Skip to main content
U.S. flag

An official website of the United States government

Sources, Forms, Extractability of Metals in Non-Ore Deposit Sources Completed

By Geology, Geophysics, and Geochemistry Science Center June 29, 2018

This project explored potential recovery and environmental consequences of metals in mining and mineral processing wastes as a function of ore deposit geology, and in debris from demolished or burned buildings. 

sampling mine drainage
Sources/Usage: Public Domain. View Media Details
USGS scientist sampling at a historical mine waste pile with associated drainage.(Public domain.)

Science Issue and Relevance

Many metals that in the past had a limited to modest industrial or technological application are now critical for emerging high-technology or green-technology applications. Increasing demand for these critical metals, coupled with their geologically rare economic enrichments in the earth's crust, has raised concern about their availability. Recovery of these metals from waste materials is increasingly of societal interest, as it may help reduce dependence on foreign sources for the metals, defray costs of waste remediation, reduce the content of metal toxicants in wastes, and diminish needs for mining that specifically targets the metals.

Previous work on the Metal and Mineral Commodities in the Built and Waste Stream Environments—Uses, Characteristics, and Environmental/Health Implications project examined the types, concentrations, and environmental and toxicological characteristics of metal and minerals in a wide range of building materials and other materials found in buildings such as concrete blocks, brick, rebar, concrete, pipes, plastics, electronics, and pressure treated lumber. Results revealed a number of unusual occurrences of metals and minerals.

Methodology to Address Issue

This project explored potential recovery and environmental consequences of metals in mining and mineral processing wastes as a function of ore deposit geology, and in debris from demolished or burned buildings. Our general objectives were to 1) characterize metals in bulk materials; 2) examine the leachability of metals from these materials; 3) examine deportment of metals during smelting or refining, and 4) tie metals in these materials to the life cycle of mineral commodities from extraction, through manufacturing, consumer use, reuse, recycling, and disposition.

  • Metals and Minerals in Debris from the Built Environment - Our primary objectives were to 1) understand the forms, concentrations, and environmental implications of metals in materials that are recycled or sent to landfills when buildings are demolished or have burned, 2) screen previously collected samples by portable X-ray fluorescence, from which selected samples were be sampled for further analysis, and 3) burn site materials were analyzed and compared to lumber of varying age.

  • Sources, Forms, and Extractability of Mining and Mineral Wastes - Our objectives were to 1) obtain additional mining waste samples from a variety of mineral deposits types, 2) conduct bulk chemical and mineralogical characterization of the waste samples, and 3) subject waste samples to leaching tests to determine extractability of elements of interest.

  • Sources, Forms, and Extractability of Metals from Smelter Wastes - We examined deportment of metals during smelting or refining. Our objectives were to 1) conduct bulk chemical and mineral characterization of modern smelter slag, 2) identify amounts and modes of occurrence of residual elements in slag for potential recovery, and 3) quantify deportment of various metals during processing steps of concentrating metals from ore in order to optimize recovery.

microscopic gold and lead particles
Sources/Usage: Public Domain. View Media Details
Microscopic gold and lead particles surrounded by organic and phosphorus-rich material in a municipal biosolids sample (combined surface topography and atomic weight images).(Credit: Heather Lowers, USGS. Public domain.)

Return to Mineral Resources Program | Geology, Geophysics, and Geochemistry Science Center 

Below are publications associated with this project.

Environmental characteristics and utilization potential of metallurgical slag

Slag, an abundant byproduct from the pyrometallurgical processing of ores, can be an environmental liability or a valuable resource. The most common environmental impact of slag is from the leaching of potentially toxic elements, acidity, or alkalinity that may impact nearby soils and surface water and groundwater. Factors that influence its environmental behavior include physical characteristics
Authors
Nadine M. Piatak
By
Mineral Resources Program, Geology, Energy & Minerals Science Center

Mining for metals in society's waste

Metals are crucial to society and enable our modern standard of living. Look around and you can't help but see products made of metals. For instance, a typical gasoline-powered automobile contains over a ton of iron and steel, 240 pounds of aluminum, 42 pounds of copper, 41 pounds of silicon, 22 pounds of zinc and more than 30 other mineral commodities including titanium, platinum and gold. Metals
Authors
Kathleen S. Smith, Geoffrey S. Plumlee, Philip L. Hageman
By
Mineral Resources Program, Geology, Geophysics, and Geochemistry Science Center, Geology, Minerals, Energy, and Geophysics Science Center, Denver Microbeam Laboratory

Potential metal recovery from waste streams

‘Waste stream’ is a general term that describes the total flow of waste from homes, businesses, industrial facilities, and institutions that are recycled, burned or isolated from the environment in landfills or other types of storage, or dissipated into the environment. The recovery and reuse of chemical elements from waste streams have the potential to decrease U.S. reliance on primary resources
Authors
Kathleen S. Smith, Philip L. Hageman, Geoffrey S. Plumlee, James R. Budahn, Donald I. Bleiwas
By
Geology, Minerals, Energy, and Geophysics Science Center, Geology, Geophysics, and Geochemistry Science Center
  • Overview

    This project explored potential recovery and environmental consequences of metals in mining and mineral processing wastes as a function of ore deposit geology, and in debris from demolished or burned buildings. 

    sampling mine drainage
    Sources/Usage: Public Domain. View Media Details
    USGS scientist sampling at a historical mine waste pile with associated drainage.(Public domain.)

    Science Issue and Relevance

    Many metals that in the past had a limited to modest industrial or technological application are now critical for emerging high-technology or green-technology applications. Increasing demand for these critical metals, coupled with their geologically rare economic enrichments in the earth's crust, has raised concern about their availability. Recovery of these metals from waste materials is increasingly of societal interest, as it may help reduce dependence on foreign sources for the metals, defray costs of waste remediation, reduce the content of metal toxicants in wastes, and diminish needs for mining that specifically targets the metals.

    Previous work on the Metal and Mineral Commodities in the Built and Waste Stream Environments—Uses, Characteristics, and Environmental/Health Implications project examined the types, concentrations, and environmental and toxicological characteristics of metal and minerals in a wide range of building materials and other materials found in buildings such as concrete blocks, brick, rebar, concrete, pipes, plastics, electronics, and pressure treated lumber. Results revealed a number of unusual occurrences of metals and minerals.

    Methodology to Address Issue

    This project explored potential recovery and environmental consequences of metals in mining and mineral processing wastes as a function of ore deposit geology, and in debris from demolished or burned buildings. Our general objectives were to 1) characterize metals in bulk materials; 2) examine the leachability of metals from these materials; 3) examine deportment of metals during smelting or refining, and 4) tie metals in these materials to the life cycle of mineral commodities from extraction, through manufacturing, consumer use, reuse, recycling, and disposition.

    • Metals and Minerals in Debris from the Built Environment - Our primary objectives were to 1) understand the forms, concentrations, and environmental implications of metals in materials that are recycled or sent to landfills when buildings are demolished or have burned, 2) screen previously collected samples by portable X-ray fluorescence, from which selected samples were be sampled for further analysis, and 3) burn site materials were analyzed and compared to lumber of varying age.

    • Sources, Forms, and Extractability of Mining and Mineral Wastes - Our objectives were to 1) obtain additional mining waste samples from a variety of mineral deposits types, 2) conduct bulk chemical and mineralogical characterization of the waste samples, and 3) subject waste samples to leaching tests to determine extractability of elements of interest.

    • Sources, Forms, and Extractability of Metals from Smelter Wastes - We examined deportment of metals during smelting or refining. Our objectives were to 1) conduct bulk chemical and mineral characterization of modern smelter slag, 2) identify amounts and modes of occurrence of residual elements in slag for potential recovery, and 3) quantify deportment of various metals during processing steps of concentrating metals from ore in order to optimize recovery.

    microscopic gold and lead particles
    Sources/Usage: Public Domain. View Media Details
    Microscopic gold and lead particles surrounded by organic and phosphorus-rich material in a municipal biosolids sample (combined surface topography and atomic weight images).(Credit: Heather Lowers, USGS. Public domain.)

    Return to Mineral Resources Program | Geology, Geophysics, and Geochemistry Science Center 

  • Publications

    Below are publications associated with this project.

    Environmental characteristics and utilization potential of metallurgical slag

    Slag, an abundant byproduct from the pyrometallurgical processing of ores, can be an environmental liability or a valuable resource. The most common environmental impact of slag is from the leaching of potentially toxic elements, acidity, or alkalinity that may impact nearby soils and surface water and groundwater. Factors that influence its environmental behavior include physical characteristics
    Authors
    Nadine M. Piatak
    By
    Mineral Resources Program, Geology, Energy & Minerals Science Center

    Mining for metals in society's waste

    Metals are crucial to society and enable our modern standard of living. Look around and you can't help but see products made of metals. For instance, a typical gasoline-powered automobile contains over a ton of iron and steel, 240 pounds of aluminum, 42 pounds of copper, 41 pounds of silicon, 22 pounds of zinc and more than 30 other mineral commodities including titanium, platinum and gold. Metals
    Authors
    Kathleen S. Smith, Geoffrey S. Plumlee, Philip L. Hageman
    By
    Mineral Resources Program, Geology, Geophysics, and Geochemistry Science Center, Geology, Minerals, Energy, and Geophysics Science Center, Denver Microbeam Laboratory

    Potential metal recovery from waste streams

    ‘Waste stream’ is a general term that describes the total flow of waste from homes, businesses, industrial facilities, and institutions that are recycled, burned or isolated from the environment in landfills or other types of storage, or dissipated into the environment. The recovery and reuse of chemical elements from waste streams have the potential to decrease U.S. reliance on primary resources
    Authors
    Kathleen S. Smith, Philip L. Hageman, Geoffrey S. Plumlee, James R. Budahn, Donald I. Bleiwas
    By
    Geology, Minerals, Energy, and Geophysics Science Center, Geology, Geophysics, and Geochemistry Science Center