Jin-Lee Kim, Ph.D., P.E. Civil Engineering & Construction Engineering Management
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Transcript of Jin-Lee Kim, Ph.D., P.E. Civil Engineering & Construction Engineering Management
Jin-Lee Kim, Ph.D., P.E.Civil Engineering & Construction Engineering Management
California State University, Long Beach
Ethics in Sustainability in Green Construction
What is Sustainable Development?
What is Sustainability in Green Construction?
An integrative effort to transform the way built environments are designed, constructed, and operated
Why is sustainability in green construction necessary?
Primary energy use 40% Electricity consumption 72% CO2 emissions 39% Potable water consumption 13.6%
Global CO2 emissions by sector
#1 Buildings
#2 Transportation
#3 Industry
Why is sustainability in green construction necessary?
Green buildings can reduce
Energy use 24~50%
CO2 Emissions 33~39%
Water use 40%
Solid waste 70%
Green occupants are healthier & more productive In the U.S., people spend, on average, 90% or more of
their time indoors Have better indoor air quality & lighting
How to define sustainable construction?
Phase
Resources
Principles
Land Materials Water EnergyEcosystem
s
PlanningDevelopment
DesignConstruction
Use & OperationMaintenance
ModificationDeconstruction
1. Reduce2. Reuse3. Recycle4. Protect nature5. Eliminate toxics6. LCC7. Quality
Triple Bottom Lines for Sustainable Development
To establish metrics and rating systems for measuring buildings
The Structure of Matter & the Material World
“In short, physics has discovered
that there are no solids,
no continuous surfaces,
no straight lines;
only waves,
no things
only energy event complexes,
only behaviors,
only verbs,
only relationships.”
By R. Buckminster Fuller, mathematician and engineer(Ref.: Fuller, Buckminster. 1983. Intuition. 2nd Edition, San Luis Obispo, California: Impact Publishers.)
Basic Concepts and Vocabulary
Industry Ecology
The study of the physical, chemical, and biological interactions and interrelationships both between and among industrial and ecological systems
Basic Concepts and Vocabulary
Construction Ecology A subcategory of industrial ecology for built
environment (1) Has a closed-loop materials system integrated with eco-industrial and natural
systems (2) Depends on renewable energy sources (3) Fosters the preservation of natural system functions
Application of these principles (1) Are readily deconstructable at the end of their useful lives (2) Have components that are decoupled from the building for easy replacement (3) Are composed of products designed for recycling (4) Are built using recyclable, bulk structural materials (5) Have slow “metabolisms” due to their durability and adaptability (6) Promote the health of their human occupants
Basic Concepts and Vocabulary
Biomimicry The direct application of ecological concepts to the
production of industrial objects
Design for the Environment (DfE) = Green design Environmental considerations into product and process
engineering procedures, considering the entire product life cycle
Front-loaded design The investment of greater effort during the design phase to
ensure the recovery, reuse, and/or recycling of the product’s components
E.g. design for disassembly, recycling, reuse, remanufacturing, etc.
Basic Concepts and Vocabulary
Ecological Economics The relationship between human economies and natural
ecosystems
Carrying Capacity The limits of a specific land’s capability to support people
and their activities
Ecological Footprint The land area required to support a certain population or
activity The inverse of carrying capacity The amount of land needed to support a given population
Basic Concepts and Vocabulary
Ecological Rucksack and MIPS To quantify the mass of materials that must be moved in
order to extract a specific resource
Ecological Rucksack of Some Well-Known Materials
Material Ecological Rucksack
Rubber 5
Aluminum 85
Recycled aluminum 4
Steel 21
Recycled steel 5
Platinum 350,000
Gold 540,000
Diamond 53,000,000
Basic Concepts and Vocabulary
Ecological Rucksack and MIPS
Materials Intensity per Unit Service (MIPS) Measures how much service a given product delivers The higher or greater the service, the lower the MIPS value An indicator of resource productivity, or eco-efficiency
Basic Concepts and Vocabulary
The Biophilia Hypothesis An innate love for the natural world, supposed to be felt
universally by humankind Nine values of biophilia offering a broad design template for
sustainable building (1) Utilitarian value (2) Aesthetic value (3) Scientific value (4) Symbolic value (5) Naturalistic value (6) Humanistic value (7) Dominionistic value (8) Moralistic value (9) Negativistic value
Basic Concepts and Vocabulary
1. Reducing the material requirements of goods and services
2. Reducing the energy intensity of goods and services
3. Reducing toxic dispersion
4. Enhancing materials recyclability
5. Maximizing sustainable use of renewable resources
6. Extending product durability
7. Increasing the service intensity of goods and services
Eco-Efficiency Seven elements of eco-efficiency (World Business Council on Sustainable Development)
Basic Concepts and Vocabulary
The Natural Step A framework for considering the effects of
materials selection on human health
Life-Cycle Assessment (LCA) A method for determining the environmental and
resource impacts of a material, a product, or even a whole building over its entire life
Life-Cycle Costing (LCC) A building’s financial performance over its life cycle Can be combined with LCA to consider both impacts
Basic Concepts and Vocabulary
Embodied Energy The total energy consumed in the acquisition and
processing of raw materials, including manufacturing, transportation, and final installation
Products with greater embodied energy have higher environmental impact due to the emissions and GHG
A truer indicator of the environmental impact = The embodied energy / the product’s time in use
More durable products will have a lower embodied energy per time in use
Basic Concepts and Vocabulary
Factor 4 and Factor 10 A set of guideline for comparing design options and for
evaluating the performance of buildings and their component systems
Factor 4 Factor Four: Doubling Wealth, Halving Resource Use Suggests reducing resource consumption to one-quarter of
its current levels
Factor 10: a parallel approach to Factor 4 Reducing resource consumption by a factor of 10
Major Environmental & Resource Concerns
Major environmental issues connected to built environment design and construction
Climate change Ozone depletion Soil erosion Desertification Deforestation Eutrophication Acidification Loss of biodiversity Land, water, and air pollution Dispersion of toxic substances Depletion of fisheries
Major Environmental & Resource Concerns
1. Climate Change and Ozone Depletion Climate change
Long-term fluctuations in temperature, precipitation, wind, and all other aspects of the Earth’s climate
Ozone depletion Caused by the interaction of halogens-chloine-
and bromine-containing gases such as chlorofluorocarbons (CFCs) use in refrigeration and form blowing, and halons used for fire suppression
Major Environmental & Resource Concerns
2. Deforestation, Desertification, and Soil Erosion
Deforestation Large-scale forest removal
Desertification The destruction of natural vegetative cover
Soil Erosion A key factor in land degradation
Major Environmental & Resource Concerns
3. Eutrophication and Acidification
Eutrophication The overenrichment of water bodies with nutrients from
agricultural and landscape fertilizer, urban runoff, sewage discharge, and eroded stream banks
Acidification The process whereby air pollution in the form of ammonia,
sulfur dioxide, and nitrogen oxides, mainly released into the atmosphere by burning fossil fuels, is converted into acids
The resulting acid rain makes damages to forests and lakes
Major Environmental & Resource Concerns
4. Loss of Biodiversity The variety and variability of living organisms and
the ecosystems in which they occur 5. Toxic Substances and Endocrine Disruptors
Toxic substances A chemical causing death, disease, behavioral abnormalities, cancer,
genetic mutations, physiological or reproductive malfunctions, or physical deformities in any organism or its offspring, or that can become poisonous after concentration in the food chain or in combination with any other substances
Endocrine-disrupting chemicals Interfere with the hormones produced by the endocrine
system (e.g., dioxin, various pesticides, etc.) 6. Depletion of Metal Stocks
Why do we need ethics in sustainable development?
Ethics must be broadened to address relationships between people by providing rules of conduct that are generally agreed to govern the good behavior of contemporaries
In the context of sustainable development and sustainable construction, a more extensive set of ethical principles is required to guide ethical behavior
What ethical challenges do we face in sustainable development?
To make decisions about how to move forward to sustainable development over the generations
(1) An ethical framework that represents society’s general moral attitudes toward life and future generations
(2) An understanding of and willingness to accept risk (3) The economic costs of implementation and resulting
impacts
Ethical principles 1Intergenerational Justice & the Chain of Obligation
The concept that the choices of today’s generations will directly affect the quality and quantity of resource remaining for future inhabitants of Earth and environmental quality
This concept will include parent’s responsibility for enabling their offspring to meet their moral obligations to their children and beyond
Ethical principles 2Distributional Equity (Distributive Justice)
An obligation to ensure fair distribution of resources among present people in order to address the life prospects of all people on Earth
For example, resources include materials, land, energy, water, and high environmental quality
Six sub-principles in this concept: 1) Difference principle
2) Resource-based principles
3) Welfare-based principles
4) Desert-based principles
5) Libertarian principles
6) Feminist principles
Ethical principles 3Precautionary Principle
This principle requires the exercise of caution when making decisions that may adversely affect nature, natural ecosystems, and global biogeochemical cycles
Global climate change is an excellent example of the need to act with caution, which is the hottest topic in sustainability in green construction
The fundamental premise is that those who are responsible for implementing technologies must be prepared to address the consequences of their implementation
Ethical principles 4Reversibility Principle
It is notable that decision made by current generations can be undone by future generations
This principle is related to the precautionary principle in that the criteria must be observed before any adoption of a new technology
Like the precautionary principle, the fundamental premise of this principle is that those who are responsible for implementing technologies must be prepared to address the consequences of their implementation
Ethical principles 5Polluter Pays Principle and Producer Responsibility
Polluter pays principle addresses existing technologies that have not been subject to these other principles, while producer responsibility addresses whole life-cycle environmental problems of the production process from initial minimization of resource usage to recovery and recycling of products from waste
Mitigating damage and consequences on the individuals causing the impacts
Ethical principles 6Protecting the Vulnerable
There are vulnerable due to the destruction of ecosystems under the guise of development, introduction of technology, and general patterns of conduct
Toxic substances, endocrine disruptors, and genetically modified organisms are examples of technology introduction
To name a few, the examples of general patterns of conduct include war, deforestation, soil erosion, eutrophication, desertification, and acid rain
This ethical principle is vital because an enormous responsibility is placed on Earth’s present population
Ethical principles 7Protecting the Rights of the Nonhuman World
The extension of the principle of protecting the vulnerable to plants, animals, bacteria, viruses, mold, and other living organisms
Humans should consider restoring nature in all our activities, righting the wrongs of the past, and restoring the badly needed link between humans and nature
Ethical principles 8Respect for Nature and the Land Ethic
An ethics of respect for nature is based on the fundamental concepts that humans are members of the Earth’s community of life, all species are interconnected in a web of life, each species is a teleological center of life pursuing good in its own way, and human beings are not superior to other species
Nature’s Conscious Representatives
“In the end
We will conserve only what we love,
We love only what we understand,
We will understand only what we are taught.”
By Baba Dioum, Senegalese Ecologist(Ref.: Baba Dioum, Senegalese Ecologist. He is the General Coordinator of the Conference of Ministers of West and Central Africa, and
organization that represents 20 African countries. This quote is taken from a speech made in New Delhi, India, to the general assembly of the International Union for the Conservation of Nature.)
Reading Assignments for Technical Report Eisenberg, David and Reed, William. 2003. “Regenerative Design: Toward the Re-Integration of Human Systems with
Nature.” IAEA, 2000. Ethical considerations in protecting the environment from the effects of ionizing radiation, International
Atomic Energy Agency, IAEA, VIENNA. Dwivedi, O. P. 2008. “An ethical approach to environmental protection: a code of conduct and guiding principles,”
Canadian Public Administration, 35(3), pp. 363-380. Peterson, Gary. 1999. “Ecology of Construction,” in Construction Ecology: Ecology as the Basis for Green Buildings,
Charles J. Kibert, Jan Sendzimir, and Bradley Guy, eds. London: Spon Press. Wang, Wilfried. 2003. “Sustainability is a Cultural Problem,” Harvard Design Magazine, Spring/Summer 2003, No. 18. Goodin, Robert E. 1983. “Ethical Principles for Environmental Protection,” in Environmental Philosohpy, R. Elliot and
A. Gare, eds. London: Open University Press. Angyal, Thomas J. 2003. “Thomas Berry’s Earth Spirituality and the ‘Great Work,’” The Ecozoic Reader, 3, pp. 35-44. Berry, Thomas. 2002. “Rights of the Earth: Earth Democracy,” Resurgence, 214, pp. 28-29. Leopold, Aldo. 1949. A Sand County Almanac. New York: Oxford University Press. Taylor, Paul W. 1981. “The Ethics of Respect for Nature,” Environmental Ethics, 3, pp. 206-218. Fuller, Buckminster. 1983. Intuition. 2nd Edition, San Luis Obispo, California: Impact Publishers. Our Common Future, Bruntland Report, 1987. UN World Commission on Environment and Development, Oxford,
England: Oxford University Press. Howarth, Richard B. 1992. “International Justice and the Chain of Obligation,” Environmental Values, 1, Isle of Harris,
U.K.: White Horse Press. Center for Community Action and Environmental Justices, accessed from www.ccaej.org Drexler, K. Eric 1987. Engines of Creation. New York: Anchor Books. Rochlin, Gene I. 1978. “Nuclear Waste Disposal: Two Social Criteria,” Science, 195, pp. 23-31.