and nutrient limitation

Author

J.-F. Exbrayat, A. J. Pitman, Q. Zhang, G. Abramowitz, and Y.-P. Wang

Subjects

Ecology, QH540-549.5, Life, QH501-531, Geology, QE1-996.5

Abstract

Reliable projections of future climate require land–atmosphere carbon (C) fluxes to be represented realistically in Earth system models (ESMs). There are several sources of uncertainty in how carbon is parameterised in these models. First, while interactions between the C, nitrogen (N) and phosphorus (P) cycles have been implemented in some models, these lead to diverse changes in land–atmosphere fluxes. Second, while the first-order parameterisation of soil organic matter decomposition is similar between models, formulations of the control of the soil physical state on microbial activity vary widely. For the first time, we address these sources of uncertainty simultaneously by implementing three soil moisture and three soil temperature respiration functions in an ESM that can be run with three degrees of biogeochemical nutrient limitation (C-only, C and N, and C and N and P). All 27 possible combinations of response functions and biogeochemical mode are equilibrated before transient historical (1850–2005) simulations are performed. As expected, implementing N and P limitation reduces the land carbon sink, transforming some regional sinks into net sources over the historical period. Meanwhile, regardless of which nutrient mode is used, various combinations of response functions imply a two-fold difference in the net ecosystem accumulation and a four-fold difference in equilibrated total soil C. We further show that regions with initially larger pools are more likely to become carbon sources, especially when nutrient availability limits the response of primary production to increasing atmospheric CO2. Simulating changes in soil C content therefore critically depends on both nutrient limitation and the choice of respiration functions.

Published

2013

24. A novel method for diagnosing seasonal to inter-annual surface ocean carbon dynamics from bottle data using neural networks

Author

T. P. Sasse, B. I. McNeil, and G. Abramowitz

Subjects

Ecology, QH540-549.5, Life, QH501-531, Geology, QE1-996.5

Abstract

The ocean's role in modulating the observed 1–7 Pg C yr−1 inter-annual variability in atmospheric CO2 growth rate is an important, but poorly constrained process due to current spatio-temporal limitations in ocean carbon measurements. Here, we investigate and develop a non-linear empirical approach to predict inorganic CO2 concentrations (total carbon dioxide (CT) and total alkalinity (AT)) in the global ocean mixed layer from hydrographic properties (temperature, salinity, dissolved oxygen and nutrients). The benefit of this approach is that once the empirical relationship is established, it can be applied to hydrographic datasets that have better spatio-temporal coverage, and therefore provide an additional constraint to diagnose ocean carbon dynamics globally. Previous empirical approaches have employed multiple linear regressions (MLR) and relied on ad hoc geographic and temporal partitioning of carbon data to constrain complex global carbon dynamics in the mixed layer. Synthesizing a new global CT/AT carbon bottle dataset consisting of ~33 000 measurements in the open ocean mixed layer, we develop a neural network based approach to better constrain the non-linear carbon system. The approach classifies features in the global biogeochemical dataset based on their similarity and homogeneity in a self-organizing map (SOM; Kohonen, 1988). After the initial SOM analysis, which includes geographic constraints, we apply a local linear optimizer to the neural network, which considerably enhances the predictive skill of the new approach. We call this new approach SOMLO, or self-organizing multiple linear output. Using independent bottle carbon data, we compare a traditional MLR analysis to our SOMLO approach to capture the spatial CT and AT distributions. We find the SOMLO approach improves predictive skill globally by 19% for CT, with a global capacity to predict CT to within 10.9 μmol kg−1 (9.2 μmol kg−1 for AT). The non-linear SOMLO approach is particularly powerful in complex but important regions like the Southern Ocean, North Atlantic and equatorial Pacific, where residual standard errors were reduced between 25 and 40% over traditional linear methods. We further test the SOMLO technique using the Bermuda Atlantic time series (BATS) and Hawaiian ocean time series (HOT) datasets, where hydrographic data was capable of explaining 90% of the seasonal cycle and inter-annual variability at those multi-decadal time-series stations.

Published

2013

25. A framework for benchmarking land models

Author

Y. Q. Luo, J. T. Randerson, G. Abramowitz, C. Bacour, E. Blyth, N. Carvalhais, P. Ciais, D. Dalmonech, J. B. Fisher, R. Fisher, P. Friedlingstein, K. Hibbard, F. Hoffman, D. Huntzinger, C. D. Jones, C. Koven, D. Lawrence, D. J. Li, M. Mahecha, S. L. Niu, R. Norby, S. L. Piao, X. Qi, P. Peylin, I. C. Prentice, W. Riley, M. Reichstein, C. Schwalm, Y. P. Wang, J. Y. Xia, S. Zaehle, and X. H. Zhou

Subjects

Ecology, QH540-549.5, Life, QH501-531, Geology, QE1-996.5

Abstract

Land models, which have been developed by the modeling community in the past few decades to predict future states of ecosystems and climate, have to be critically evaluated for their performance skills of simulating ecosystem responses and feedback to climate change. Benchmarking is an emerging procedure to measure performance of models against a set of defined standards. This paper proposes a benchmarking framework for evaluation of land model performances and, meanwhile, highlights major challenges at this infant stage of benchmark analysis. The framework includes (1) targeted aspects of model performance to be evaluated, (2) a set of benchmarks as defined references to test model performance, (3) metrics to measure and compare performance skills among models so as to identify model strengths and deficiencies, and (4) model improvement. Land models are required to simulate exchange of water, energy, carbon and sometimes other trace gases between the atmosphere and land surface, and should be evaluated for their simulations of biophysical processes, biogeochemical cycles, and vegetation dynamics in response to climate change across broad temporal and spatial scales. Thus, one major challenge is to select and define a limited number of benchmarks to effectively evaluate land model performance. The second challenge is to develop metrics of measuring mismatches between models and benchmarks. The metrics may include (1) a priori thresholds of acceptable model performance and (2) a scoring system to combine data–model mismatches for various processes at different temporal and spatial scales. The benchmark analyses should identify clues of weak model performance to guide future development, thus enabling improved predictions of future states of ecosystems and climate. The near-future research effort should be on development of a set of widely acceptable benchmarks that can be used to objectively, effectively, and reliably evaluate fundamental properties of land models to improve their prediction performance skills.

Published

2012

26. Towards a public, standardized, diagnostic benchmarking system for land surface models

Author

G. Abramowitz

Subjects

Geology, QE1-996.5

Abstract

This work examines different conceptions of land surface model benchmarking and the importance of internationally standardized evaluation experiments that specify data sets, variables, metrics and model resolutions. It additionally demonstrates how essential the definition of a priori expectations of model performance can be, based on the complexity of a model and the amount of information being provided to it, and gives an example of how these expectations might be quantified. Finally, the Protocol for the Analysis of Land Surface models (PALS) is introduced – a free, online land surface model benchmarking application that is structured to meet both of these goals.

Published

2012

27. The CSIRO Mk3L climate system model v1.0 coupled to the CABLE land surface scheme v1.4b: evaluation of the control climatology

Author

J. Mao, S. J. Phipps, A. J. Pitman, Y. P. Wang, G. Abramowitz, and B. Pak

Subjects

Geology, QE1-996.5

Abstract

The CSIRO Mk3L climate system model, a reduced-resolution coupled general circulation model, has previously been described in this journal. The model is configured for millennium scale or multiple century scale simulations. This paper reports the impact of replacing the relatively simple land surface scheme that is the default parameterisation in Mk3L with a sophisticated land surface model that simulates the terrestrial energy, water and carbon balance in a physically and biologically consistent way. An evaluation of the new model's near-surface climatology highlights strengths and weaknesses, but overall the atmospheric variables, including the near-surface air temperature and precipitation, are simulated well. The impact of the more sophisticated land surface model on existing variables is relatively small, but generally positive. More significantly, the new land surface scheme allows an examination of surface carbon-related quantities including net primary productivity which adds significantly to the capacity of Mk3L. Overall, results demonstrate that this reduced-resolution climate model is a good foundation for exploring long time scale phenomena. The addition of the more sophisticated land surface model enables an exploration of important Earth System questions including land cover change and abrupt changes in terrestrial carbon storage.

Published

2011

28. Exploring the Substrate Specificity of a Sugar Transporter with Biosensors and Cheminformatics

Author

Jihyun Park, Ryan G. Abramowitz, Sojeong Gwon, and Lily S. Cheung

Subjects

Biomedical Engineering, General Medicine, Biochemistry, Genetics and Molecular Biology (miscellaneous)

Published

2023

29. Acute climate risks in the financial system: examining the utility of climate model projections

Author

A J Pitman, T Fiedler, N Ranger, C Jakob, N Ridder, S Perkins-Kirkpatrick, N Wood, and G Abramowitz

Abstract

Efforts to assess risks to the financial system associated with climate change are growing. These commonly combine the use of integrated assessment models to obtain possible changes in global mean temperature (GMT) and then use coupled climate models to map those changes onto finer spatial scales to estimate changes in other variables. Other methods use data mined from ‘ensembles of opportunity’ such as the Coupled Model Intercomparison Project (CMIP). Several challenges with current approaches have been identified. Here, we focus on demonstrating the issues inherent in applying global ‘top-down’ climate scenarios to explore financial risks at geographical scales of relevance to financial institutions (e.g. city-scale). We use data mined from the CMIP to determine the degree to which estimates of GMT can be used to estimate changes in the annual extremes of temperature and rainfall, two compound events (heatwaves and drought, and extreme rain and strong winds), and whether the emission scenario provides insights into the change in the 20, 50 and 100 year return values for temperature and rainfall. We show that GMT provides little insight on how acute risks likely material to the financial sector (‘material extremes’) will change at a city-scale. We conclude that ‘top-down’ approaches are likely to be flawed when applied at a granular scale, and that there are risks in employing the approaches used by, for example, the Network of Central Banks and Supervisors for Greening the Financial System. Most fundamental, uncertainty associated with projections of future climate extremes must be propagated through to estimating risk. We strongly encourage a review of existing top-down approaches before they develop into de facto standards and note that existing approaches that use a ‘bottom-up’ strategy (e.g. catastrophe modelling and storylines) are more likely to enable a robust assessment of material risk.

Published

2022

30. Single-cell analysis reveals effective siRNA delivery in brain tumors with microbubble-enhanced ultrasound and cationic nanoparticles

Author

Anastasia Velalopoulou, Ryan G. Abramowitz, Ahmet F. Coskun, Mark Thomas, Zhou Fang, Tobey J. MacDonald, Jingbo Liu, Yutong Guo, Daniel Pomeranz Krummel, Hohyun Lee, Soma Sengupta, YongTae Kim, Jinhwan Kim, and Costas D. Arvanitis

Subjects

Adult, Small interfering RNA, Brain tumor, 03 medical and health sciences, 0302 clinical medicine, Engineering, Single-cell analysis, Cations, Cell Line, Tumor, medicine, Protein biosynthesis, Tumor Microenvironment, Humans, RNA, Small Interfering, Child, Research Articles, 030304 developmental biology, Cancer, Medulloblastoma, 0303 health sciences, Multidisciplinary, Microbubbles, Chemistry, business.industry, Brain Neoplasms, Ultrasound, RNA, SciAdv r-articles, medicine.disease, Blood-Brain Barrier, 030220 oncology & carcinogenesis, Cancer research, Nanoparticles, Single-Cell Analysis, Smoothened, business, Research Article

Abstract

Focused ultrasound–mediated delivery of RNA-loaded nanoparticles increases brain tumor cell apoptosis through oncogene targeting., RNA-based therapies offer unique advantages for treating brain tumors. However, tumor penetrance and uptake are hampered by RNA therapeutic size, charge, and need to be “packaged” in large carriers to improve bioavailability. Here, we have examined delivery of siRNA, packaged in 50-nm cationic lipid-polymer hybrid nanoparticles (LPHs:siRNA), combined with microbubble-enhanced focused ultrasound (MB-FUS) in pediatric and adult preclinical brain tumor models. Using single-cell image analysis, we show that MB-FUS in combination with LPHs:siRNA leads to more than 10-fold improvement in siRNA delivery into brain tumor microenvironments of the two models. MB-FUS delivery of Smoothened (SMO) targeting siRNAs reduces SMO protein production and markedly increases tumor cell death in the SMO-activated medulloblastoma model. Moreover, our analysis reveals that MB-FUS and nanoparticle properties can be optimized to maximize delivery in the brain tumor microenvironment, thereby serving as a platform for developing next-generation tunable delivery systems for RNA-based therapy in brain tumors.

Published

2020

31. The Roots and Evolution of Ego-State Theory and Therapy

Author

Eitan G. Abramowitz and Moshe S. Torem

Subjects

Ego, Complementary and Manual Therapy, Cognitive science, Structure (mathematical logic), Hypnosis, Clinical effectiveness, media_common.quotation_subject, 05 social sciences, State theory, 050109 social psychology, Psychotherapy, 03 medical and health sciences, Clinical Psychology, 0302 clinical medicine, Id, ego and super-ego, Psychological Theory, Humans, Personality, 0501 psychology and cognitive sciences, Psychology, 030217 neurology & neurosurgery, media_common

Abstract

The purpose of this article is to elucidate the origins of ego-state theory and therapy and to discuss the concept of human personality as a structure comprising numerous ego states. The historical roots of ego-state theory and therapy are reviewed. Also, the evolution of ego-state therapy from classic hypnotherapy to modern methods is identified. The article notes that these methods of ego-state therapy have been described by different authors and under different names. It is suggested that core concepts related to ego-state theory and therapy of guided hypnotic dissociation may underlie the core of clinical effectiveness in many contemporary psychotherapeutic methods.

Published

2018

32. [EGO-STATES HYPNO-ANALYSIS: CASE STUDY OF PATIENT WITH CHRONIC COMBAT PTSD]

Author

Eitan G, Abramowitz

Subjects

Psychotherapy, Stress Disorders, Post-Traumatic, Humans, Hypnosis

Abstract

Psychotherapy by means of hypnosis is one of the oldest methods of psychotherapy. The hypnotherapy method is particularly suitable for treating trauma victims. This article presents a clinical case and description of treatment by the hypnotherapy method called Ego State Hypno-Analysis. This treatment is part of a multi-stage therapeutic program based on the principles of the psycho-trauma treatment by Pierre Janet and John Watkins. The results indicate that hypnotic psychotherapy can accelerate and improve the treatment of patients suffering from chronic PTSD.

Published

2019

33. Derived Optimal Linear Combination Evapotranspiration (DOLCE): a global gridded synthesis ET estimate

Author

S. Hobeichi, G. Abramowitz, J. Evans, and A. Ukkola

Subjects

010504 meteorology & atmospheric sciences, Computer science, 0208 environmental biotechnology, 02 engineering and technology, computer.software_genre, 01 natural sciences, lcsh:Technology, lcsh:TD1-1066, FluxNet, Evapotranspiration, Statistics, lcsh:Environmental technology. Sanitary engineering, Linear combination, lcsh:Environmental sciences, 0105 earth and related environmental sciences, lcsh:GE1-350, lcsh:T, lcsh:Geography. Anthropology. Recreation, Covariance, Grid, 020801 environmental engineering, Weighting, lcsh:G, Temporal resolution, Data mining, Scale (map), computer

Abstract

Accurate global gridded estimates of evapotranspiration (ET) are key to understanding water and energy budgets, in addition to being required for model evaluation. Several gridded ET products have already been developed which differ in their data requirements, the approaches used to derive them and their estimates, yet it is not clear which provides the most reliable estimates. This paper presents a new global ET dataset and associated uncertainty with monthly temporal resolution for 2000–2009. Six existing gridded ET products are combined using a weighting approach trained by observational datasets from 159 FLUXNET sites. The weighting method is based on a technique that provides an analytically optimal linear combination of ET products compared to site data and accounts for both the performance differences and error covariance between the participating ET products. We examine the performance of the weighting approach in several in-sample and out-of-sample tests that confirm that point-based estimates of flux towers provide information on the grid scale of these products. We also provide evidence that the weighted product performs better than its six constituent ET product members in four common metrics. Uncertainty in the ET estimate is derived by rescaling the spread of participating ET products so that their spread reflects the ability of the weighted mean estimate to match flux tower data. While issues in observational data and any common biases in participating ET datasets are limitations to the success of this approach, future datasets can easily be incorporated and enhance the derived product.

Published

2019

34. EPCT-25. SMO PROTEIN DEPLETION IN SHH MEDULLOBLASTOMAS USING MICROBUBBLE-ENHANCED ULTRASOUND AND SIRNA LOADED CATIONIC NANOPARTICLES

Author

Ahmet F. Coskun, Soma Sengupta, YongTae Kim, Ryan G. Abramowitz, Yutong Guo, Costas D. Arvanitis, Mark Thomas, Jinhwan Kim, Zhou Fang, Jingbo Liu, Daniel Pomeranz Krummel, Anastasia Velalopoulou, Tobey J MacDonald, and Hohyun Lee

Subjects

Medulloblastoma, Cancer Research, Tumor microenvironment, Chemistry, Brain tumor, medicine.disease, Blood–brain barrier, Translational/Early Phase Clinical Trials, medicine.anatomical_structure, Oncology, Apoptosis, Drug delivery, Cancer cell, medicine, Cancer research, AcademicSubjects/MED00300, AcademicSubjects/MED00310, Neurology (clinical), Smoothened

Abstract

RNA-based therapies offer unique advantages for treating pediatric brain tumors. However, the systemic delivery remains a major problem due to degradation of unmodified RNA in biological fluids, poor brain accumulation, and poor cancer cell uptake or escape from the endosomal lipid bilayer barrier. While nanoparticle encapsulation can prolong circulation time and facilitate cellular uptake, their accumulation in brain tumor remains particularly poor due to their low permeability across the blood-brain barrier and limited intratumoral penetration. Focused ultrasound, when combined with circulating microbubbles (MB-FUS) provides a physical method to transiently modulate the brain tumor microenvironment (TME) and improve nanoparticle delivery. Here, we have examined the delivery of siRNA targeting the Smoothened (SMO) pathway, packaged in 50 nm cationic lipid-polymer hybrid nanoparticles (cLPH:siRNA-SMO), combined with MB-FUS in murine SmoA2 sonic hedgehog (SHH) medulloblastoma. At 30 hours after treatment, we observed the depletion of the SMO protein target, responsible for driving SHH medulloblastoma formation and growth, in mice that had received treatment with MB-FUS and cLPH:siRNA-SMO, but not with cLPH:siRNA-SMO alone. We also confirmed that SMO protein depletion was spatially achieved in the tumor regions with detected cLPH:siRNA-SMO using FISH assay, and that there was 15 fold induction of tumor cell apoptosis compared to tumors in mice that had received cLPH:siRNA-SMO alone. The limited induction of apoptosis was observed with either cLPH:siRNA (non-targeting) or MB-FUS and cLPH:siRNA (non-targeting), suggest that the observed apoptosis induction in the SmoA2 model was the direct result of SMO depletion rather than nonspecific effects of MB-FUS or cLPH:siRNA. Our findings provide a paradigm shift in drug delivery in brain tumors, where physical methods and nanotechnology are tuned together to develop rational strategies for the effective delivery of nucleic acids in brain tumors.

Published

2021

35. Hypnotically induced somatosensory alterations: Toward a neurophysiological understanding of hypnotic anaesthesia

Author

Eitan G. Abramowitz, Abraham Goldstein, Omer Bonne, and Maor Zeev-Wolf

Subjects

Adult, Male, Hypnosis, Sensory processing, medicine.drug_class, Brain activity and meditation, Cognitive Neuroscience, medicine.medical_treatment, Experimental and Cognitive Psychology, Somatosensory system, 050105 experimental psychology, Fingers, Hypnotic, 03 medical and health sciences, Behavioral Neuroscience, 0302 clinical medicine, Physical Stimulation, Surveys and Questionnaires, Sensation, medicine, Humans, Anesthesia, 0501 psychology and cognitive sciences, Pain Measurement, Cerebral Cortex, medicine.diagnostic_test, 05 social sciences, Magnetoencephalography, Pain Perception, Alpha Rhythm, Female, Beta Rhythm, Psychology, Insula, 030217 neurology & neurosurgery

Abstract

Whereas numerous studies have investigated hypnotic analgesia, few have investigated hypnotic anaesthesia. Using magnetoencephalography (MEG) we investigated and localized brain responses (event-related fields and oscillatory activity) during sensory processing under hypnotic anaesthesia. Nineteen right handed neurotypical individuals with moderate-to-high hypnotizability received 100 vibrotactile stimuli to right and left index fingers in a random sequence. Thereafter a hypnotic state was induced, in which anaesthetic suggestion was applied to the left hand only. Once anaesthetic suggestion was achieved, a second, identical, session of vibrotactile stimuli was commenced. We found greater brain activity in response to the stimuli delivered to the left (attenuated) hand before hypnotic anaesthesia, than under hypnotic anaesthesia, in both the beta and alpha bands. In the beta band, the reduction of activity under hypnotic anaesthesia was found around 214-413ms post-stimuli and was located mainly in the right insula. In the alpha band, it was found around 253-500ms post-stimuli and was located mainly in the left inferior frontal gyrus. In a second experiment, attention modulation per se was ruled out as the underlying cause of the effects found. These findings may suggest that the brain mechanism underlying hypnotic anaesthesia involves top-down somatosensory inhibition and, therefore, a reduction of somatosensory awareness. The result of this mechanism is a mental state in which individuals lose bodily sensation.

Published

2016

36. Linear Optimal Runoff Aggregate (LORA): A global gridded synthesis runoff product

Author

S. Hobeichi, G. Abramowitz, J. Evans, and H. E. Beck

Subjects

010504 meteorology & atmospheric sciences, Meteorology, 0208 environmental biotechnology, Drainage basin, 02 engineering and technology, lcsh:Technology, 01 natural sciences, lcsh:TD1-1066, Proxy (climate), Streamflow, lcsh:Environmental technology. Sanitary engineering, lcsh:Environmental sciences, 0105 earth and related environmental sciences, lcsh:GE1-350, geography, geography.geographical_feature_category, lcsh:T, business.industry, lcsh:Geography. Anthropology. Recreation, Covariance, Grid, 020801 environmental engineering, Weighting, lcsh:G, New product development, Environmental science, business, Surface runoff

Abstract

No synthesized global gridded runoff product, derived from multiple sources, is available, despite such a product being useful for meeting the needs of many global water initiatives. We apply an optimal weighting approach to merge runoff estimates from hydrological models constrained with observational streamflow records. The weighting method is based on the ability of the models to match observed streamflow data while accounting for error covariance between the participating products. To address the lack of observed streamflow for many regions, a dissimilarity method was applied to transfer the weights of the participating products to the ungauged basins from the closest gauged basins using dissimilarity between basins in physiographic and climatic characteristics as a proxy for distance. We perform out-of-sample tests to examine the success of the dissimilarity approach, and we confirm that the weighted product performs better than its 11 constituent products in a range of metrics. Our resulting synthesized global gridded runoff product is available at monthly timescales, and includes time-variant uncertainty, for the period 1980–2012 on a 0.5∘ grid. The synthesized global gridded runoff product broadly agrees with published runoff estimates at many river basins, and represents the seasonal runoff cycle for most of the globe well. The new product, called Linear Optimal Runoff Aggregate (LORA), is a valuable synthesis of existing runoff products and will be freely available for download on https://geonetwork.nci.org.au/geonetwork/srv/eng/catalog.search#/metadata/f9617_9854_8096_5291 (last access: 31 January 2019).

Published

2018

37. Oscillatory brain mechanisms of the hypnotically-induced out-of-body experience

Author

Maor Zeev-Wolf, Eitan G. Abramowitz, Yair Dor-Ziderman, Omer Bonne, and Abraham Goldstein

Subjects

Adult, Male, Brain activity and meditation, Cognitive Neuroscience, media_common.quotation_subject, Illusion, Experimental and Cognitive Psychology, 050105 experimental psychology, 03 medical and health sciences, 0302 clinical medicine, Parietal Lobe, medicine, Body Image, Humans, 0501 psychology and cognitive sciences, media_common, Brain Mapping, medicine.diagnostic_test, 05 social sciences, Perspective (graphical), Out-of-body experience, Magnetoencephalography, Illusions, Self Concept, Temporal Lobe, Neuropsychology and Physiological Psychology, Feeling, Embodied cognition, Space Perception, Female, Consciousness, Psychology, 030217 neurology & neurosurgery, Cognitive psychology

Abstract

One of the most challenging questions regarding the nature and neural basis of consciousness is the embodied dimension of the phenomenon, that is, feeling located within the body and viewing the world from that spatial perspective. Current theories in neurophysiology highlight the active role of multisensory and sensorimotor integration in supporting self-location and self-perspective, and propose the right temporal-parietal-junction (rTPJ) as a key area for such function. These theories are based mainly on findings from two experimental paradigms: manipulation of bottom-up multisensory information integration regarding one's body location (full-body illusion), or direct and invasive manipulation disrupting brain activity at the rTPJ. In this study we take a different approach by using hypnotic suggestion - a non-invasive top-down technique - to manipulate the subjective experience of self-location. The brain activity of 18 right-handed participants was recorded using magnetoencephalography (MEG) while their subjective experience of self-location was hypnotically manipulated. Spectral analyses were conducted on the spontaneous MEG data before and during an induction of an out-of-body experience (OBE) by a trained psychiatrist. The results indicate high correlations between power at alpha and high-gamma frequency-bands and the degree of perceived change in self-location. Regions exhibiting such correlations include temporal-occipital regions, the rTPJ, as well as frontal and midline regions. These findings are in line with an oscillatory-based predictive coding framework.

Published

2017

38. International Land Model Benchmarking (ILAMB) Workshop Report, Technical Report DOE/SC-0186

Author

Forrest M. Hoffman, Charles D. Koven, Gretchen Kappel-Aleks, David M. Lawrence, William Riley, James T. Randerson, Anders Ahlstrom, G. Abramowitz, Dennis Baldocchi, Benjamin Bond-Lamberty, Martin G. De Kauwe, Scott Denning, Ankur R. Desai, Veronika Eyring, Joshua B. Fisher, R. Fisher, Peter J. Gleckler, Maoyi Huang, Gustaf Hugelius, Atul K. Jain, Nancy Y. Kiang, Hyungjun Kim, Randy Koster, Sujay V. Kumar, Hongyi Li, Yiqi Luo, Jiafu Mao, Nate G. McDowell, Umakant Mishra, Paul Moorcroft, George Pau, Daniel M. Ricciuto, Kevin Schaefer, C. Schwalm, Shawn Serbin, Elena Shevliakova, Andrew G. Slater, Jinyun Tang, Mathew Williams, Jianyang Xia, Chonggang Xu, Renu Joseph, and Dorothy Koch

Published

2016

39. A New Hypnotic Technique for Treating Combat-Related Posttraumatic Stress Disorder:A Prospective Open Study

Author

Pesach Lichtenberg and Eitan G. Abramowitz

Subjects

Adult, Male, Complementary and Manual Therapy, medicine.medical_specialty, Hypnosis, Time Factors, medicine.drug_class, Dissociative Experiences Scale, Traumatic memories, Hypnotic, Young Adult, medicine, Humans, Prospective Studies, Israel, Psychiatry, Psychiatric Status Rating Scales, Combat Disorders, Beck Depression Inventory, Middle Aged, Treatment period, Smell, Open study, Clinical Psychology, Posttraumatic stress, Psychology, Clinical psychology

Abstract

Many combat veterans with posttraumatic stress disorder (PTSD) have an olfactory component to their traumatic memories that might be utilized by a technique called hypnotherapeutic olfactory conditioning (HOC). Thirty-six outpatients with chronic PTSD, featuring resistant olfactory-induced flashbacks, were treated with six 1.5-hour sessions using hypnosis. The authors used the revised Impact of Events Scale (IES–R), Beck Depression Inventory, and Dissociative Experiences Scale as outcome measures. Significant reductions in symptomatology were recorded by the end of the 6-week treatment period for the IES–R, as well as for the Beck Depression Inventory and the Dissociative Experiences Scale; 21 (58%) of the subjects responded to treatment by a reduction of 50% or more on the IES–R. Improvement was maintained at 6-month and 1-year follow-ups. Use of medication was curtailed. HOC shows potential for providing benefit to individuals suffering from PTSD with olfactory components.

Published

2010

40. Israeli Norms for the Stanford Hypnotic Susceptibility Scale, Form C

Author

Yuval Kalish, Haim Shapira, Eitan G. Abramowitz, and Pesach Lichtenberg

Subjects

Complementary and Manual Therapy, Hebrew, Scale (music), language.human_language, German, Clinical Psychology, Reference Values, Surveys and Questionnaires, language, Humans, Hypnotic susceptibility, Israel, Suggestion, Psychology, Social psychology, Hypnosis, Clinical psychology

Abstract

A Hebrew version of the 12-item Stanford Hypnotic Susceptibility Scale, Form C (SHSS:C) was administered to 169 subjects in Israel. The authors compared the results with those obtained for the English original administered in the USA and with an additional group of 38 English-speaking subjects in Israel, as well as with versions translated into Spanish (2 versions, for Spain and for Mexico), Italian, German, and Dutch. Mean scores and pair-wise rank-order correlations between item pass rates were comparable across the different samples. Item reliability was somewhat lower in the Hebrew version; however, if testing was discontinued after failure to comply with 3 consecutive items, reliability was similar to that obtained for the other samples. We conclude that the Hebrew version of the SHSS:C can be used for the assessment of hypnotizability and recommend that the discontinuation criterion be applied.

Published

2009

41. Hypnotherapy in the Treatment of Chronic Combat-Related PTSD Patients Suffering From Insomnia:A Randomized, Zolpidem-Controlled Clinical Trial

Author

Yoram Barak, Irit Ben-Avi, Eitan G. Abramowitz, and Haim Y. Knobler

Subjects

Adult, Male, Complementary and Manual Therapy, medicine.medical_specialty, Hypnosis, Zolpidem, Pyridines, Night Terrors, law.invention, Young Adult, Randomized controlled trial, law, Sleep Initiation and Maintenance Disorders, mental disorders, medicine, Insomnia, Humans, Hypnotics and Sedatives, Psychiatry, Combat Disorders, Beck Depression Inventory, Combined Modality Therapy, Dreams, Psychotherapy, Clinical trial, Clinical Psychology, Supportive psychotherapy, Hypnotic susceptibility, medicine.symptom, Psychology, Selective Serotonin Reuptake Inhibitors, medicine.drug

Abstract

This study evaluated the benefits of add-on hypnotherapy in patients with chronic PTSD. Thirty-two PTSD patients treated by SSRI antidepressants and supportive psychotherapy were randomized to 2 groups: 15 patients in the first group received Zolpidem 10 mg nightly for 14 nights, and 17 patients in the hypnotherapy group were treated by symptom-oriented hypnotherapy, twice-a-week 1.5-hour sessions for 2 weeks. All patients completed the Stanford Hypnotic Susceptibility Scale, Form C, Beck Depression Inventory, Impact of Event Scale, and Visual Subjective Sleep Quality Questionnaire before and after treatment. There was a significant main effect of the hypnotherapy treatment with PTSD symptoms as measured by the Posttraumatic Disorder Scale. This effect was preserved at follow-up 1 month later. Additional benefits for the hypnotherapy group were decreases in intrusion and avoidance reactions and improvement in all sleep variables assessed.

Published

2008

42. Scaleable, microstructured plant for steam reforming of methane

Author

Anthony Matthew Johnston, E.L.C. Seris, G. Abramowitz, and Brian S. Haynes

Subjects

Engineering, Waste management, Hydrogen, business.industry, General Chemical Engineering, Proton exchange membrane fuel cell, chemistry.chemical_element, General Chemistry, Combustion, Industrial and Manufacturing Engineering, Methane, Steam reforming, chemistry.chemical_compound, chemistry, Natural gas, Heat exchanger, Environmental Chemistry, Process engineering, business, Hydrogen production

Abstract

We report results obtained in a demonstration plant for hydrogen production at 5 Nm 3 h −1 in a microchannel system constructed using techniques proven in Heatric printed-circuit heat exchangers (PCHE). The manufacturing technique allows great complexity in the design to be achieved with little incremental cost and our plant takes advantage of this to carry out the combustion and reforming reactions in highly integrated multiple adiabatic beds (MAB). The PCHE manufacturing technique is scaleable and the results from this small-scale plant demonstrate not only a practical miniplant for distributed manufacture of hydrogen but also provide the design basis for much larger plant (for example for transport fuelling and industrial applications) based on replication of the plate structures. The system operated at 2 bar to produce hydrogen for a notional PEM fuel cell, with essentially complete conversion of natural gas in the reformer to equilibrium yields of CO, CO2 and H2 (∼80%). The plant showed excellent turn-down characteristics to 30% of design capacity. © 2007 Elsevier B.V. All rights reserved.

Published

2008

43. Supplementary material to 'Modelling evapotranspiration during precipitation deficits: identifying critical processes in a land surface model'

Author

A. M. Ukkola, A. J. Pitman, M. Decker, M. G. De Kauwe, G. Abramowitz, J. Kala, and Y.-P. Wang

Published

2015

44. Implementation of an optimal stomatal conductance model in the Australian Community Climate Earth Systems Simulator (ACCESS1.3b)

Author

J. Kala, M. G. De Kauwe, A. J. Pitman, R. Lorenz, B. E. Medlyn, Y.-P Wang, Y.-S Lin, and G. Abramowitz

Abstract

We implement a new stomatal conductance model, based on the optimality approach, within the Community Atmosphere Biosphere Land Exchange (CABLE) land surface model. Coupled land-atmosphere simulations are then performed using CABLE within the Australian Community Climate and Earth Systems Simulator (ACCESS) with prescribed sea surface temperatures. As in most land surface models, the default stomatal conductance scheme only accounts for differences in model parameters in relation to the photosynthetic pathway, but not in relation to plant functional types. The new scheme allows model parameters to vary by plant functional type, based on a global synthesis of observations of stomatal conductance under different climate regimes over a wide range of species. We show that the new scheme reduces the latent heat flux from the land surface over the boreal forests during the Northern Hemisphere summer by 0.5 to 1.0 mm day-1. This leads to warmer daily maximum and minimum temperatures by up to 1.0 °C and warmer extreme maximum temperatures by up to 1.5 °C. These changes generally improve the climate model's climatology and improve existing biases by 10–20 %. The change in the surface energy balance also affects net primary productivity and the terrestrial carbon balance. We conclude that the improvements in the global climate model which result from the new stomatal scheme, constrained by a global synthesis of experimental data, provide a valuable advance in the long-term development of the ACCESS modelling system.

Published

2015

45. Demonstration Plant for Distributed Production of Hydrogen from Steam Reforming of Methane

Author

G. Abramowitz, E.L.C. Seris, Anthony Matthew Johnston, and Brian S. Haynes

Subjects

Chemistry, business.industry, General Chemical Engineering, Mechanical engineering, Chemical plant, General Chemistry, Steam reforming, Pilot plant, Natural gas, Process integration, Heat exchanger, business, Syngas, Hydrogen production

Abstract

We describe and demonstrate a technique for the creation of highly intensified, highly integrated chemical plant. The process is implemented using Printed Circuit Heat Exchanger (PCHE) technology in which the fluid passages and vessels are etched into flat plates, with the plates being stacked and bonded to create highly integrated modules. The manufacturing technique allows extraordinary complexity in the routing of fluid streams through the process, thus enabling very high levels of process integration to be achieved without significant capital or plant volume penalty. The fine passages employed in the structure have characteristic dimensions of around 1 mm, thus promoting further process intensification especially in heat transfer.The PCHE technique produces scaleable modules ideally suited to a wide range of production capacities, from miniplant to world scale. In our work, we explore the concept of distributed manufacture based on miniplants, as espoused by Benson and Ponton more than 10 years ago. We believe this paradigm offers new capital-accessible opportunities for chemical processing in smaller and more isolated economies such as in Australia and in the developing countries.A pilot plant for the production of syngas or hydrogen by the reforming of natural gas with steam has been installed at the University of Sydney. The main plant module contains nine reactors, 10 combustors and 11 heat exchangers in a single integrated block. We describe the system in detail and the experimental set up for the operation and control of the system.

Published

2005

46. Supplementary material to 'Disentangling residence time and temperature sensitivity of microbial decomposition in a global soil carbon model'

Author

J.-F. Exbrayat, A. J. Pitman, and G. Abramowitz

Published

2014

47. [Use of hypnosis in the treatment of combat post traumatic stress disorder (PTSD)]

Author

Eitan G, Abramowitz and Omer, Bonne

Subjects

Stress Disorders, Post-Traumatic, Combat Disorders, Treatment Outcome, Adaptation, Psychological, Practice Guidelines as Topic, Humans, Professional-Patient Relations, Hypnosis

Abstract

Clinical reports and observations going back almost two centuries consistently indicate that hypnotherapy is an effective modality for the treatment of post traumatic stress disorder (PTSD). Pierre Janet was the first clinician to describe the successful initiation of stepwise hypnotic techniques in PTSD symptom reduction. Hypnotherapy may accelerate the formation of a therapeutic alliance and contribute to a positive treatment outcome. Hypnotic techniques may be valuable for patients with PTSD who exhibit symptoms such as anxiety, dissociation, widespread somatoform pain complaints and sleep disturbances. Hypnotic techniques may also facilitate the arduous tasks of working through traumatic memories, increasing coping skills, and promoting a sense of competency. In this review we will present guidelines for the stepwise implementation of hypnotherapy in PTSD. Since most data regarding the use of hypnotherapy in PTSD has been gathered from uncontrolled clinical observations, methodologically sound research demonstrating the efficacy of hypnotic techniques in PTSD is required for hypnotherapy to be officially added to the therapeutic armamentarium for this disorder.

Published

2013

48. Supplementary material to 'A novel method for diagnosing seasonal to inter-annual surface ocean carbon dynamics from bottle data using neural networks'

Author

T. P. Sasse, B. I. McNeil, and G. Abramowitz

Published

2012

49. A framework of benchmarking land models

Author

Y. Q. Luo, J. Randerson, G. Abramowitz, C. Bacour, E. Blyth, N. Carvalhais, P. Ciais, D. Dalmonech, J. Fisher, R. Fisher, P. Friedlingstein, K. Hibbard, F. Hoffman, D. Huntzinger, C. D. Jones, C. Koven, D. Lawrence, D. J. Li, M. Mahecha, S. L. Niu, R. Norby, S. L. Piao, X. Qi, P. Peylin, I. C. Prentice, W. Riley, M. Reichstein, C. Schwalm, Y. P. Wang, J. Y. Xia, S. Zaehle, and X. H. Zhou

Abstract

Land models, which have been developed by the modeling community in the past two decades to predict future states of ecosystems and climate, have to be critically evaluated for their performance skills of simulating ecosystem responses and feedback to climate change. Benchmarking is an emerging procedure to measure and evaluate performance of models against a set of defined standards. This paper proposes a benchmarking framework for evaluation of land models. The framework includes (1) targeted aspects of model performance to be evaluated; (2) a set of benchmarks as defined references to test model performance; (3) metrics to measure and compare performance skills among models so as to identify model strengths and deficiencies; and (4) model improvement. Component 4 may or may not be involved in a benchmark analysis but is an ultimate goal of general modeling research. Land models are required to simulate exchange of water, energy, carbon and sometimes other trace gases between the atmosphere and the land-surface, and should be evaluated for their simulations of biophysical processes, biogeochemical cycles, and vegetation dynamics across timescales in response to both weather and climate change. Benchmarks that are used to evaluate models generally consist of direct observations, data-model products, and data-derived patterns and relationships. Metrics of measuring mismatches between models and benchmarks may include (1) a priori thresholds of acceptable model performance and (2) a scoring system to combine data-model mismatches for various processes at different temporal and spatial scales. The benchmark analyses should identify clues of weak model performance for future improvement. Iterations between model evaluation and improvement via benchmarking shall demonstrate progress of land modeling and help establish confidence in land models for their predictions of future states of ecosystems and climate.

Published

2012

50. Hypnotherapeutic olfactory conditioning (HOC): case studies of needle phobia, panic disorder, and combat-induced PTSD

Author

Pesach Lichtenberg and Eitan G. Abramowitz

Subjects

Complementary and Manual Therapy, Adult, Male, Hypnosis, Psychotherapist, Dissociation (neuropsychology), Adolescent, behavioral disciplines and activities, Olfactory conditioning, Stress Disorders, Post-Traumatic, mental disorders, Conditioning, Psychological, medicine, Humans, Association (psychology), Phobias, Panic disorder, Panic, Middle Aged, medicine.disease, Smell, Clinical Psychology, Phobic Disorders, Needles, Anxiety, Panic Disorder, medicine.symptom, Psychology

Abstract

The authors developed a technique, which they call hypnotherapeutic olfactory conditioning (HOC), for exploiting the ability of scents to arouse potent emotional reactions. During hypnosis, the patient learns to associate pleasant scents with a sense of security and self-control. The patient can subsequently use this newfound association to overcome phobias and prevent panic attacks. This may be especially effective for posttraumatic stress disorder (PTSD) with episodes of anxiety, flashbacks, and dissociation triggered by smells. The authors present 3 cases, patients with needle phobia, panic disorder, and combat-induced PTSD who were successfully treated with the HOC technique.

Published

2009