[1] urinary concentrations of toxic and essential trace elements among rural residents in hainan island, china

[2] Search for Higgs bosons and other massive states decaying into two photons in e+e− collisions at 189 GeV

[3] Search for Long-Lived Heavy Particles

[4] Measurement of charm and bottom production from semileptonic hadron decays in p+p collisions at s=200 GeV

[5] Search for supermassive nuclei in nature

[6] Charged particle multiplicities in heavy and light quark initiated events above the Z0 peak

[7] Same maximum figure of merit ZT(=1), due to effects of impurity size and heavy doping, obtained in the n(p)-type degenerate InP-crystal <img src="https://img.scirea.org/article/140529_1.png">, at same reduced Fermi energy <img src="https://img.scirea.org/article/140529_2.png"> and same minimum (maximum) Seebeck coefficient <img src="https://img.scirea.org/article/140529_3.png">, at which same <img src="https://img.scirea.org/article/140529_4.png">

[8] ACCUMULATION OF HEAVY METALS IN MANGROVE SEDIMENTS OF CHUMPHON PROVINCE, THAILAND

[9] Soil Remediation Practices for Hydrocarbon and Heavy Metal Reclamation in Mining Polluted Soils.

[10] Solid-phase microextraction of heavy metals in natural water with a polypyrrole/carbon nanotube/1, 10–phenanthroline composite sorbent material

[11] Waste water irrigation in the regulation of soil properties, growth determinants, and heavy metal accumulation in different Brassica species.

[12] Plant Growth-Promoting Traits in Rhizobacteria of Heavy Metal-Resistant Plants and Their Effects on Brassica nigra Seed Germination

[13] Assessment of heavy metal pollution in soil and their implications within and around mechanic villages

[14] Accumulation of heavy metals in soil and uptake by plant species with phytoremediation potential

[15] Removal of heavy metals from a contaminated soil using organic chelating acids

[16] Pine (Pinus Eldarica Medw.) needles as indicator for heavy metals pollution

[17] Synthesis of new Schiff base from natural products for remediation of water pollution with heavy metals in industrial areas

[18] Organically Modified Silica with Pyrazole-3-carbaldehyde as a New Sorbent for Solid-Liquid Extraction of Heavy Metals

[19] Heavy metal distribution between contaminated soil and Paulownia tomentosa, in a pilot-scale assisted phytoremediation study: influence of different complexing agents

[20] Removal of heavy metals (Cu, Cd and Zn) from contaminated soils using EDTA and FeCl3

[21] [Children's non-carcinogenic health risk assessment of heavy metals exposure to residential indoor dust around an e-waste dismantling area in South China].

[22] Health risk assessment of heavy metals in soil samples from an abandoned industrial waste dumpsite in Ibadan, Nigeria.

[23] Modulation of the gut microbiota by a galactooligosaccharide protects against heavy metal lead accumulation in mice.

[24] Noncovalent interactions in inorganic supramolecular chemistry based in heavy metals. Quantum chemistry point of view

[25] Evaluation of the heavy metals (mercury, lead, and cadmium) contamination of sardine () and swordfish () fished in three Algerian coasts.

[26] Heavy metals concentrations in some commercially key species from Sicilian coasts (Mediterranean Sea): Potential human health risk estimation.

[27] Fluorometric chemosensors. Interaction of toxic heavy metal ions Pb(II), Cd(II), and Hg(II) with novel mixed-donor phenanthroline-containing macrocycles: spectrofluorometric, conductometric, and crystallographic studies.

[28] Removal of Heavy Metal Ions with Acid Activated Carbons Derived from Oil Palm and Coconut Shells

[29] Effect of NH<inf>4</inf>Cl addition to sewage sludgebased activated carbons on the adsorption of heavy metals from aqueous solution

[30] Comment on "Short-lived pause in Central California subsidence after heavy winter precipitation of 2017" by K. D. Murray and R. B. Lohman.

[31] A novel layer-by-layer heterogeneous cation exchange membrane for heavy metal ions removal from water.

[32] Investigation of the fate of heavy metals based on process regulation-chemical reaction-phase distribution in an A-O<inf>1</inf>-H-O<inf>2</inf> biological coking wastewater treatment system

[33] Process safety management challenges in heavy oil production

[34] Concentration of heavy metals in Mirusha and Stanishor rivers of Gjilan municipality and their impact on pollution of the Morava river, Kosovo

[35] Metal Oxide Nanoparticles Supported on Macro-Mesoporous Aluminosilicates for Catalytic Steam Gasification of Heavy Oil Fractions for On-Site Upgrading

[36] Antibiotic resistance and heavy metal tolerance plasmids: the antimicrobial bulletproof properties of Escherichia fergusonii isolated from poultry

[37] Methicillin-resistant Staphylococcus aureus: livestock-associated, antimicrobial, and heavy metal resistance

[38] Growth, Biochemical parameters and Heavy Metals Concentrations of Citrus and Fig Fruit

[39] Antibiotic resistance and heavy metal tolerance plasmids: the antimicrobial bulletproof properties of Escherichia fergusonii isolated from poultry

[40] Methicillin-resistant Staphylococcus aureus: livestock-associated, antimicrobial, and heavy metal resistance

[41] Environmental Chemistry and Ecotoxicology of Hazardous Heavy Metals: Environmental Persistence, Toxicity, and Bioaccumulation

[42] Growth, Biochemical parameters and Heavy Metals Concentrations of Citrus and Fig Fruit

[43] Adsorption study of heavy metals in aqueous solutions aiming at the treatment of contaminated groundwater.

[44] Bioremoval of Different Heavy Metals by the Resistant Fungal Strain Aspergillus niger

[45] Characterization of microplastics and the association of heavy metals with microplastics in suburban soil of central China

[46] Heavy metals and rare earth elements distribution in the brine fields of awe, keana and giza, central benue trough, Nigeria

[47] An Estimator of Heavy Tail Index through the Generalized Jackknife Methodology

[48] Heavy Metal Ion Sensing By Surface Plasmon Resonance on Gold Nanoparticles

[49] Removal of heavy oil using rhinoceros beetle, Oryctes rhinoceros.

[50] Development and application of an amylopectin-graft-poly(methyl acrylate) solidifier for rapid and efficient containment and recovery of heavy oil spills in aqueous environments

[51] A SEARCH ON HEAVY METAL ACCUMULATION IN SCADS CAUGHT IN THE GULF OF İZMİT AND OFF TEKİRDAG PROVINCE IN THE SEA OF MARMARA

[52] Heavy fermion quantum criticality at dilute carrier limit in CeNi(AsP).

[53] A review on polyaniline-based materials applications in heavy metals removal and catalytic processes

[54] Assisting Phytoremediation of Heavy Metals Using Chemical Amendments.

[55] Bioaccumulation of heavy metals air pollutants by urban trees.

[56] Phytoremediation of heavy metal-contaminated sites: Eco-environmental concerns, field studies, sustainability issues, and future prospects

[57] Heavy metal accumulation and phytoremediation potential by transplants of the seagrass Zostera marina in the polluted bay systems

[58] Co-occurrence patterns of microbial communities affected by inoculants of plant growth-promoting bacteria during phytoremediation of heavy metal-contaminated soils

[59] Pyrolysis of heavy metal contaminated Avicennia marina biomass from phytoremediation: Characterisation of biomass and pyrolysis products

[60] Effect of heavy metals in mixed domestic-industrial wastewater on performance of recirculating standing hybrid constructed wetlands (RSHCWs) and their removal

[61] Geochemical characteristics, partitioning, quantitative source apportionment, and ecological and health risk of heavy metals in sediments and water: A case study in Shadegan Wetland, Iran

[62] Heavy metal dissolution mechanisms from electrical industrial sludge.

[63] Flocculation of different types of combined contaminants of antibiotics and heavy metals by thermo-responsive flocculants with various architectures

[64] Assessment of Soil Pollution with Heavy Metals in Urban Areas of the Kola Arctic

[65] Environmental pollution with heavy metals: Case study of the household waste

[66] Virtual flows of aquatic heavy metal emissions and associated risk in China.

[67] Mechanical behavior of inert steel slag ballast for heavy haul rail track: Laboratory evaluation

[68] Study on analytical method for the content of aluminium inclusions in heavy rail steel by laser-induced breakdown spectroscopy

[69] Determination of the chemical compositions of heavy, medium, and light crude oils by using the Distillation, Precipitation, Fractionation Mass Spectrometry (DPF MS) method

[70] Rheological characteristics of unstable heavy crude oil-water dispersed mixtures

[71] Environmental assessment of heavy metal pollution of Diyala River within Baghdad City

[72] Highly efficient and selective capture of heavy metals by poly(acrylic acid) grafted chitosan and biochar composite for wastewater treatment

[73] Estimation of the spatial distribution of heavy metal in agricultural soils using airborne hyperspectral imaging and random forest.

[74] Quantitative analysis of the factors influencing spatial distribution of soil heavy metals based on geographical detector.

[75] A Parametric Model of the LARCODEMS Heavy Media Separator by Means of Multivariate Adaptive Regression Splines.

[76] Speciation Distribution of Heavy Metals in Uranium Mining Impacted Soils and Impact on Bacterial Community Revealed by High-Throughput Sequencing.

[77] The impact of low to high waste cooking oil-based biodiesel blends on toxic organic pollutant emissions from heavy-duty diesel engines

[78] Removal of Heavy Metal Water Pollutants (Co and Ni) Using Polyacrylamide/Sodium Montmorillonite (PAM/Na-MMT) Nanocomposites.

[79] Analysis of the Stay Time of Patients in Gunma University Heavy Ion Medical Center (GHMC) Using RFID Technology.

[80] Relation between changes in organic matter structure of poultry litter and heavy metals solubility during composting

[81] A novel layer-by-layer heterogeneous cation exchange membrane for heavy metal ions removal from water

[82] 3D vessel-wall virtual histology of whole-body perfused mice using a novel heavy element stain

[83] Study on rheological properties of aviation lubricating oil under conditions of heavy load, high speed, and high temperature

[84] Distribution of heavy metals (Cd, Pb, Hg, As) and essential elements (Fe, Se) in forest soil and plant communities of the state open hunting area "krndija II" XIV/23

[85] A New Spatiotemporal Risk Index for Heavy Metals: Application in Cyprus

[86] Preparation of Magnetic Carboxymethylchitosan Nanoparticles for Adsorption of Heavy Metal Ions.

[87] Comparative study of the characteristics and fluorescent properties of three different biochar derived‑carbonaceous nanomaterials for bioimaging and heavy metal ions sensing

[88] The Fractionation of Some Heavy Metals in Calcareous Soils Affected by Land Uses of Central Area of Zanjan Provine (Northwest of Iran)

[89] Drinking water quality in six small tea gardens of Sonitpur District of Assam, India, with special reference to heavy metals.

[90] Polycyclic aromatic hydrocarbon and heavy metal contents in the urban soils in southern Poland.

[91] Characteristics, sources and health risks of toxic species (PCDD/Fs, PAHs and heavy metals) in PM during fall and winter in an industrial area.

[92] Heavy metal pollution and co-selection for antibiotic resistance: A microbial palaeontology approach.

[93] Numerical prediction of swirl burner geometry effects on NOx emission and combustion instability in heavy oil-fired boiler

[94] Light and heavy drinking in jurisdictions with different alcohol policy environments.

[95] Search for a heavy composite Majorana neutrino in the final state with two leptons and two quarks at s=13TeV

[96] Evaluating the potential health risks of heavy metal pollution in sediment and selected benthic fauna of Benin River, Southern Nigeria

[97] Mapping Occupational Hazards with a Multi-sensor Network in a Heavy-Vehicle Manufacturing Facility

[98] Characteristics and speciation of heavy metals in fly ash and FGD gypsum from Chinese coal-fired power plants

[99] Influence of organic matter and CO<inf>2</inf> supply on bioremediation of heavy metals by Chlorella vulgaris and Scenedesmus almeriensis in a multimetallic matrix

[100] Plant-based oil-sorbents harbor native microbial communities effective in spilled oil-bioremediation under nitrogen starvation and heavy metal-stresses

[101] Wood-derived biochar influences nutrient use efficiency of heavy metals in spinach (spinacia oleracea) under groundwater and wastewater irrigation