Some basic mitigation measures are very efficient

Some basic mitigation measures are very efficient

The risk associated with water pollution is more complex. Obviously, pollution of ground water must be avoided. Pollution of a water stream would be limited due to the mercury being diluted by the flow of the water body. But if a water reservoir is involved (natural or man made), mercury can accumulate over time, contaminating the food chain. This particular case is site-specific and should be further analyzed when relevant. This issue should be considered when choosing the site of the facility, as well as other site characteristics that would help control the environmental impact, in particular good geological permeability, no ground water in low deep beds, and other water bodies under some conditions. In addition, basic engineered landfill design is essential. A liner underneath will prevent soil pollution from most of the pollutants and avoid pollution of the ground water. Leachate is collected and evacuated (after treatment) to an environment where the risk is lower. These are actually basic requirements under most national environmental regulations.

In general, for all the cases when the risk is low because lamp concentration is mostly low and mercury is freely released into the outdoor atmosphere, where it is rapidly diluted by wind, it can still be mitigated by good practice. In particular, some simple rules can help control the impact on the environment to ensure that exposure is minimal. For example, urban development (residential or business, except for the purpose of waste treatment) should be absolutely prohibited in the vicinity of the waste treatment facility. This is also a basic requirement under most national environmental regulations. To minimize the risk of exposure for the population, treatment sites (plants or landfills) should be built as far away as possible from existing human habitat, crops, livestock, water bodies, etc. and access to the site should be very strictly regulated and prohibited to the general public.

The next step: mercury containment in EOL waste management

Once mercury is contained, it can be recovered. Powders containing mercury are extracted from the bulbs (as in the previous solution), and then distillated to be recycled. Pure metal mercury is thus produced and can be reused. This requires a downstream market for mercury, which must also be controlled to avoid further dangerous emissions (for example, mercury use in gold mining must be prohibited). An advantage of this solution is that it reduces the quantity of primary mercury that needs to be extracted.

Peripheral considerations

It is also important to assess the potential for proper collection systems and their impact on the options presented above. MCL waste may be collected either separately (necessary for mercury extraction and mercury recovery) or together with municipal waste. Separate collection is based on container systems that can be transported as general cargo, and might take place as a ’lamps-only’ collection or with other hazardous waste collection either from private households (requires collection points) or businesses (where pre-crushing is also an option that can reduce the amounts that have to be transported), or with the collection of non-hazardous commercial waste.

Furthermore, the treatment options listed above involve significant operational and capital expenses. The revenues potentially raised by the sale of recovered materials are not inconsiderable although they do not significantly alter the overall economic balance. Hence the MCL waste market is not financially sustainable and other funding sources are necessary to develop any of these treatment options. Some possible options include:

General or local taxation, where collection and treatment would be handled by governmental bodies (local, regional or national),

Payment by the electricity utility, which would either incur all the costs as it would benefit from energy efficiency savings or transfer some of these costs to the customer, at which point various billing options are possible (billing the heaviest users only, flat-rate service fee, etc.),

enforcement of an eco-tax, as increasingly introduced in developed countries, mostly in Europe in the form of a contribution from lamp manufacturers who as major beneficiaries of CFL market growth may contribute directly or indirectly to the development of a waste management scheme, similar to that implemented through the Extended Producer’s Responsibility scheme in Europe.

Comparative assessment of EOL waste management options

There are many options for managing MCL waste. In the following table, three specific treatment options have been assessed: an engineered landfill, incineration and a mercury recycling facility, based on a set of criteria, mainly:

Mitigation of the mercury risk and emission reduction potential, i.e. the potential benefit of the solution from the environmental and health points of view;

Overall feasibility, including the regulatory framework, the operational capability and the financing that would be necessary;

Peripheral considerations such as the collection scheme that would be required to implement such an option or additional benefits such as mitigation spillover and/or revenue generation

Criteria	Engineered landfill	Incineration	Mercury powder extraction and/or recycling
Potential for reducing mercury emissions	In a normal engineered landfill, emissions are not reduced. Emissions at the facility can be reduced by 50% (through biogas and leachate treatment with advanced filter technology). Emissions during DSW* collection and at the time of or shortly after disposal, about 50%, cannot be reduced.	Emissions can be reduced by 20% in a normal incinerator, and by 90% in a state-of-the-art incinerator (with advanced filter technology) In addition, emissions during DSW* collection, about 30%, cannot be reduced. In the case of hazardous waste or separate collection, emissions are about 10%.	Emissions in a recycling facility are only 1%. In addition, emissions during collection (separate scheme) are about 10% (from accidental breakage). With proper handling, breakage and resulting emissions can be reduced.
Risk mitigation	Low risk from airborne emissions, and even mitigated for the surrounding population compared to uncontrolled landfill Ground water pollution avoided by waterproof lining Open water pollution avoided in the case of an evaporation-based leachate treatment	High risk in the case of a separate scheme due to lamp concentration Very high risks if poor O&M Filters must be stored in hazardous waste landfills or exported	High risk due to lamp concentration Effective risk mitigation if normal safety procedures applied (contingency plans, proper ventilation)
O&M issues	High skills not required Proper site location recommended for maximum mitigation	High-tech facilities requiring highly competent operators Negative social impact due to loss of work for waste scavengers 24/7 electricity supply must be ensured	Simple facilities based on one high-tech machine Requires air management and/or treatment and proper safety protocol in case of breakage
Regulatory requirements	Enforcement of basic national waste management policies and regulations	Strict regulation & control of incineration Provisions for hazardous waste landfills or filter export possibilities Provisions for employment of scavengers in sorting plants would be an advantage.	Strict regulation & control of glass management (e.g. prohibition for reuse in food packaging) Provisions for hazardous waste landfills or mercury export possibilities for the mercury powders (if not recycled) Strict regulation on the mercury market if sale of recycled mercury
Economics	Low CAPEX and OPEX MCL in landfills actually comes at very little extra cost since landfill would be built for wider purposes (municipal waste)	High CAPEX, sustainability of funding is crucial to maintain O&M MCL in incineration actually comes at very little extra cost since incinerator would be built for wider purposes (domestic or hazardous waste)	Average CAPEX and high OPEX, with high variability in marginal costs depending on the market size and the plant capacity (factor of 1 to 5 from the lowest to the highest capacities) Recycling equipments specific to MCL Sustainability of funding crucial to maintain O&M
Collection requirements	Domestic Solid Waste collection	Domestic Solid Waste, Hazardous Waste, or separate collection, depending on the incinerator category In case of activated carbon filters, avoid waste-compacting trucks to maximize amount of mercury recovered at the treatment facility	Separate collection, requiring proper handling to avoid breakage (training for workers needed) Pre-crushing is relevant for business users
Additional benefits	Widespread environmental benefits compared to an uncontrolled landfill Potential for biogas and leachate treatment to recover mercury	Limited emissions with proper filter technology Minimal land occupation	Recycling and resale of glass and metals, in addition to mercury, with somewhat relevant potential revenues Mercury is completely recovered and re-injected into the market, reducing the quantity of mercury that needs to be extracted globally

*DSW: Domestic Solid Waste

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