Speiss, copper

Administrative data

Hazard for aquatic organisms

Freshwater

Hazard assessment conclusion:

no data available: testing technically not feasible

Marine water

Hazard assessment conclusion:

no data available: testing technically not feasible

STP

Hazard assessment conclusion:

no data available: testing technically not feasible

Sediment (freshwater)

Hazard assessment conclusion:

no data available: testing technically not feasible

Sediment (marine water)

Hazard assessment conclusion:

no data available: testing technically not feasible

Hazard for air

Air

Hazard assessment conclusion:

no hazard identified

Hazard for terrestrial organisms

Soil

Hazard assessment conclusion:

no data available: testing technically not feasible

Hazard for predators

Secondary poisoning

Hazard assessment conclusion:

no data available: testing technically not feasible

Additional information

The hazard assessment of inorganic UVCBs for the purpose of classification and derivation of safe effect thresholds (i.e. PNEC) is a cumbersome and complex process. Due to the intrinsic variability of the composition of an UVCB, it is difficult to select a sample that would unambiguously be representative for the (eco)toxicological hazard profile of the UVCB and could subsequently be used for testing. Instead of direct testing, a precautionary approach is taken where the UVCB is treated as a complex metal containing substance containing a number of discrete constituents (metals, metal compounds, non-metal inorganic compounds etc.). For each of these constituents, the hazard profile is used for deriving the proper classification of the UVCB (using the mixture rules) and/or for the derivation of the PNECs of the constituent (forwarded to the risk assessment). Using the PNEC of all individual constituents circumvents indirectly the issue of varying composition of an UVCB as it implicitly assumes that each time the UVCB substance consists of the pure substance, i.e. that each constituent would be present and bioavailable at a 100% concentration in the UVCB substance. This can be considered a conservative approach. A main outcome of the constituents’ based assessment is the selection of all the constituents for which any environmental hazard is identified. This selection defines the scope of the further exposure and risk assessment (CSR, Ch. 9&10).

 

The actual hazard profile of the inorganic UVCB substance and the individual constituents is dependent on the speciation of each and every constituent andhence this information needs to be collected in order to obtain a robust classification or PNEC value used for risk assessment purposes. Different scenarios can be encountered.

·      When the speciation of a constituent is known, this is used as such for the environmental hazard assessment.

·      When the speciation is unknown or few metal species co-exist, the worst-case speciation for the purpose of environmental hazard assessment is selected, i.e. the speciation that would lead to the most severe effects and thus the lowest PNEC.

 

For most metals, it is generally assumed that the Me-ion is the metal species of concern and therefore, the environmental hazard assessment is generally based on Me-ion speciation (ECHA, 2008.Guidance on information requirements and chemical safety assessment; Appendix R.7.13-2: Environmental risk assessment for metals and metal compounds)

 

Selection of the ecotoxicological information for the purpose of classification

 

The UVCB classification is calculated by applying the CLP mixture rules based on the classification of the known or worst-case speciation for each constituent and worst-case constituent concentration in the UVCB (i.e. maximum of the legal entity typical value), using the MeClas tool. Depending on the availability of information, the UVCB classification can be refined following MeClas Tiered approach.

 

Selection of the ecotoxicological information for the purpose of risk assessment

 

For the purpose of the environmental risk assessment for the UVCB, the hazards of each constituent will be assessed and PNEC values for all the constituents for which a hazard has been identified are compiled.

The UVCB is an intermediate, with a very limited life cycle (manufacturing and industrial uses only).Testing the UVCB is difficult because of the large uncertainty involved when selecting representative samples due to the variable elemental concentrations in the composition of the UVCB. Derivation of PNECs for the UVCB as such are therefore difficult to interpretbecause of the uncertainty related to the representativeness of the testing. Also, exposure to the UVCB cannot be measured or modelled because of the multi-constituent character of the UVCB. For these reasons,the UVCB environmental (hazard) assessment is driven by the assessment of the individual UVCB constituents.

For the purpose of the classification, the UVCB is treated as a complex metal containing substance with a number of discrete constituting compounds (metals, metal compounds, non-metal inorganic compounds). The hazard classifications of each compound are then factored into a combined classification of the UVCB as a whole. For environmental endpoints, additivity and/or summation algorithms are applied to quantitatively estimate the mixture’s toxicity to aquatic organisms.

For the purpose of the environmental (risk) assessment, the ecotoxicological information that was taken forward is based on all hazardous constituents of all relevant UVCBs at the site for which quantitative exposure and risk assessment was conducted. For the environment, most often, it is the metal ion that is the toxic driver (ECHA, 2008, R.7.13-2). Consequently, the PNECs expressed as metal ion are the relevant ones to forward to risk characterisation. Considering the composition of this UVCB, full solubilisation of the emissions of the various constituting speciation is metals are assessed. The physical form (powder or massive) does not lead in this case to different release potential of the elements from the UVCB and consequently no different PNECs. When quantitative exposure and risk assessment were conducted on a metal constituent, the ecotoxicological information on this individual metal is reported in the respective summary sheet. The information is taken from the respective REACH IUCLID dossiers (see annex II of this CSR). More information on the scope of the UVCB assessment can be found in the CSR of the UVCB (Chapter 9).

 

Table36:Summary of the information on toxicological information for the purpose of riskassessment:

UVCB constituent			Variability in chemical composition		PNECs
Element	Speciation used for environmental risk assessment
Cu	Metal ion	Hazard assumed as if UVCB consists of 100% worst-case speciation	See respective PNEC summary in IUCLID and table below
S	(Sulfides are transformed to) sulphates	Hazard assumed as if UVCB consists of 100% worst-case speciation	Potential pH-effect on the receiving environmental compartments
Ni	Metal ion	Hazard assumed as if UVCB consists of 100% worst-case speciation	See respective PNEC summary in IUCLID and table below
Pb	Metal ion	Hazard assumed as if UVCB consists of 100% worst-case speciation	See respective PNEC summary in IUCLID and table below
As	Metal ion	Hazard assumed as if UVCB consists of 100% worst-case speciation	See respective PNEC summary in IUCLID and table below
Zn	Metal ion	Hazard assumed as if UVCB consists of 100% worst-case speciation	See respective PNEC summary in IUCLID and table below
Co	Metal ion	Hazard assumed as if UVCB consists of 100% worst-case speciation	See respective PNEC summary in IUCLID and table below
Sn	Metal ion	Hazard assumed as if UVCB consists of 100% worst-case speciation	See respective PNEC summary in IUCLID and table below
Sb	Metal ion	Hazard assumed as if UVCB consists of 100% worst-case speciation	See respective PNEC summary in IUCLID and table below
Ag	Metal ion	Hazard assumed as if UVCB consists of 100% worst-case speciation	See respective PNEC summary in IUCLID and table below
Ba	Metal ion	Hazard assumed as if UVCB consists of 100% worst-case speciation	See respective PNEC summary in IUCLID and table below
Other minors	Metal ion	Hazard assumed as if UVCB consists of 100% worst-case speciation	See respective PNEC summary in IUCLID and table below
Oxides	Oxides	Hazard assumed as if UVCB consists of 100% worst-case speciation	Potential pH-effect on the receiving environmental compartments

For the purpose of the risk assessment, the hazard conclusions and the metal-specific PNECs (Predicted No Effect Concentration) were collected for each environmental compartment. An overview of the PNECs relevant for the Copper intermediates is given in the table below. PNEC for arsenic metal was not available. Consequently, one was derived based on arsenic oxide using molecular weight conversion. Elements for which no PNEC is reported inTable37have no relevant environmental hazards and for which there is no need to derive environmental threshold. For oxides, hydroxides and sulphates, there is a potential pH-effect on the receiving environmental compartments.

 

Table:Overview of hazard conclusions - Predicted No Effect Concentration (PNEC) takenforward for CSA of the the Copper intermediates

See respective PNEC summaries in IUCLID. 

Environmental classification justification

The UVCB is treated as a complex metal containing substance with a number of discrete constituting compounds (metals, metal compounds, non-metal inorganic compounds). The hazard classifications of each compound are then factored into a combined classification of the UVCB as a whole. The classification was derived using Meclas (MEtals CLASsification tool - see www.meclas.eu), a calculation tool that follows classification guidance and implementation in accordance to legal rules and technical guidance from ECHA and CLP. See IUCLID section 13 attachment for MeClas classification conclusions.

 

Table38:Summary of the information on ecotoxicological information for the purpose ofclassification

UVCB constituent		Variabiliy of elemental composition	Classification according each relevant endpoint
Element	Speciation* taken forward for Tier 1 classification
Cu	66% Cu massive, 34% covellite	Maximum of typicals	Self-classification of the speciation, see MECLAS report in CSR Annex I
Ag	Ag compounds	Maximum of typicals	Self- classification of the speciation, see MECLAS report in CSR Annex I
Al	Al silicate	Maximum of typicals	Not classified
As	As metal	Maximum of typicals	Harmonised classification of the speciation, see MECLAS report in CSR Annex I
Ba	Ba	Maximum of typicals	Self- classification of the speciation, see MECLAS report in CSR Annex I
Co	CoS	Maximum of typicals	Harmonised classification of the speciation, see MECLAS report in CSR Annex I
Fe	Fe compounds	Maximum of typicals	Not classified
Mg	Mg/Mg compounds	Maximum of typicals	Not classified
Mn	MnSO4	Maximum of typicals	Harmonised classification of the speciation, see MECLAS report in CSR Annex I
Ni	Ni massive	Maximum of typicals	Harmonised classification of the speciation, see MECLAS report in CSR Annex I
Pb	Pb massive	Maximum of typicals	Self- classification of the speciation, see MECLAS report in CSR Annex I
Sb	Sb metal	Maximum of typicals	Not classified
Sn	Sn	Maximum of typicals	Not classified
S	Sulfide		Taken into account in corresponding metal sulfides already
Zn	Zn sulphate	Maximum of typicals	Harmonised classification of the speciation, see MECLAS report in CSR Annex I
Minors: Au, Bi, C, Ce, Pd	Metallic	Maximum of typicals	Below 0.1% and/or the speciation not impacting classification, see MECLAS report in CSR Annex I
oxides	SiO2, CaO, etc	Maxiumum of typicals	Below 4% and/or the speciation not impacting classification, see MECLAS report in CSR Annex I

 

* Detailed information on speciation can be found in IUCLID Section 4.23 Additional Physcio-chemical information

Hazards to the aquatic environment (short-term): Aquatic Acute 1 H400: Very toxic to aquatic life.

Hazards to the aquatic environment (long-term): Aquatic Chronic 1 H410: Very toxic to aquatic life with long lasting effects.

The estimated hazard is representative for the substance across industry, as defined by the maximum of the typical elemental concentration across industry (as outlined under IUCLID section 1.2).

Conclusion on classification

See Annex I MeClas.

The estimated hazard is representative for the substance across industry, as defined by the maximum of the typical elemental concentration across industry (as outlined under IUCLID section 1.2).