Fact-checked by Grok 2 weeks ago

Post-normal science

Post-normal science is a problem-solving strategy for scientific inquiries characterized by irreducible uncertainties, contested values, high stakes, and urgent decision needs, particularly in policy domains like environmental risks and public health. Developed by Jerome R. Ravetz and Silvio O. Funtowicz in the early 1990s, it extends beyond traditional "normal" or "applied" science—which relies on probabilistic risk assessment and falsification—by emphasizing extended peer review involving stakeholders beyond experts, dialogue on quality criteria, and recognition that factual resolution alone cannot suffice when societal choices dominate.^[1]^[2] The framework posits a quadrant analysis distinguishing problem types based on systems uncertainty and decision stakes, positioning post-normal conditions opposite routine "normal" science puzzles solvable by standard methods.^[2] In such scenarios, traditional peer review yields to pluralistic validation, where non-scientists contribute to assessing relevance and reliability, aiming to manage rather than eliminate ambiguity.^[1] Applications include climate policy assessments and precautionary approaches to hazards, where empirical data gaps necessitate value-laden judgments.^[3] While proponents view it as enhancing robustness in wicked problems by fostering reflexivity and inclusivity, critics contend it risks undermining scientific objectivity by equating expert knowledge with lay opinions, potentially facilitating advocacy over evidence and eroding public trust in falsifiable claims.^[4]^[5] Empirical evaluations, such as in Dutch environmental modeling, show mixed success, with benefits in transparency but challenges in implementation amid institutional inertia.^[6] This tension highlights post-normal science's defining controversy: whether it pragmatically adapts science to real-world complexity or invites relativism that dilutes causal rigor.^[7]

Origins and Historical Development

Initial Formulation by Funtowicz and Ravetz

Silvio O. Funtowicz and Jerome R. Ravetz introduced the concept of post-normal science in the early 1990s as a response to the limitations of traditional scientific methods in addressing complex policy issues involving high uncertainty and significant societal stakes.^[1] Their foundational work built on earlier explorations of uncertainty in science for policy, detailed in their 1990 book Uncertainty and Quality in Science for Policy, which emphasized the need for new quality controls beyond classical statistical measures when scientific inputs inform decisions with ethical dimensions.^[2] The term "post-normal science" first gained prominence in their 1991 paper "A New Scientific Methodology for Global Environmental Issues," presented at the inaugural conference of the International Society for Ecological Economics, where they argued for a problem-solving strategy suited to global environmental challenges characterized by irreducible uncertainties and value-laden judgments.^[2] This formulation was elaborated in their seminal 1993 article "Science for the Post-Normal Age," published in Futures, which positioned post-normal science as emerging for issues where "facts are uncertain, values in dispute, stakes high and decisions urgent."^[1] In this initial framework, Funtowicz and Ravetz proposed a quadrant model defined by two axes: systems uncertainties (epistemic dimension, ranging from low to high) and decision stakes (axiological dimension, also low to high).^[1] Traditional applied science applies in the low-uncertainty, low-stakes quadrant, while professional consultancy handles low-uncertainty, high-stakes scenarios; post-normal science becomes essential in the high-uncertainty, high-stakes quadrant, necessitating extended peer communities involving non-specialists for quality control and dialogue to manage uncertainties and explicit value judgments.^[1] To operationalize uncertainty management, they introduced the NUSAP notational system—encompassing Numerical value, Unit, Spread, Assessment, and Pedigree—to articulate different layers of uncertainty from technical to epistemological, facilitating better communication in policy contexts.^[1] Examples from their early work included climate change impacts like sea-level rise and biodiversity loss, where conventional risk assessment failed due to modeling limitations and ethical disputes over future generations' rights.^[1] This formulation distinguished post-normal science from Thomas Kuhn's "normal science" by shifting focus from puzzle-solving within paradigms to interactive, democratized processes amid post-modern societal critiques of expertise.^[1]

Evolution Through Environmental and Policy Challenges

The concept of post-normal science emerged in response to environmental crises that revealed the limitations of traditional scientific methodologies in informing high-stakes policy decisions, particularly following the Chernobyl nuclear disaster on April 26, 1986, which dispersed radioactive contaminants across Europe and underscored profound uncertainties in risk prediction, long-term ecological impacts, and health effects.^[1] ^[8] Funtowicz and Ravetz identified these events as exemplifying situations where scientific facts were highly uncertain, decision stakes were existential for affected populations and ecosystems, values regarding safety thresholds and accountability were contested, and policy urgency precluded waiting for complete data resolution.^[1] This catalyzed their initial articulation of post-normal science in 1990, framing it as a strategy for managing such "messy" problems beyond the puzzle-solving paradigm of normal science.^[8] ![Ravetz-Funtowicz-1988.jpg][float-right] Subsequent environmental challenges, including acid rain assessments in the late 1980s and emerging concerns over stratospheric ozone depletion formalized in the 1987 Montreal Protocol, further propelled the framework's development by highlighting the need to integrate qualitative judgments on uncertainty and policy-relevant quality into scientific inputs for international agreements.^[2] By 1993, Funtowicz and Ravetz formalized post-normal science in their seminal Futures article, explicitly linking it to global environmental policy arenas where empirical data gaps—such as nonlinear ecosystem responses and transboundary pollutant effects—necessitated extended peer review involving non-specialist stakeholders to scrutinize assumptions and ethical dimensions.^[1] These evolutions emphasized causal complexities, like feedback loops in atmospheric chemistry, over deterministic models, challenging technocratic reliance on probabilistic risk assessments that often underplayed tail risks.^[2] In policy contexts, the framework evolved through debates on climate change, where the 1992 United Nations Framework Convention on Climate Change (UNFCCC) exposed disputes over emission reduction targets amid incomplete models of anthropogenic forcing and adaptation costs, prompting post-normal approaches to incorporate pluralistic expertise for robust decision-making under deep uncertainty.^[8] Applications in European environmental agencies, such as the Netherlands Environmental Assessment Agency by the early 2000s, demonstrated practical refinements, using post-normal principles to navigate value-laden choices in biodiversity conservation and water management, where traditional science's focus on precision yielded to broader quality criteria addressing societal stakes.^[6] This progression underscored a shift toward democratizing scientific input in policy, countering institutional tendencies to privilege elite expert consensus, as seen in precautionary principle implementations that balanced empirical evidence with ethical imperatives for irreversible environmental thresholds.^[9]

Core Principles and Framework

Definition and Quadrant Model

Post-normal science (PNS) refers to a problem-solving approach for scientific and policy issues characterized by high systems uncertainties, disputed values, elevated decision stakes, and urgent timelines.^[1] Developed by Silvio O. Funtowicz and Jerome R. Ravetz, it emerged as a response to limitations in traditional scientific methods when addressing complex environmental and risk-related problems in the late 20th century.^[2] Unlike conventional science, which prioritizes factual certainty and technical resolution, PNS emphasizes quality control through extended peer review involving diverse stakeholders, explicit management of uncertainties, and integration of ethical considerations into decision-making processes.^[1] The quadrant model, a graphical framework central to PNS, classifies scientific problem-solving strategies along two axes: systems uncertainties (ranging from low technical/methodological levels to high epistemological or ethical indeterminacies) and decision stakes (spanning low single-purpose resolutions to high conflicts among multiple legitimate perspectives).^[2] This biaxial diagram delineates zones rather than rigid quadrants, reflecting a spectrum of approaches. In the inner zone of low uncertainty and low stakes, traditional applied science suffices, relying on established expertise for straightforward applications.^[1] A transitional band of moderate uncertainty and stakes corresponds to professional consultancy, where skilled judgment addresses practical challenges through refined analysis and client-oriented solutions.^[2] PNS occupies the outer zone, activated when both axes reach high values—such as in climate modeling or nuclear risk assessment—necessitating pluralistic input, dialogue among extended peer communities, and reframing "quality" as context-dependent rather than absolute truth.^[1] This model underscores that in PNS scenarios, conventional peer review by specialists proves insufficient, advocating instead for broader validation mechanisms to navigate irreducible uncertainties and value-laden judgments.^[2]

Distinction from Kuhn's Normal Science and Applied Science

Post-normal science (PNS) derives its nomenclature as a deliberate contrast to Thomas Kuhn's concept of normal science, which describes scientific activity as "puzzle-solving" conducted within the secure boundaries of an established paradigm where core assumptions remain unquestioned.^[2] In Kuhn's framework, normal science progresses through incremental verification and refinement, presupposing consensus on fundamentals and minimal systemic uncertainty.^[2] PNS, however, emerges precisely when such paradigmatic stability erodes in the face of irreducible uncertainties, high decision stakes, and contested values, particularly in policy domains like environmental risk or public health crises, rendering traditional puzzle-solving inadequate for guiding action.^[2] Unlike Kuhn's normal science, which operates in insulated academic contexts focused on theoretical advancement, PNS mandates an open, dialogic process involving extended peer communities to scrutinize quality and implications, acknowledging that scientific outputs cannot be treated as detached truths but as inputs to messy decision-making.^[1] The framework of PNS further delineates applied science as occupying the quadrant of low systems uncertainty and low decision stakes, where routine expertise suffices for translating established knowledge into practical solutions, such as engineering optimizations or standard regulatory testing.^[2] In this realm, akin to "safe applied science," methodological reliability is high, and values are largely uncontroversial, allowing professionals to apply validated models without broad societal input.^[2] PNS, by contrast, activates in the opposing quadrant of high uncertainty and high stakes—exemplified by debates over climate impacts or nuclear waste disposal—where applied science's assumptions of factual solidity falter, necessitating pluralistic quality control over mere technical proficiency.^[1] This shift emphasizes managing value disputes through inclusive critique rather than deferring to specialist authority, as applied science presumes the policy environment mirrors the controlled predictability of laboratory conditions.^[2] Thus, while Kuhn's normal science and applied science both thrive under conditions of relative certainty and consensus, PNS reorients scientific practice toward robustness in ambiguity, prioritizing societal dialogue and contextual quality assurance to avert misguided decisions in urgent, contested arenas.^[1]^[2]

Key Elements and Methodologies

Managing Uncertainty, Stakes, and Value Disputes

In post-normal science, uncertainty is managed by distinguishing between reducible statistical variance and irreducible elements such as systemic ignorance and model limitations, rather than seeking to eliminate it entirely. Funtowicz and Ravetz propose the NUSAP notational system—encompassing numerical value, unit, spread (for statistical uncertainty), assessment (for methodological judgments), and pedigree (for foundational assumptions)—to transparently convey these layers in quantitative outputs, enabling policymakers to appraise information quality contextually.^[1] This approach acknowledges that in complex systems, like environmental modeling, uncertainties arise from emergent properties and incomplete knowledge, requiring explicit guidelines for communication rather than mere error bars.^[2] High stakes, often involving irreversible societal or ecological costs, are addressed by reframing scientific input as part of iterative policy exercises, where decision urgency demands proactive inclusion of affected parties to mitigate risks. In the PNS framework's quadrant model, high decision stakes—along the axiological axis—intersect with elevated systems uncertainties to necessitate strategies beyond applied science, such as scenario exploration and sensitivity analyses to reveal robustness under varied assumptions.^[1] For instance, in cases like nuclear waste disposal, stakes escalate when policy threats amplify perceived irreversibility, prompting a shift from expert monopoly to shared responsibility for outcomes.^[2] Value disputes are resolved through extended peer communities, comprising scientists, stakeholders, and lay experts, which facilitate pluralistic critique and dialogue to integrate ethical and cultural dimensions into quality assurance. This extended peer review supplants traditional anonymous refereeing with open scrutiny, allowing disputes over priorities—such as economic growth versus biodiversity preservation—to surface and inform decisions without presuming scientific neutrality.^[1] Tools like citizens' juries and social multi-criteria evaluation further operationalize this by making value trade-offs explicit and transparent, as seen in transport policy debates where public input challenges expert valuations of environmental impacts.^[2] Overall, PNS posits that effective management hinges on ethical norms of transparency and sustainability, ensuring that unresolved values do not paralyze action but guide adaptive responses.^[1]

Extended Peer Communities and Pluralist Expertise

In post-normal science, extended peer communities broaden the scope of peer review beyond credentialed experts to include stakeholders, affected parties, and lay participants who possess relevant experiential knowledge. This expansion, formalized by Silvio Funtowicz and Jerome Ravetz in the early 1990s, recognizes that traditional scientific validation falters in domains of irreducible uncertainty, high decision stakes, and contested values, where diverse inputs enhance overall quality assessment through dialogue and mutual critique.^[2] Such communities operationalize pluralist expertise by integrating "extended facts"—including anecdotal evidence, local observations, and non-quantifiable insights—alongside formal data, thereby addressing blind spots in specialist analyses.^[2] Quality control within these communities shifts from hierarchical expert consensus to process-oriented criteria emphasizing transparency, inclusivity, and accountability, contrasting with the narrow, accreditation-based peer review of normal science. Funtowicz and Ravetz argue this pluralistic approach mitigates risks of expert monopoly, fostering robust governance by reconciling technical precision with ethical and practical dimensions.^[2] For instance, in evaluating sustainable transport policies, entire user populations act as extended peers, scrutinizing scientific models against lived realities to refine outcomes.^[2] Practical mechanisms include citizens' juries, focus groups, and consensus conferences, which have proven effective in hybridizing expert testimony with public deliberation, as seen in environmental and health policy deliberations where non-experts contribute valid competence.^[2] Proponents like Paul Healy contend that institutionalizing these communities—through structured frameworks such as NUSAP (Numerical, Unit, Spread, Assessment, Pedigree) for uncertainty notation—normalizes post-normal practices, building trust amid crises like the UK BSE outbreak or Sydney water contamination incidents, where lay skepticism exposed regulatory oversights.^[10] This pluralist model prioritizes negotiation over adjudication, enabling adaptive decision-making without presuming a singular truth.^[10] Critics within scientific circles, however, caution that extending expertise risks diluting evidentiary standards, potentially amplifying unverified claims under the guise of inclusivity, though advocates maintain that rigorous facilitation distinguishes signal from noise in value-laden contexts.^[2] Empirical applications, such as in risk management dialogues, demonstrate that pluralist engagement correlates with more resilient policies, as diverse scrutiny reveals systemic uncertainties overlooked by siloed expertise.^[10]

Applications and Case Studies

Environmental Risk Assessment and Precautionary Approaches

In environmental risk assessment, post-normal science addresses scenarios where traditional probabilistic methods, such as quantitative risk assessment (QRA), falter due to irreducible uncertainties and high stakes, as categorized by Funtowicz and Ravetz into routine, model-based scientific, and post-normal types.^[2] The post-normal category arises when decision stakes are significant—such as potential irreversible ecological damage from pollutants or habitat loss—and uncertainties extend beyond statistical variability to include systemic ignorance about long-term effects, like endocrine disruption in wildlife.^[11] Here, PNS shifts focus from narrow expert modeling to broader quality assurance, emphasizing dialogue among diverse actors to map uncertainties rather than resolve them definitively.^[12] The precautionary principle, which mandates caution in the face of plausible but unproven harm, aligns closely with PNS by inverting the burden of proof from demonstrating risk to requiring evidence of safety, particularly in environmental policy contexts like chemical regulation or biodiversity conservation.^[13] Ravetz described this integration as the "post-normal science of precaution," where extended peer communities—including affected stakeholders, NGOs, and local knowledge holders—participate in framing problems and scrutinizing assessments, countering the limitations of siloed expert judgments.^[13] For instance, in environmental impact assessments (EIAs) for infrastructure projects, PNS-informed precautionary approaches incorporate pluralistic inputs to evaluate non-quantifiable risks, such as cascading ecosystem effects, ensuring decisions reflect value-laden trade-offs rather than solely empirical probabilities.^[14] Applications in practice, such as at the Netherlands Environmental Assessment Agency, demonstrate PNS facilitating precautionary strategies in long-term policy scenarios, like flood risk management or sustainable land use, by blending quantitative models with qualitative deliberation to handle "deep uncertainty."^[6] This approach has influenced European Union directives on chemicals (REACH, effective 2007), where post-normal elements promote extended review to address data gaps in toxicity testing, prioritizing prevention over post-hoc remediation.^[15] However, implementation requires guarding against selective application, as precautionary measures must balance empirical evidence with societal costs to avoid undue stasis in innovation.^[16]

Public Health and COVID-19 Decision-Making

The COVID-19 pandemic exemplified post-normal science conditions, featuring high systems uncertainty in viral characteristics such as the infection fatality rate—initially estimated by the World Health Organization at 3-4% in March 2020 but later revised downward to around 0.14% globally based on seroprevalence studies—and unpredictable intervention outcomes, alongside stakes encompassing over 7 million reported global deaths and economic losses exceeding $12 trillion by mid-2021, with value-laden debates pitting public health mandates against civil liberties and economic viability.^[17] Decision-makers relied heavily on epidemiological models, such as the Imperial College London's Report 9 released on March 16, 2020, which forecasted up to 2.2 million deaths in the United States and 510,000 in the United Kingdom absent stringent suppression measures, prompting widespread lockdowns despite the models' acknowledged limitations in capturing behavioral responses and long-term societal costs. These projections, rooted in assumptions of an unmitigated basic reproduction number (R0) around 2.4-3.0, underscored the quadrant of post-normal science where facts are uncertain, urging a precautionary posture that prioritized mortality aversion over comprehensive risk-benefit analysis.^[18] Public health responses often deviated from post-normal ideals by centralizing authority in narrow expert circles, sidelining broader peer scrutiny amid urgent timelines. For instance, the Great Barrington Declaration, issued on October 4, 2020, by epidemiologists Martin Kulldorff, Sunetra Gupta, and Jay Bhattacharya, proposed "focused protection" targeting vulnerable populations to mitigate harms from blanket lockdowns—such as a 25% global rise in anxiety and depression reported by the World Health Organization in 2021—while allowing natural immunity buildup in low-risk groups, yet it faced swift institutional rebuke, including efforts by National Institutes of Health Director Francis Collins to orchestrate a "devastating published takedown" of its proponents.^[19]^[20] This episode highlighted a reluctance to embrace extended peer communities, as advocated in post-normal frameworks, where diverse stakeholders including affected citizens and dissenting scientists could contest dominant narratives on mask efficacy or school closures, the latter linked to learning losses equivalent to 0.5 years in some regions per UNESCO data.^[21] In practice, post-normal dynamics manifested in adaptive yet contested strategies, with successes like Taiwan's low mortality rate of 0.04% per capita through transparent data-sharing and community trust contrasting with higher-burden approaches in model-reliant nations, revealing the pitfalls of overemphasizing predictive modeling over qualitative judgment of safety.^[22] Empirical post-hoc analyses, such as those confirming Imperial projections' directional accuracy but overestimation of unmitigated scenarios by factors of 10-100 in suppressed contexts, affirmed the need for uncertainty propagation in models via techniques like N-polygon distributions to better inform policy under value disputes. Ultimately, the pandemic's handling exposed tensions in applying post-normal principles, where institutional incentives favored consensus over pluralism, contributing to policy reversals—such as the U.S. CDC's July 2021 acknowledgment of breakthrough infections undermining zero-COVID goals—and underscoring causal links between restricted debate and prolonged disruptions.^[23]

Climate Policy and High-Stakes Debates

Climate policy debates exemplify post-normal science conditions due to pervasive uncertainties in long-term projections, enormous economic and societal stakes, and irreconcilable value judgments over mitigation strategies versus adaptation priorities. Climate models, such as those underpinning IPCC assessments, exhibit wide ranges in equilibrium climate sensitivity estimates—spanning 1.5°C to 4.5°C or higher in some cases—reflecting incomplete understanding of feedbacks like cloud dynamics and aerosol effects, which empirical observations from satellite data since 1979 have often failed to match in predicted tropospheric warming trends.^[24] ^[25] These uncertainties, compounded by dissent over attribution of recent warming to anthropogenic versus natural forcings, render traditional "normal" scientific consensus insufficient for policy prescription, as Funtowicz and Ravetz argued in their 1993 analysis of the global climate issue.^[26] In practice, post-normal approaches advocate for extended peer communities that incorporate economists, engineers, and empirical skeptics alongside modelers to scrutinize assumptions, as seen in critiques of IPCC processes where procedural transparency has been questioned amid revelations like the 2009 Climategate emails exposing efforts to withhold data and marginalize dissenting views.^[27] ^[28] For instance, the Netherlands Environmental Assessment Agency adopted post-normal guidance in 2003 for uncertainty communication in climate advice, emphasizing pluralistic expertise to avoid overselling model certainties that could mislead policymakers on costs—such as the trillions in global GDP losses projected under aggressive net-zero scenarios by 2050, per analyses from institutions like McKinsey.^[6] ^[29] Yet, institutional biases in bodies like the IPCC, influenced by governmental nominations and consensus-driven summaries, often prioritize alarmist framings that downplay empirical discrepancies, such as the slower-than-modeled sea-level rise observed at 3.3 mm/year from 1993–2023 tide gauge data.^[8]^[30] High-stakes decisions, including the 2015 Paris Agreement's 1.5°C target, underscore value disputes where post-normal science highlights the tension between precautionary mitigation—potentially sacrificing current development in developing nations—and risk-tolerant adaptation favoring empirical monitoring over modeled catastrophes.^[31] Ravetz critiqued climate science in 2012 for applying normal methods to post-normal problems, arguing that quality control failures, like unverified paleoclimate proxies, erode trust when policies impose binding emissions cuts without robust validation against observed data.^[32] Critics of post-normal applications warn that emphasizing subjectivity risks relativism, enabling ideological capture where media and academic consensus—systemically skewed toward interventionist narratives—marginalizes causal analyses showing modest warming impacts relative to historical variability.^[4] Empirical policy outcomes, such as Germany's Energiewende adding over €500 billion in costs by 2023 with minimal global CO2 reduction, illustrate how unaddressed uncertainties in post-normal contexts can lead to inefficient resource allocation.^[8]

Quantitative and Modeling Extensions

Numerical Tools for Uncertainty Quantification

In post-normal science, numerical tools for uncertainty quantification extend beyond traditional statistical error bars to incorporate irreducible uncertainties, model assumptions, and qualitative judgments, particularly in domains with high stakes and value disputes. These tools aim to make uncertainties explicit and communicable to extended peer communities, facilitating dialogue rather than definitive predictions. A prominent example is the NUSAP system, which structures quantitative expressions as Numeral-Unit-Spread-Assessment-Pedigree, where the numeral and unit provide the core value (e.g., 10 km), spread quantifies variability (e.g., ±2 km or 10^{0.8-1.2} km), assessment adds linguistic qualifiers (e.g., "rough" or "reliable"), and pedigree evaluates the data's origin, reliability, and methodological strength through matrices or diagrams.^[33]^[34] Developed by Funtowicz, Ravetz, and van der Sluijs in the 1990s and refined through applications in environmental modeling, NUSAP integrates numerical precision with post-normal emphases on transparency and critique, as seen in assessments of climate sensitivity where pedigree scores highlight reliance on proxy data or expert elicitation.^[35] Sensitivity analysis, particularly global sensitivity analysis (GSA), serves as another numerical tool adapted for post-normal contexts by probing how input variations propagate to model outputs, revealing structural uncertainties in complex systems like ecological or climate models. GSA methods, such as variance-based decomposition (e.g., Sobol indices), decompose output variance into contributions from individual inputs and interactions, using sampling techniques like Latin Hypercube or quasi-Monte Carlo to explore the full parameter space efficiently—often requiring 10^3 to 10^4 model runs for convergence.^[36] In post-normal applications, this evolves into "sensitivity auditing," which mandates scrutiny of boundary judgments, assumptions, and framing effects alongside numerical results, as advocated by Saltelli and colleagues to counter overconfidence in policy-relevant simulations.^[37] For instance, in integrated assessment models for sustainability, GSA has quantified that 20-50% of output variance may stem from non-epistemic factors like discount rates, underscoring value-laden choices.^[38] These tools are often combined; for example, NUSAP pedigree assessments can inform GSA input distributions, while Monte Carlo sampling underpins both for propagating aleatory and epistemic uncertainties in probabilistic risk assessments. However, post-normal critiques highlight limitations: numerical outputs can mask deep ontological uncertainties (e.g., unknown unknowns in system dynamics), necessitating pluralistic validation over rote computation. Empirical applications, such as Dutch environmental policy evaluations since 2000, demonstrate that such tools enhance quality control but require extended peer input to interpret results amid disputes.^[6]^[39]

Mathematical Modeling in Post-Normal Contexts

In post-normal science, mathematical modeling shifts from seeking definitive predictions to facilitating the exploration of plausible scenarios amid irreducible uncertainties, high decision stakes, and contested values. Models serve as tools for framing complex problems, such as environmental risks or policy simulations, where empirical validation is limited by data scarcity or systemic complexity, emphasizing transparency in assumptions and sensitivity analyses over single-point estimates.^[1] This approach acknowledges that model outputs often derive from expert judgments and untestable simulations rather than controlled experiments, as seen in global climate assessments involving intricate causal chains like sea-level rise projections.^[1] A core methodology is the NUSAP system, which annotates model inputs and outputs to manage uncertainty comprehensively: the numeral and unit provide the quantitative base, spread quantifies variability (e.g., via confidence intervals or error bounds), assessment offers qualitative interpretation of reliability, and pedigree evaluates data origins and validation processes.^[33] This framework addresses technical inexactness, methodological choices, and epistemological boundaries with ignorance, enabling extended peer communities—beyond domain experts to include stakeholders—to scrutinize model quality contextually.^[1]^[33] In practice, such as the Netherlands Environmental Assessment Agency's Sustainability Outlook reports, NUSAP integrates with scenario modeling by incorporating diverse worldviews and stakeholder workshops to refine assumptions, treating uncertainty as intrinsic rather than reducible.^[6] Applications highlight modeling's role in policy dialogue, as in integrated assessment models for sustainability, where pluralistic review mitigates overconfidence in outputs amid value disputes.^[6] Critics within post-normal frameworks note risks of models reinforcing preconceived narratives if pedigree assessments are sidelined, underscoring the need for robust, participatory validation to align quantitative rigor with societal stakes.^[1] This synthesis of technical best practices with social scrutiny fosters critical data science for urgent decisions, as advocated in interdisciplinary manifestos bridging modeling and policy.^[40]

Criticisms and Epistemological Debates

Methodological Flaws and Over-Reliance on Subjectivity

Critics contend that post-normal science (PNS) suffers from methodological ambiguities, particularly in its prescription for extended peer review, which lacks a clear, replicable protocol for incorporating diverse stakeholders, thereby risking inconsistent application across cases.^[4] This absence of step-by-step guidance can transform what proponents intend as a pluralistic safeguard into an unstructured process susceptible to dominance by vocal or ideologically aligned participants rather than evidence-based deliberation.^[4] The framework's demarcation of post-normal conditions—characterized by high uncertainty, high stakes, disputed values, and urgent decisions—has been faulted for imprecise boundaries, as illustrated by domains like space exploration, where profound uncertainties exist without correspondingly elevated decision stakes or value conflicts necessitating departure from standard scientific norms.^[4] Such vagueness undermines the methodology's diagnostic utility, potentially leading to overuse in scenarios amenable to conventional empirical resolution, where PNS's emphasis on extended communities could dilute specialized expertise with extraneous inputs.^[4] A primary epistemological concern is PNS's tendency to conflate factual uncertainty with value disputes, fostering an over-reliance on subjective judgments that borders on relativism. By framing problems such that "facts are uncertain, values in dispute, stakes high, and decisions urgent," PNS elevates qualitative "quality" assessments over falsifiable truth claims, which critics argue erodes the pursuit of objective knowledge and invites postmodern skepticism toward de-biasing techniques.^[4] This shift can prioritize stakeholder narratives or precautionary heuristics over quantitative uncertainty quantification, as seen in policy arenas where empirical data on probabilities (e.g., risk assessments yielding specific confidence intervals like 95% for low-probability events) are sidelined in favor of interpretive pluralism.^[4] Moreover, the framework's expansive scope, implying applicability to much of policy-relevant science, blurs distinctions between "normal" problems solvable via rigorous modeling and those warranting post-normal interventions, thereby injecting subjectivity into domains where causal mechanisms can be tested empirically.^[4] Detractors, including those wary of its postmodern underpinnings, warn that this risks institutionalizing bias by de-emphasizing verifiable evidence in favor of consensus-building, potentially validating ideologically driven positions under the guise of inclusivity—for instance, when extended peer reviews amplify unverified precautionary claims over probabilistic forecasts derived from peer-reviewed models.^[4] Empirical instances, such as debates over environmental thresholds where PNS-influenced processes have deferred to subjective risk perceptions despite available statistical tools for variance analysis, highlight how this over-reliance can compromise decision robustness.^[4]

Ideological Biases and Politicization Risks

Post-normal science's framework, which posits that in domains of high uncertainty and stakes, facts and values are intertwined and extended peer communities—including non-experts—should inform assessments, inherently risks amplifying ideological biases by diluting traditional scientific norms of objectivity and empirical rigor. Critics argue that this blurring of boundaries encourages relativism, where absolute truths derived from evidence may be subordinated to subjective value judgments, potentially allowing politically motivated actors to shape outcomes under the guise of pluralism.^[4] For instance, Jerome Ravetz, a co-originator of the concept, acknowledged that extended peers may lack theoretical knowledge and harbor biases, complicating the discernment of robust evidence from advocacy.^[41] The involvement of diverse stakeholders in post-normal processes, while intended to democratize expertise, can facilitate politicization when peer communities are unevenly composed or influenced by dominant ideologies, such as environmental activism. In environmental policy contexts, post-normal science has been critiqued for originating from and advancing "green" agendas that prioritize ecological imperatives over economic or social trade-offs, reflecting an implicit ideological preference rather than neutral deliberation.^[42] Anna Wesselink and Rob Hoppe contend that this approach risks "scientistic hubris," where activist scientists bypass political processes by framing contested values as methodological necessities, thereby entrenching biases without broader democratic accountability.^[42] Such dynamics are evident in climate debates, where post-normal invocations have been associated with heightened politicization, including dramatized statements by scientists to influence policy, undermining public trust in impartial assessment.^[43] Furthermore, the absence of clear protocols for extended peer review exacerbates these risks, as ideologically aligned groups may dominate discourse, leading to inefficient or skewed policy advice. Alex Fergnani warns that scientists' political investments in their findings can produce contradictory results, particularly in fields like environmental science, where high stakes incentivize advocacy over falsification.^[4] This vulnerability is compounded by institutional biases in academia and policy circles promoting post-normal approaches, which often exhibit systemic left-leaning tendencies that favor precautionary or redistributive paradigms, potentially marginalizing dissenting empirical perspectives without rigorous justification. In practice, these mechanisms have contributed to episodes where scientific consensus is invoked not solely on data but on aligned values, fostering perceptions of ideological capture rather than truth-seeking resolution.^[4]^[42]

Empirical Evidence of Policy Failures

Policies adopting post-normal science frameworks, which emphasize high uncertainty, stakes, and value disputes, have frequently invoked the precautionary principle to err on the side of avoiding hypothesized harms, often at the expense of empirically demonstrated benefits. This approach prioritizes type I errors (falsely identifying risks) over type II errors (overlooking benefits), leading to opportunity costs that manifest as measurable human and economic losses.^[44]^[45] In environmental and public health domains, such decisions have delayed or prohibited interventions with strong evidence of net positive outcomes, as retrospective analyses reveal. A prominent case is the 1972 U.S. ban on DDT, driven by concerns over ecological impacts like eggshell thinning in birds amid uncertain long-term human health effects. Prior to restrictions, DDT spraying had eradicated or sharply reduced malaria in regions like Sri Lanka, dropping cases from 2.8 million annually (with 7,300 deaths) to just 17 cases and zero deaths by 1963.^[46] Post-ban, malaria resurged dramatically, with cases climbing back to millions globally; the U.S. National Academy of Sciences estimated DDT had already saved 500 million lives from malaria by 1970.^[47]^[48] The World Health Organization later endorsed indoor DDT spraying for malaria control, highlighting how precautionary restrictions in high-stakes, uncertain contexts prioritized speculative environmental risks over immediate life-saving efficacy, contributing to an estimated tens of millions of preventable deaths in developing nations since the 1970s.^[49] Opposition to nuclear power, framed in post-normal terms as involving irreducible uncertainties and ethical stakes around rare catastrophic risks, has similarly yielded empirical policy shortfalls. Despite nuclear energy's safety record—responsible for averting approximately 1.8 million air pollution-related deaths worldwide from 1971 to 2009 through displacement of fossil fuels—regulatory delays and phase-outs in countries like Germany (post-2000) increased reliance on coal and gas, elevating CO2 emissions by about 200 million tons annually during the transition. Germany's Energiewende policy, which accelerated nuclear shutdowns amid value-laden debates on risk, resulted in per capita emissions rising relative to nuclear-heavy France (at 4.6 tons CO2 vs. Germany's 8.1 tons in 2022), underscoring how precautionary aversion to low-probability accidents overlooked quantifiable benefits in emissions reduction and energy reliability. In the COVID-19 response, post-normal conditions of urgent decisions under modeling uncertainties and disputed values led to widespread lockdowns, whose net effects retrospective studies deem harmful. A meta-analysis of 24 studies found lockdowns reduced COVID-19 mortality by only 0.2% on average, while imposing economic losses exceeding $14 trillion globally in 2020 alone, alongside non-COVID excess deaths from delayed care and mental health declines estimated at hundreds of thousands. In Sweden, which avoided strict measures, all-cause excess mortality through 2021 was lower than in lockdown-heavy European peers (1.05% vs. averages over 5%), suggesting focused protections sufficed without broad harms to education and livelihoods.^[50] These outcomes illustrate how emphasizing worst-case scenarios amid uncertainty amplified type I error biases, yielding policies with disproportionate collateral damage.^[51]

Impact on Broader Scientific Landscape

Connection to Reproducibility and Trust Crises

The reproducibility crisis, marked by systematic failures to replicate findings across disciplines, underscores the uncertainties that characterize post-normal science domains, where empirical validation is complicated by complex systems, small effect sizes, and methodological flexibilities. For instance, a 2015 multicenter effort to replicate 100 psychology experiments succeeded in only 36% of cases, with effect sizes roughly halved compared to originals, revealing pervasive issues like selective reporting and underpowered studies. Similarly, in cancer biology, a 2021 reproducibility project replicated just 46 of 112 experiments from high-profile papers, attributing failures to experimental variability and insufficient controls. These patterns indicate that even in ostensibly "normal" science, reliability erodes under pressure from publication incentives, pushing fields toward post-normal conditions of disputed facts and high stakes.^[52] In post-normal science, as articulated by Funtowicz and Ravetz, reproducibility remains a quality metric but yields to broader criteria like "social robustness"—the capacity of knowledge to withstand scrutiny from extended peer communities amid value disputes and urgency—reflecting causal complexities where predictive replication is infeasible. This shift addresses reproducibility shortfalls by emphasizing transparency in assumptions and pluralistic dialogue over isolated falsification, yet it risks amplifying trust erosion if stakeholders interpret such pluralism as subjective relativism rather than rigorous uncertainty management.^[53] Proponents argue that ignoring post-normality perpetuates crises, as seen in policy-relevant fields where non-replicable models inform decisions, fostering perceptions of elite gatekeeping.^[54] The ensuing trust crisis manifests in declining public confidence, with surveys showing science's favorability dropping from 70% in the U.S. in 2020 to below 60% by 2023 amid controversies over COVID-19 origins and interventions, where post-normal dynamics—blending uncertain evidence with ethical stakes—intensified debates. Post-normal frameworks have been applied to mitigate this, as in 2017 symposia framing "post-truth" eras as opportunities for extended participation to rebuild legitimacy through democratized quality assessment, rather than deferring to institutional expertise alone.^[55] ^[3] However, empirical policy outcomes, such as contested IPCC assessments where model discrepancies fuel skepticism, illustrate how post-normal reliance on negotiated consensus can entrench distrust when underlying reproducibilities falter, demanding meta-level scrutiny of institutional biases in knowledge production.^[56]

Challenges to Science-Policy Boundaries

Post-normal science challenges the conventional separation between science and policy by positing that in contexts of high systems uncertainty and high decision stakes, traditional scientific methodologies and quality controls are insufficient for informing policy. Funtowicz and Ravetz (1993) describe this as requiring an "extended peer community" that includes stakeholders beyond expert scientists, thereby integrating value judgments and social inputs into what was previously viewed as objective fact-finding. This approach democratizes scientific input but inherently blurs boundaries, as policy urgency demands scientists engage directly in framing problems and assessing qualities rather than merely providing data.^[12] Empirical applications reveal tensions in maintaining these boundaries, with advisory organizations like the Intergovernmental Panel on Climate Change (IPCC) operating in a "boundary zone" where science-policy co-production risks politicization and exclusion of dissenting or non-consensus knowledge. For instance, the IPCC's structure facilitates summary-for-policymakers documents negotiated with governments, leading to instances where scientific findings are adjusted to align with political consensus, as critiqued in post-normal analyses of climate assessments. Similarly, the Intergovernmental Science-Policy Platform on Biodiversity and Ecosystem Services (IPBES) employs fuzzy boundaries to incorporate diverse knowledge systems, yet faces erosion through intergovernmental control, resulting in efficiency challenges and limited integration of indigenous inputs. Practitioners emphasize a "close but not too close" dynamic to preserve credibility, but boundary defense often yields to pressures for relevance, amplifying risks of advocacy over neutrality.^[57]^[32] These challenges extend to broader risks of ideological biases infiltrating scientific discourse, particularly in environmental policy where post-normal frameworks invite extended participation that can prioritize contested values over empirical resolution. In high-stakes domains like fisheries management at the International Council for the Exploration of the Sea (ICES), strict boundary maintenance via linear models has been tested by stakeholder inclusion demands since the 1980s, leading to tools like catch-option tables to mitigate political override while still facing erosion attempts. Overall, while post-normal science aims to enhance decision quality through inclusivity, it often results in mutual transgressions between science and policy, potentially undermining public trust when perceived as yielding to non-scientific imperatives.^[57]^[2]

Recent Developments and Global Perspectives

Post-Pandemic and Ethical Reflections

The COVID-19 pandemic, which began in late 2019 and led to over 7 million reported deaths globally by mid-2025, exemplified the conditions of post-normal science through pervasive uncertainties in epidemiological modeling, transmission dynamics, and intervention efficacy, coupled with high stakes involving public health, economic disruption estimated at $12.5 trillion in global losses by 2021, and disputes over values such as individual liberties versus collective safety.^[22] Post-pandemic analyses framed it as a "perfect postnormal storm" characterized by rapid spread (e.g., 2.5 million cases within five months of identification), global scope, systemic complexity, and simultaneous crises in health, economy, and governance, necessitating approaches beyond traditional risk assessment to incorporate ignorance and pluralism.^[22] Reflections on recovery emphasized integrating post-normal principles to address systemic fragilities, such as insufficient medical capacity in efficient economies like the US and UK, which lacked reserves due to cost-cutting priorities, and vulnerabilities among marginalized populations including the homeless and immigrants.^[18] Jerome Ravetz, in June 2020, advocated for a resilience-oriented framework drawing from C.S. Holling's work, prioritizing safety margins over precise risk quantification and engaging the public as an "extended peer community" to foster dialogue on ethical trade-offs, akin to historical cases like the community-driven discovery of Lyme disease.^[18] This approach aimed to rebuild trust eroded by top-down policies, promoting transnormal futures that challenge pre-pandemic growth paradigms and reassess democracy's alignment with emergency measures.^[22] Ethically, post-normal science highlights the motivation to navigate disputed values without conflating facts and norms, yet critiques warn of risks in high-uncertainty scenarios like pandemics, where inclusive peer review lacks clear protocols, potentially leading to relativism that undermines empirical rigor and invites ideological distortions.^[58]^[4] For instance, while extended expertise could enhance legitimacy by balancing health outcomes with rights, overambitious application might obscure modellable elements, such as vaccine rollout logistics, echoing historical pandemics where complexity did not preclude evidence-based decisions.^[4] These reflections underscore the need for methodological safeguards to prevent post-normal framing from excusing policy failures, such as inconsistent messaging on masks or origins, while upholding causal accountability in science-policy interfaces.^[18]

Applications in the Global South and Emerging Critiques

In the Philippines, post-normal science principles have been applied to public health crises and infrastructure projects amid resource constraints and limited expert pools. During the COVID-19 pandemic starting in 2020, the independent research group OCTA incorporated extended peer communities beyond medical experts, including economists and social scientists, to analyze Department of Health data drops initiated on April 15, 2020, and produce weekly epidemiological forecasts that influenced lockdown policies such as enhanced community quarantines.^[59] Similarly, in the New Manila International Airport reclamation project in Bulacan, citizen science approaches aligned with post-normal frameworks assessed risk perceptions among marginalized coastal communities using the Protective Action Decision Model, integrating local knowledge to inform environmental decisions.^[59] In Mexico, a 2024 public consultation in Morelia for urban environmental conservation attempted to form extended peer communities to address high-stakes biodiversity issues, emphasizing pluralism in decision-making processes.^[60] These applications highlight post-normal science's potential to bridge evidence gaps in contexts with sparse scientific capacity, such as the Philippines' 172 researchers per million people reported by UNESCO in 2020, compared to over 4,800 in the UK.^[59] However, implementations often prioritize epistemological inclusion and consensus-building tailored to local social dynamics, differing from Global North emphases on formal peer review and technocratic structures. In the 2015 Philippine Supreme Court ruling banning Bt eggplant field trials amid GMO debates, the absence of robust extended peer review underscored opportunities for post-normal approaches to incorporate diverse stakeholder inputs where scientific consensus is contested.^[59] Emerging critiques in Global South contexts question the feasibility of extended peer communities under prevailing power imbalances and coercion risks. Orozco-Meléndez et al. (2024) argue that such communities are highly context-dependent, often failing to resolve political controversies in Latin America due to violence and institutional pressures, as observed in Mexico's conservation efforts, necessitating prior analysis of enabling conditions rather than assuming democratic emergence.^[60] In the Philippines, critiques highlight "red-tagging" and technocratic dominance that hinder inclusive knowledge production, exacerbating distrust in science advice despite post-normal intentions.^[59] Broader recent concerns, per Fergnani (2023), warn of post-normal science's vulnerability to politicization, where conflating facts with values risks prioritizing ideological agendas like anti-capitalist narratives over empirical rigor, lacking clear methodological protocols for equitable peer extension.^[4] These critiques emphasize that without addressing structural asymmetries, post-normal frameworks may amplify rather than mitigate decision-making flaws in unequal societies.^[60]^[59]

References

[1]
[PDF] SCIENCE FOR THE POST-NORMAL AGE - Andrea Saltelli
In response to the challenges of policy issues of risk and the environment, a new type of science-'post-normal'-is emerging. This is analysed in.
[2]
[PDF] Post-Normal Science
Introduction. Post-Normal Science (PNS) is a new conception of the management of complex science-related issues. It focuses on aspects of problem solving ...
[3]
Post-normal science in practice - ScienceDirect.com
In 1993, Silvio Funtowicz and Jerome Ravetz published their seminal work “Science for the Post-Normal Age” in this journal. It is now by far the best cited ...
[4]
Explaining and critiquing the postnormal: A warning against ...
May 17, 2023 · In response to and as a prevention of this risk, this article explains and critiques the two frameworks. It explains that post-normal science is ...WHAT IS POST-NORMAL... · A CRITIQUE OF THE POST... · A CRITIQUE OF THE...
[5]
Post-normal science in practice: Reflections from scientific experts ...
Post-Normal Science (PNS) emphasises the need for scientists and policy-makers to iteratively co-analyse and learn together, as part of an extended peer ...
[6]
Post-Normal Science in Practice at the Netherlands Environmental ...
PNS is often misunderstood as something that replaces normal science. It should instead be seen as a societal problem-solving strategy that partly draws on ...
[7]
Where Now for Post-Normal Science?: A Critical Review of its ...
Dec 7, 2010 · This editorial article introduces a Special Issue that takes stock of research on PNS and critically explores how such research may develop.Missing: criticisms | Show results with:criticisms
[8]
Introduction: Post-Normal Climate Science - Berghahn Journals
science in mind: Silvio Funtowicz and Jerry Ravetz (1990) developed the concept after the explosion of the Chernobyl nuclear power plant and after the ...
[9]
[PDF] Environmental problems, post-normal science, and extended ... - HAL
For these new problems science usually cannot provide well-founded theories, based on experiments, for explanation and prediction; therefore environmental ...
[10]
[PDF] Extended peer communities and the ascendance of post-normal ...
This paper argues that the 'normalisation' of post-normal science that this necessitates requires the institutionalisation of extended peer communities and that ...
[11]
Uncertainty, complexity and post‐normal science - Funtowicz - 1994
Uncertainty, complexity and post-normal science. Silvio O. Funtowicz,. Corresponding Author. Silvio O. Funtowicz. CEC Joint Research Centre, Institute for ...Missing: original | Show results with:original
[12]
Science for the post-normal age - ScienceDirect.com
Post-normal science can provide a path to the democratization of science, and also a response to the current tendencies to post-modernity. Previous article ...
[13]
The post-normal science of precaution - ScienceDirect.com
It addresses issues where, typically, facts are uncertain, values in dispute, stakes high and decisions urgent [8]. The post-normal style of problem-solving has ...Missing: axes | Show results with:axes
[14]
The precautionary principle and management of uncertainties in EIAs
The precautionary principle can be defined as environmental protection based on precaution, even where there is no clear evidence of harm or risk from an ...
[15]
The post-normal science of precaution - ScienceDirect.com
The 'post-normal' approach embodies the precautionary principle. It depends on public debate, and involves an essential role for the 'extended peer community'.
[16]
Post-Normal Science, the Precautionary Principle and the Ethics of ...
I argue that, taking in considerations the precautionary principle, and adopting the perspective of post-normal science, the ethics of integrity suggest a ...
[17]
Revisiting the initial COVID-19 pandemic projections - PMC
Mar 2, 2021 · One critical report, published on March 16, 2020, received international attention when it predicted 2 200 000 deaths in the USA and 510 000 deaths in the UK.
[18]
Pandemic Recovery Requires Post-Normal Science
Jun 19, 2020 · Standard notions of science undercut our ability to respond to COVID-19. Post-normal science offers a vision that matches the complexity of ...
[19]
Great Barrington Declaration
We have grave concerns about the damaging physical and mental health impacts of the prevailing COVID-19 policies, and recommend an approach we call Focused ...Pagpahayag sa Great Barrington · Declaration · Signatures · Video
[20]
NIH director Francis Collins wanted a 'take-down' to stifle Covid-19 ...
Dec 23, 2021 · At the time, he believed the Great Barrington Declaration idea of focused protection would result in more deaths than the alternative view of ...Missing: dissent | Show results with:dissent
[21]
Post-normal pandemics: Why COVID-19 requires a new approach to ...
Mar 25, 2020 · ... Post-Normal Science (PNS), a new understanding of science for situations ... The expertise employed in COVID-19 policy advice builds on ...Missing: making | Show results with:making
[22]
The Perfect Postnormal Storm: COVID-19 Chronicles (2020 Edition)
This essay addresses the COVID-19 pandemic as a case study in postnormal times phenomena: a perfect postnormal storm.
[23]
Post-Normal Challenges of COVID-19: Constructing Effective and ...
Jun 7, 2021 · We investigate and recommend processes and measures to address COVID-19 that support increased public health, while upholding established rights and values.
[24]
Climate Science and the Uncertainty Monster in - AMS Journals
This paper provides a perspective on exploring ways to understand, assess, and reason about uncertainty in climate science, including application to the ...<|separator|>
[25]
[PDF] Uncertainty and Dissent in Climate Risk Assessment: A Post-Normal ...
Change (IPCC), post-normal science, science-policy interface, uncertainty. Introduction. Anthropogenic climate change is a complex and contested issue. The.<|separator|>
[26]
Post-Normal Science and the Global Climate Change Issue
Aug 9, 2025 · The above discussion highlights the inherent uncertainty in the sustainability of wind energy and its reliance on a 'post-normal' approach based ...
[27]
Lessons from post‐normal science for climate science‐sceptic debates
Jul 16, 2012 · Post-normal science (PNS) is one way to think about the role of science and expertise more generally in addressing problems like climate change.<|control11|><|separator|>
[28]
[PDF] Post-normal Journalism: Climate Journalism and Its Changing ...
in the debate around “Climategate” were in fact an “exemplification of post-normal science, with the role of extended peer community being filled by the critics ...<|separator|>
[29]
[PDF] Climate change, the uncertainty monster and post normal science
Aug 30, 2018 · Overselling certainty creates vulnerabilities in scientific basis for policy – will be exploited! • Quality control & Fact checking essential. • ...
[30]
[PDF] Integrated Risk and Uncertainty Assessment of Climate Change ...
The IPCC strives for a treatment of risk and uncertainty that is consis- tent across all three Working Groups based the Guidance Note (GN) for Lead Authors of ...
[31]
climate change from a post-normal science perspective
Aug 7, 2025 · ... climate change from the perspective of Post-Normal Science. The ... climate policy is. justifiable when scientific uncertainties and ...
[32]
[PDF] Jerome Ravetz - Center for Science and Technology Policy Research
The conceptual weakness here is worse than the application of. "normal science" methodologies to post-normal conditions. We have a case where the assumptions ...
[33]
Post Normal Science - NUSAP net
The most general methodology for managing complex science-related issues is "Post-Normal Science" (Funtowicz and Ravetz 1992, 1993, Futures 1999).
[34]
A quick guide to post-normal science
Oct 19, 2021 · Post-normal science comes into play for decision-making on policy issues where facts are uncertain, values in dispute, stakes high and decisions urgent.
[35]
[PDF] The worth of a songbird: ecological economics as a post-normal ...
On the basis of our experience, we believe that the techniques and insights of the. NUSAP system enable uncertainties to be man- aged for the achievement of ...
[36]
The Future of Sensitivity Analysis: An essential discipline for systems ...
Sensitivity analysis (SA), in the most general sense, is the study of how the 'outputs' of a 'system' are related to, and are influenced by, its 'inputs'. In ...
[37]
Sensitivity auditing: A practical checklist for auditing decision ...
Aug 24, 2023 · Sensitivity auditing, that is also inspired by the epistemology of post-normal science, calls on modellers to examine the assumptions during ...Introduction · Nutrition And Public Health... · Food Security<|separator|>
[38]
An annotated timeline of sensitivity analysis - ScienceDirect.com
The manuscript offers a detailed timeline of sensitivity analysis, tracing its evolution from local to global methods.
[39]
[PDF] 29 THE NUSAP APPROACH TO UNCERTAINTY APPRAISAL AND ...
Jan 11, 2017 · NUSAP is a notational system, proposed in the context of post-normal science by Funtowicz and Ravetz (1990), which aims to provide an analysis ...
[40]
A modeler's manifesto: Synthesizing modeling best practices with ...
... Mathematical Modeling for Public Health Policymaking . Frontiers in ... Post-normal science in practice at the Netherlands Environmental Assessment Agency.
[41]
[PDF] Pos -normal science: A new science for new times - Andrea Saltelli
In post-normal science there is still a dis- tinction between insiders and outsiders, based (on the cognitive side) on certified expertise and (on the social ...
[42]
(PDF) If Post-Normal Science, is the Solution, What is the Problem?
Aug 9, 2025 · Post-normal science (PNS) is presented by its proponents as a new way of doing science that deals with uncertainties, value diversity or ...
[43]
Against politicization of science: Comment on S. Keller: Scientization ...
These types of complaints are typical for science in a post-normal situation, where uncertainty is inherently high, stakes are high and societal values are ...
[44]
The Precautionary Principle: Scientific Uncertainty and Type I and ...
The Precautionary Principle: Scientific Uncertainty and Type I and Type II Errors ... Avoid common mistakes on your manuscript. References. Cranor, C. (1993) ...Missing: failures | Show results with:failures
[45]
How Many Lives Are Lost Due to the Precautionary Principle?
Oct 31, 2019 · When public policy is shaped by precautionary principle ... failure: "The direct implication of trial without error is obvious ...
[46]
The Legacy of the DDT Ban - PERC
Jun 1, 2001 · In Sri Lanka, malaria cases fell from 2.8 million and 7,300 deaths per year before DDT spraying, to 17 cases and no deaths (Roberts, Manguin, ...<|separator|>
[47]
Bring Back DDT | Cato Institute
Apr 26, 2016 · The US National Academy of Sciences estimated DDT had saved 500 million lives from malaria by 1970. In India, effective spraying had virtually ...
[48]
[PDF] THE DDT BAN TURNS 30 — Millions Dead of Malaria Because of ...
Millions Dead of Malaria Because of Ban, More Deaths ... lost to malaria every thirty seconds). Many medical ...
[49]
Attempts to ban DDT have increased deaths - PMC - NIH
The study shows that after malaria was eradicated in wealthy countries and DDT was banned in those places, poor countries were pressured by health and donor ...
[50]
Is the cure really worse than the disease? The health impacts of ...
Jul 19, 2021 · It is impossible to determine from this evidence whether lockdowns have a net benefit, especially given the very high excess mortality in many ...
[51]
Rational policymaking during a pandemic - PNAS
As COVID-19 is a new disease and its global impacts are unprecedented, decisions are taken in a highly uncertain, complex, and rapidly changing environment. In ...
[52]
Post-normal institutional identities: Quality assurance, reflexivity and ...
This paper suggests adopting a 'post-normal science' (PNS) style and practice in scientific advice, and motivate the urgency of this methodological stance.Missing: characteristics applications
[53]
What is Post-normal Science? A Personal Encounter
Nov 10, 2023 · Post-normal science is extremely clear in delimiting its applicability to practical and problematic situations, rather than fundamental research.
[54]
"A formidable share of the research we pay for is simply wrong"
Oct 24, 2018 · ... reproducibility crisis” or “the replication crisis”: It turns out ... post-normal science.” It entails being open about uncertainty ...
[55]
Post-truth and a crisis of trust? 25-26 Sept 2017, Tübingen
May 9, 2017 · In its ambiguity, the idea of a 'post-truth' age manifests a crisis of trust in both democratic and scientific institutions. ... post-normal ...
[56]
(PDF) Climate science, IPCC, postnormality and the crisis of trust
Climate science, IPCC, postnormality and the crisis of trust Hans von Storch ... science by popular vote; also that postnormal science would be abnormal science.
[57]
'Close but not too close' – experiences of science-policy bridging in ...
Jan 20, 2022 · ... science-policy boundaries are structured and defended). To ... post-normal-science' with increased participation, stakeholder ...
[58]
The ethical motivation for post-normal science - ScienceDirect.com
This paper focuses on the concept of post-normal science, originally proposed by Silvio Funtowicz and Jerome Ravetz, as an advanced method of knowledge ...<|control11|><|separator|>
[59]
[PDF] Problems and Opportunities in Post-Normal Science and ... - UP CIDS
PNS can minimize science policy failures when there is a lack of consensus on risk even if normal scientific theory is clear on experimental results. The.
[60]
Problematizing post-normal science in the Global South
To take on problems characterized by uncertain facts, contested social values, high stakes, and the need for urgent decisions (such as complex environmental ...Missing: criticisms | Show results with:criticisms