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Publications

Publications Listed by Project

Soil Health

  • Keshavarz, R., T. Banet, L. Li, and¬†J.A. Ippolito. 2022. Furrow-irrigated corn residue management and tillage strategies for improved soil health. Soil and Tillage Research.¬†216:105238.¬†
  • Ippolito, J.A.¬†2021.¬†Chapter 7:¬†Nutrient availability: Macro- and micro-nutrients and soil quality and¬†health.¬†In: Soil Health: Vol. 2: Laboratory Methods for Soil Health Assessment¬†(D.L. Karlen,¬†D.E. Stott, and M.M. Mikha,¬†eds.), Soil Science Society of America (SSSA) & Wiley International, SSSA, Madison, WI.¬†pp. 109-125.¬†
  • Buchanan, C.M., and¬†J.A. Ippolito. 2021. Long-term biosolids applications to overgrazed rangelands improve soil health. MDPI Agronomy. 11: 1339.¬†
  • Ippolito, J.A., T.F. Ducey,¬†K. Diaz, and K.A. Barbarick. 2021. Long-term biosolids land application influences soil health. Sci. Tot. Environ. 791:148344.¬†
  • Shawver, C.,¬†J.A. Ippolito, J. Brummer, J.¬†Ahola, and R. Rhoades. 2021. Management-intensive grazing affects soil health.¬†Agrosystems, Geosciences, and Environment.¬†4, e20181.¬†https://doi.org/10.1002/agg2.20181.¬†
  • Miner, G.L., J.A. Delgado,¬†J.A. Ippolito, and C.E. Stewart. 2020. Soil health management practices and crop productivity. Ag. Environ. Letters. DOI: 10.1002/ael2.20023.¬†
  • Miller, H.,¬†K. Diaz, H. Hare, K.¬†Borton, R. Daly, J. Blotevogel, C. Danforth, M. Wilkins, K. Wrighton,¬†J. Ippolito, and T. Borch. 2020. Reusing¬†oil and gas produced water for agricultural irrigation: Effects on soil health and microbiome. Sci. Tot. Environ. 722: 137888 (https://doi.org/10.1016/j.scitotenv.2020.137888).¬†
  • Miner, G.L., J.A. Delgado,¬†J.A. Ippolito, C.E. Stewart, D.K. Manter, S.J. Del Grosso, B.A. Floyd, and R.E. D‚ÄôAdamo. 2020. Assessing manure and inorganic N fertilization impacts on soil health, crop productivity and quality in a continuous maize agroecosystem. J. Soil Water¬†Conserv. doi:10.2489/jswc.2020.00148.¬†
  • Ippolito, J.A., D.L. Bjorneberg, D.E. Stott, and D.L. Karlen. 2017. Soil quality improvement through conversion to sprinkler irrigation. Soil Sci. Soc. Am. J. 81:1505-1516.¬†
  • Novak, J.M.,¬†J.A. Ippolito, R.D. Lentz, K.A. Spokas, C.H. Bolster, K. Sistani, K.M. Trippe, and M.G. Johnson. 2016. Soil health, crop productivity, microbial transport, and mine spoil¬†response to biochars. Bioenergy¬†Res. 9:454-464.¬†
  • Blecker, S., L.¬†Stillings, N.¬†DeCrappeo, and¬†J. Ippolito. 2014.¬†Soil-plant-microbial relations in hydrothermally altered soils of Northern California. Soil Sci. Soc. Am. J.¬†78:509-519.¬†
  • Moore, A., S. Hines, B. Brown, C.¬†Falen, M. de¬†Haro¬†Marti, M.¬†Chahine, R.¬†Norell,¬†J. Ippolito, S. Parkinson, and M.¬†Satterwhite. 2014. Soil-plant nutrient interactions on manure-enriched calcareous soils.¬†Agronomy¬†J. 106:73-80.¬†
  • Blecker, S.W., L.L.¬†Stillings, M.C.¬†Amacher,¬†J.A. Ippolito, and N.M.¬†DeCrappeo. 2013.¬†Development and application of a soil organic matter based soil quality index in mineralized terrane of the Western US.¬† Environ. Earth Sci. 68:1887-1901.¬†
  • Blecker, S.W, L.L.¬†Stillings, M.C.¬†Amacher,¬†J.A. Ippolito, and N.M.¬†DeCrappeo. 2012. Development of¬†vegetation based soil quality indices for mineralized terrane in arid and semi-arid ecosystems. J. Ecol. Indic. 20:65-74.¬†

Environmental Quality

Biosolids

  • Buchanan, C.M., and¬†J.A. Ippolito. 2021. Long-term biosolids applications to overgrazed rangelands improve soil health. MDPI Agronomy. 11: 1339.¬†
  • Ippolito, J.A., T.F. Ducey,¬†K. Diaz, and K.A. Barbarick. 2021. Long-term biosolids land application influences soil health. Sci. Tot. Environ. 791:148344.¬†
  • Brown, S.,¬†J. Ippolito, N. Basta,¬†and¬†L. Hundal. 2020. Municipal biosolids as a tool for sustainable communities. Current Opinion in Environmental Science and Health.¬†14:56-62.¬†
  • Barbarick, K.A.,¬†J.A. Ippolito, and J. McDaniel. 2017. Meta-analysis of biosolids effect in dryland wheat agroecosystems. J. Environ. Qual. 46:452-460.¬†
  • Barbarick, K.A.,¬†J.A. Ippolito, and J. McDaniel. 2016. Path Analyses of grain P, Zn, Cu, Fe, and Ni in a biosolids-amended dryland wheat agroecosystem. J. Environ. Qual. 45:1400-1404.¬†
  • Barbarick, K.A.,¬†J.A. Ippolito, and J. McDaniel. 2015. Uptake coefficients for biosolids-amended dryland winter wheat. J. Environ. Qual. 44:286-292.¬†
  • Ippolito, J.A., K.A. Barbarick, and R.B. Brobst. 2014. Copper and zinc speciation in a biosolids-amended semi-arid grassland soil. J. Environ. Qual. 43:1576-1584.¬†
  • Meiman, P.J., N.R. Davis, J.E. Brummer, and¬†J.A. Ippolito. 2012. Riparian shrub metal concentrations and growth in amended fluvial mine tailings. Water, Air, Soil¬†Pollut.¬†223:1815-1828.¬†
  • Barbarick, K.A.,¬†J.A. Ippolito, and J. McDaniel. 2010. Fifteen years of wheat yield, N uptake, and soil nitrate-N dynamics in a biosolids amended agroecosystem. Agric.¬†Ecosys. Environ.¬†139:116-120.¬†
  • Ippolito, J.A., K.A. Barbarick, M.W. Paschke, and R.B. Brobst. 2010. Infrequent composted biosolids applications effect semi-arid grassland soils and vegetation. J. Environ. Manage.¬†91:1123-1130.¬†
  • Ippolito, J.A., K.A. Barbarick, M.E. Stromberger, M.W. Paschke, and R.B. Brobst. 2009. Water treatment residuals and biosolids long-term co-applications effects to semi-arid grassland soils and vegetation. Soil Sci. Soc. Am. J. 73:1880-1889.¬†
  • Ippolito, J.A., K.A. Barbarick, R.B. Brobst. 2009. Fate of biosolids Cu and Zn in a semi-arid grassland. Agric.¬†Ecosys. Environ.¬†131:325-332.¬†
  • Barbarick, K.A., and¬†J.A. Ippolito. 2009. Continuous biosolids application affects wheat grain elemental concentrations in a dryland-wheat agroecosystem. Agric.¬†Ecosys. Environ.¬†129:340-343.¬†
  • Ippolito, J.A., and K.A. Barbarick. 2008. Fate of biosolids trace metals in a dryland wheat agroecosystem. J. Environ. Qual. 37:2135-2144.¬†
  • Bayley, R.M.,¬†J.A. Ippolito, M.E. Stromberger, K.A. Barbarick, and M.W. Paschke. 2008. Water treatment residuals and biosolids co-applications affect the activity of phosphatases in a semi-arid rangeland soil.¬†Commun. Soil Sci. Plant Anal.¬†39:2812-2826.¬†
  • Bayley, R.M.,¬†J.A. Ippolito, M.E. Stromberger, K.A. Barbarick, and M.W. Paschke. 2008. Water treatment residuals and biosolids¬†coapplications¬†affect semi-arid rangeland phosphorus cycling. Soil Sci. Soc. Am. J. 72:711-719.¬†
  • Barbarick, K.A., and¬†J.A. Ippolito. 2008. Predicting soil-extractable zinc, phosphorus, copper, and iron in a biosolids-amended dryland-wheat agroecosystem. Soil Sci. 173:175-185.¬†
  • Barbarick, K.A., and¬†J.A. Ippolito.¬†2007. Dryland wheat nutrient assessment for 12 years of¬†biosolids applications. Agronomy¬†J. 99:715-722.¬†
  • Ippolito, J.A., K.A. Barbarick, and¬†K.L.¬†Norvell‚Ć. 2007. Biosolids¬†impact¬†soil phosphorus recovery, fractionation, and potential environmental risk. J. Environ. Qual. 36:764-772.¬†
  • Ippolito, J.A., and K.A. Barbarick. 2006. Biosolids affect soil barium¬†in a dryland wheat agroecosystem. J. Environ. Qual. 35:2333-2341.¬†
  • Sullivan, T.S., M.E. Stromberger, M.W. Paschke, and¬†J.A. Ippolito. 2005. Long-term impacts of infrequent biosolids application on chemical and microbial properties of a semi-arid rangeland soil. Biol.¬†Fert. Soils.¬†42:258-266.¬†
  • Barbarick, K.A., and¬†J.A. Ippolito. 2003. Termination of sewage biosolids application affects wheat yield and other agronomic characteristics.¬†Agronomy J. 95:1288-1294.¬†
  • Ippolito, J.A., K.A. Barbarick, and E.F. Redente. 2002. Combinations of water treatment residuals and biosolids¬†affect¬†on two range grasses.¬†Commun. Soil Sci. Plant Anal.¬†33:831-844.¬†
  • Barbarick, K.A., and¬†J.A. Ippolito. 2000. Nitrogen fertilizer equivalency of sewage biosolids applied to winter wheat. J. Environ. Qual. 29:1345-1351.¬†
  • Ippolito, J.A., K.A. Barbarick, and R.F. Redente. 1999. Co-application effects of water treatment residuals¬†and biosolids on two range grasses. J. Environ. Qual. 28:1644-1650.¬†
  • Barbarick, K.A.,¬†J.A. Ippolito, and D.G. Westfall. 1998. Extractable trace elements in the soil profile after years of biosolids application. J. Environ. Qual. 27:801-805.¬†
  • Barbarick, K.A.,¬†J.A. Ippolito, and D.G. Westfall. 1997. Sewage biosolids cumulative effects on extractable-soil and grain elemental concentrations. J. Environ. Qual. 26:1696-1702.¬†
  • Barbarick, K.A.,¬†J.A. Ippolito, and D.G. Westfall. 1996. Distribution and mineralization of biosolids nitrogen applied to dryland wheat. J. Environ. Qual. 25:796-801.¬†
  • Barbarick, K.A.,¬†J.A. Ippolito, and D.G. Westfall. 1995. Biosolids effect on phosphorus, copper, zinc, nickel, and molybdenum concentrations in dryland wheat. J. Environ. Qual. 24:608-611.¬†

Biochar

  • McKenna, A.M., M.L. Chacon-Patino, H. Chen, G.T.¬† Blakney, F.¬†Metnink-Vigier, R.B. Young,¬†J.A. Ippolito, and T. Borch. 2021. Solvent extraction reveals nonpolar and aromatic species isolated from biochar not detected in water-soluble fractions by FT-ICR mass spectrometry. Analytical Chemistry.¬†https://doi.org/10.1021/acs.analchem.1c03058.¬†
  • Joseph, S., A. Cowie, L. Van Zwieten, N. Bolan, A. Budai, W. Buss, M.L. Cayuela, E. Graber,¬†J. Ippolito, Y.¬†Kuzyakov, Y.S. Ok, K. Palansooriya, J. Shepherd, S. Stephens, Z. Weng, Y. Luo, and J. Lehmann. 2021. How biochar works and when it¬†doesn‚Äôt: A review of mechanisms controlling soil and plant response to biochar. Global Change Biology¬†Biochem.¬†13:1731-1764.¬†Doi: 10.1111/gcbb.12885.¬†
  • Cui, L., L. Li, R.¬†Bian, J. Yan, G.¬†Quan,¬†J.A. Ippolito, and H. Wang. 2021. Physical disintegration of biochar: A potentially important process for long-term cadmium and lead sorption. Biochar.¬†https://doi.org/10.1007/s42773-021-00108-z.¬†
  • Cui, L.,¬†J.A. Ippolito, M.¬†Noerpel, and K.G. Scheckel. 2021. Nutrient alterations following biochar application to a Cd-contaminated solution and soil. Biochar.¬†3:457-468.¬†https://doi.org/10.1007/s42773-021-00106-1.¬†
  • Ducey, T.F. J.M. Novak, G.C. Sigua,¬†J.A. Ippolito, H.C. Rushmiller, D.W. Watts, K.M. Trippe, K.A. Spokas,¬†K.C. Stone,¬†and M.G. Johnson. 2021. Microbial response to designer biochar and compost treatments in remediated, mine-impacted soils. Biochar.¬†3:299-314.¬†https://doi.org/10.1007/s42773-021-00093-3.¬†
  • Trippe, K.M., V. Manning, C. Reardon, A. Klein, M.G. Mateu, C. Weidman, T.F. Ducey, J.M. Novak, M.G. Johnson, K.A. Spokas,¬†J.A. Ippolito, and A. Moore. 2021.¬†Phytostabilization¬†of acidic mine tailings with biochar, biosolids, lime, and¬†locally-sourced¬†inoculum: Do amendment mixtures influence plant growth, tailing¬†chemistry, and microbial composition? Applied Soil Ecology.¬†165:103962.¬†
  • Natasha, N., M. Shahid, S. Khalid, I. Bibi, M.A.¬†Naeem, N.K. Niazi, F.M.G. Tack,¬†J.A. Ippolito, and J. Rinklebe. 2021. Influence of biochar on trace element uptake, toxicity, and detoxification in plants and associated health risks: A critical review. Critical Reviews in Environmental Science and Technology. Available at:¬†https://www.tandfonline.com/doi/full/10.1080/10643389.2021.1894064.¬†
  • Awan, S.,¬†J.A. Ippolito, J.L. Ullman, K. Ansari, L. Cui, and A.A. Siyal. 2021. Biochars reduce¬†irrigation water sodium adsorption ratio. Biochar.¬†3:77-87.¬†
  • Ippolito, J.A., Cui, L., C. Kammann, N.¬†Wrage-Monnig, J.M. Estavillo, T. Fuertes-Mendizabal, M. Cayuela, G. Sigua, J. Novak, K. Spokas, and N. Borchard. 2020. Feedstock choice, pyrolysis temperature and type influence biochar characteristics: A comprehensive review. Biochar.¬†2:421-438.¬†
  • Cui, L., L. Li, R.¬†Bian, J. Yan, G.¬†Quan, Y. Liu,¬†J.A. Ippolito, and H. Wang. 2020. Short- and long-term biochar cadmium and lead immobilization mechanisms. Environments. 7:53. doi:10.3390/environments7070053.¬†
  • Ippolito, J.A., L. Cui, J.M. Novak, and M.G. Johnson. 2019. Biochar for mine land reclamation. In:¬†Biochar from Biomass and Waste¬†(Y.S. Ok, N. Bolan, D. Tsang, and J. Novak, Eds.). Elsevier. Amsterdam, Netherlands.¬†pp. 75-90.¬†
  • Lentz, R.D.,¬†J.A. Ippolito, and G.A.¬†Lehrsch. 2019. Biochar, manure, and sawdust alter long-term water retention dynamics in degraded soil. Soil Sci. Soc. Am. J. 83:1491-1501.¬†
  • Cui, L., C. Yin,¬†T. Chen. G.¬†Quan,¬†J.A. Ippolito, H. Gan., B. Xiao, M. Pan, B.¬†Lui, J. Yan, C. Ding, Q. Hussain, and M.¬†Umer. 2019.¬†Remediation of organic halogen- contaminated wetland soil using biochar. Sci. Tot. Environ. 696:134087.¬†
  • Sigua, G.C., J.M. Novak, D.W. Watts,¬†J.A. Ippolito, T.F. Ducey, M.G. Johnson, and K.A. Spokas. 2019.¬†Phytostabilization¬†of Zn and Cd in mine soil using corn in combination with manure-based biochar and compost.¬†Environments.¬†6:69 doi:10.3390/environments6060069.¬†
  • Novak, J.,¬†J.A. Ippolito, D.W. Watts, G.C. Sigua, T.F. Ducey, and M.G. Johnson. 2019. Biochar compost blends facilitates¬†switchgrass¬†growth in mine soils by reducing Cd and Zn bioavailability. Biochar.¬†1:97-114.¬†
  • Cui, L., M.R.¬†Noerpel, K.G. Scheckel, and¬†J.A. Ippolito. 2019. Wheat straw biochar reduces environmental cadmium bioavailability. Environ. International.¬†126:69-75.¬†
  • Cui, L., C. Yin, T. Chen, G.¬†Quan, B. Xiao, Y. Ma, M. Pan, Y. Liu, B. Liu,¬†J.A. Ippolito, J. Yan, X. Han, C. Ding, M.¬†Bian, and Q. Hussain. 2019. Biochar immobilizes and degrades 2,4,6-trichlorophenol in soils. Environ. Toxic. Chem. 38:1364-1371.¬†
  • Fuertes-Mendiz√°bal, T., X. Hu√©rfano, I. Vega-Mas, F.¬†Torralbo, S. Men√©ndez,¬†J.A. Ippolito, C. Kammann, N. Wrage-M√∂nnig, M.L. Cayuela, N. Borchard, K. Spokas, J. Novak, M.B. Gonz√°lez-Moro, C. Gonz√°lez-Murua, and J.M. Estavillo. 2019. Biochar reduces the efficiency of nitrification inhibitor 3,4-dimethypyrazole phosphate (DMPP) mitigating N2O emissions. Scientific Reports. Available at:¬†https://www.nature.com/articles/s41598-019-38697-2.pdf.¬†
  • Cui, L., L. T. Chen, C. Yin, J. Yan,¬†J.A. Ippolito, and Q. Hussain. 2018. Mechanism of adsorption of cadmium and lead ions by iron-activated biochar.¬†Bioresour.¬†14:842-857.¬†
  • Borchard, N., M. Schirrmann, M. Cayuela, C. Kammann, N.¬†Wrage-M√∂nnig, J.M. Estavillo, T. Fuertes-Mendizabal, G. Sigua, K. Spokas,¬†J.A. Ippolito, and J. Novak. 2018. Biochar, soil and land use interactions that reduce nitrate leaching and N2O emissions: A meta-analysis. Sci. Tot. Environ.¬†651:2354-2364.¬†
  • Novak, J.M.,‚ÄĮJ.A. Ippolito, T.F. Ducey, M.G. Johnson, D.W. Watts, K.M. Trippe, K.A. Spokas, and G.C. Sigua. 2018. Remediation of an acidic mine spoil:¬†Miscanthus¬†biochar and lime amendment affects metal availability, plant growth, and soil enzyme activity. Chemosphere.¬†205:709-718.¬†
  • Mehmood, K., E. Ch√°vez Garcia, M.¬†Schirrmann, B. Ladd, C. Kammann, N. Wrage-M√∂nnig, C.¬†Siebe, J.M. Estavillo, T. Fuertes, M. Cayuela, G. Sigua, K. Spokas, A.L. Cowie, J. Novak,¬†J.A. Ippolito, and N. Borchard. 2017.¬†Biochar research activities and their relation to development and environmental quality. A meta-analysis.¬†Agron. Sustain. Dev. 37:22.¬†
  • Kammann, C., N. Borchard, M. Cayuela, N.¬†Hagemann,¬†J. Ippolito, S. Jeffery, J. Kern, D.¬†Rasse, S.¬†Sanna, H-P. Schmidt, K. Spokas, and N. Wrage-M√∂nnig.¬†2017. Biochar as a tool to reduce the agricultural greenhouse burden ‚Äď Knowns, unknowns and future research needs. J.¬†Environ. Engineer. Landscape Management.¬†25:114-139.¬†
  • Ippolito, J.A.,¬†C.M. Berry, D.G. Strawn, J.M. Novak, J. Levine, and A. Harley. 2017. Biochars reduce mine land soil bioavailable metals.¬†J. Environ. Qual. 46:411-419.¬†
  • Spokas, K.A, R. Weis, G. Feyereisen, D.W. Watts, J.M. Novak, T.J. Lee, and¬†J.A. Ippolito. 2017. Biomass or biochar ‚Äď Which is better at improving soil hydraulic properties?¬†Acta¬†Horticulturae.¬†1146.31:235-242.¬†
  • Laird, D.A., J.M. Novak, H.P. Collins,¬†J.A. Ippolito, D.L. Karlen, R.D. Lentz, K.R. Sistani, K. Spokas, and R.S. Van Pelt. 2017. Multi-year and multi-location soil quality and¬†crop biomass yield responses¬†to hardwood fast pyrolysis biochar.¬†Geoderma.¬†289:46-53.¬†
  • Novak, J.M.,¬†J.A. Ippolito, R.D. Lentz, K.A. Spokas, C.H. Bolster, K. Sistani, K.M. Trippe, and M.G. Johnson. 2016. Soil health, crop productivity, microbial transport, and mine spoil¬†response to biochars. Bioenergy¬†Res. 9:454-464.¬†
  • Ippolito, J.A., M.E. Stromberger, R.D. Lentz, and R.S. Dungan. 2016. Hardwood biochar and manure co-application to a calcareous soil. Chemosphere.¬†142:86-91.¬†
  • Elzobair, K.A., M.E. Stromberger, and¬†J.A. Ippolito. 2016. Stabilizing effect of biochar on soil extracellular enzymes after a denaturing stress.¬†Chemosphere.¬†142:114-119.¬†
  • Ippolito, J.A., T.F. Ducey, K.B. Cantrell, J.M. Novak, and R.D. Lentz. 2016. Designer, acidic biochar influences calcareous soil characteristics.¬†Chemosphere.¬†142:184-191.¬†
  • Elzobair, K.A., M.E. Stromberger,¬†J.A. Ippolito, and R.D. Lentz. 2016. Contrasting effects of biochar versus manure on soil microbial communities and enzyme activities in an¬†Aridisol.¬†Chemosphere.¬†142:145-152.¬†
  • Ippolito, J.A., J.¬†Grob, and A. Donnelly. 2015.¬†Anatomy of a field trial:¬†Wood-based biochar and compost influences a Pacific Northwest US soil. The Biochar Journal. Available at:¬†http://www.biochar-journal.org/en/ct/62-Anatomy-of-a-Field-Trial-Wood-based-Biochar-and-Compost-Influences-a-Pacific-Northwest-Soil.¬†
  • Thomazini, A., K. Spokas, K. Hall,¬†J. Ippolito, R. Lentz, and J. Novak. 2015. GHG¬†impacts¬†of biochar: Predictability for the same biochar. Agric.¬†Ecosys. Environ.¬†207:183-191.¬†
  • Ippolito, J.A., K.A. Spokas, J.M. Novak, R.D. Lentz, and K.B. Cantrell. 2015. Biochar elemental composition and factors influencing nutrient retention. In: Biochar for Environmental Management: Science, Technology and Implementation.¬†2nd¬†Ed.¬†(J.¬†Lehmann, and S. Joseph,¬†eds.), Routledge. New York, NY. pp. 137-161.¬†
  • Lentz, R.D.,¬†J.A. Ippolito, and K.A. Spokas. 2014. Biochar and manure effects on net N mineralization and greenhouse gas emissions from calcareous soil under corn. Soil Sci. Soc. Am. J.¬†78:1641‚Äď1655.¬†
  • Spokas, K.A., J.M. Novak, C.A.¬†Masiello, M.G. Johnson, E.C.¬†Colosky,¬†J.A. Ippolito, and C.T. Cordoba. 2014. Physical disintegration of biochar: An overlooked process. Environ. Sci. Technol. Letters.¬†1:326-332.¬†
  • Ippolito, J.A., M.E. Stromberger, R.D. Lentz, and R.S. Dungan. 2014. Hardwood biochar influences calcareous soil physicochemical and microbiological status. J. Environ. Qual. 43:681-689.¬†
  • Ducey, T.F.,¬†J.A. Ippolito, K.B. Cantrell, J.M. Novak, and R.D. Lentz. 2013.¬†Addition of activated¬†switchgrass¬†biochar to an aridic subsoil increases microbial nitrogen cycling gene abundances. Applied Soil Ecol.¬†65:65-72.¬†
  • Ippolito, J.A., D.A. Laird, and W.J.¬†Busscher. 2012. Environmental benefits of biochar. J. Environ. Qual. 41:973-989.¬†
  • Ippolito, J.A., J.M. Novak, D.G. Strawn, K.G. Scheckel, M.¬†Ahmedna, and M.A.S.¬†Niandou. 2012. Macroscopic and molecular approaches of copper sorption by a steam activated biochar. J. Environ. Qual. 41:1150-1156.¬†
  • Lentz, R.D., and¬†J.A. Ippolito. 2012. Biochar and manure affects calcareous soil and corn silage nutrients concentrations and uptake. J. Environ. Qual. 41:1033-1043.¬†
  • Spokas, K.A, K.B. Cantrell, J.M. Novak, D.A. Archer,¬†J.A. Ippolito, H.P. Collins, A.A.¬†Boatang, I.M. Lima, M.C. Lamb, A.J.¬†McAloon, R.D. Lentz, and K. Nichols. 2012. Biochar: A synthesis of its agronomic potential beyond carbon sequestration. J. Environ. Qual. 41:973-989.¬†
  • Novak, J.M., W.J.¬†Busscher, D.W. Watts,¬†¬†J.E. Amonette,¬†J.A. Ippolito, I.M. Lima, J. Gaskin, K.C. Das, C. Steiner, M.¬†Ahmedna, D.¬†Rehran, and H. Schomberg. 2012.¬†Biochars¬†impact on¬†soil moisture storage in an¬†Ultisol¬†and two¬†Aridisols. Soil Sci.¬†177:310-320.¬†

Water Treatment Residuals

  • Banet, T., I. Zohar, I.M. Litaor, M. Massey, and¬†J.A. Ippolito. 2020. Phosphorus removal from swine wastewater using aluminum-based water treatment residuals. Res.¬†Conserv.¬†Recycl. X. 6:100039.¬†https://doi.org/10.1016/j.rcrx.2020.100039.¬†
  • Zohar, I., N.B. Rose,¬†J.A. Ippolito, and I. Litaor. 2020. Phosphorus pools in Al and Fe-based water treatment residuals (WTRs) following mixing with agro-wastewater – a sequential extraction study. Environ. Technol. Innovation.¬†https://doi.org/10.1016/j.eti.2020.100654.¬†
  • Banet, T., M. Massey, I. Zohar, I. Litaor, and¬†J.A. Ippolito. 2020. Assessing modified aluminum-based water¬† treatment residuals as a plant-available phosphorus source. Chemosphere.¬†247: 125949.¬†
  • Litaor, M.I., S. Schechter, I. Zohar, M.S. Massey, and¬†J.A. Ippolito. 2019. Making phosphorus fertilizer from dairy wastewater with¬†aluminum water treatment residuals. Soil Sci. Soc. Am. J. 83:649-657.¬†
  • Massey, M.S., I. Zohar,¬†J.A. Ippolito, and I.M. Litaor. 2018. Phosphorus sorption to aluminum-based water treatment residuals reacted with dairy wastewater: 2. X-ray absorption spectroscopy. J. Environ. Qual. 47:546-553.¬†
  • Zohar, I., Litaor, M.I.,¬†J.A. Ippolito, and M. Massey. 2018.¬†Phosphorus¬†sorption characteristics in aluminum-based water treatment residuals reacted with dairy wastewater, 1: Isotherms, XRD and SEM-EDS analysis.¬†J. Environ. Qual. 47:538-545.¬†
  • Zohar, I., Litaor, M.I.,¬†J.A. Ippolito, and M. Massey. 2017. Innovative approach for agro-wastewater phosphorus removal using water treatment residuals. Chemosphere.¬†168:234-243.¬†
  • Ippolito, J.A.¬†2015. Aluminum-based water treatment residuals use in a constructed wetland for capturing urban runoff phosphorus: Column study. Water, Air, and Soil Pollution.¬†226:334.¬†
  • Ippolito, J.A., K.A. Barbarick, and H.A. Elliott. 2011.¬†Drinking water treatment residuals: A review of recent uses. J. Environ. Qual. 40:1-12.¬†
  • Ippolito, J.A., K.G. Scheckel, and K.A. Barbarick. 2009. Selenium adsorption to aluminum-based water treatment residuals. J. Colloid¬†Interf. Sci. 338:48-55.¬†
  • Ippolito, J.A., and K.A. Barbarick. 2006. Phosphorus extraction methods from water treatment residual-amended soil.¬†Commun. Soil Sci. Plant Anal.¬†37:859-870.¬†
  • Ippolito, J.A., K.A. Barbarick, D.M.¬†Heil, J.P. Chandler, and E.F. Redente. 2003. Phosphorus retention mechanisms of a water treatment residual.¬†J. Environ. Qual. 32:1857-1864.¬†

Phosphorus in the Environment

  • Afkairin, A.,¬†J.A. Ippolito, M. Stromberger, and J.G. Davis. 2021. Solubilization of organic phosphorus sources by cyanobacteria and a commercially available bacterial consortium. Applied Soil Ecology. 162, 103900.¬†
  • Banet, T., I. Zohar, I.M. Litaor, M. Massey, and¬†J.A. Ippolito. 2020. Phosphorus removal from swine wastewater using aluminum-based water treatment residuals. Res.¬†Conserv.¬†Recycl. X. 6:100039.¬†https://doi.org/10.1016/j.rcrx.2020.100039.¬†
  • Zohar, I., N.B. Rose,¬†J.A. Ippolito, and I. Litaor. 2020. Phosphorus pools in Al and Fe-based water treatment residuals (WTRs) following mixing with agro-wastewater – a sequential extraction study. Environ. Technol. Innovation.¬†https://doi.org/10.1016/j.eti.2020.100654.¬†
  • Banet, T., M. Massey, I. Zohar, I. Litaor, and¬†J.A. Ippolito. 2020. Assessing modified aluminum-based water¬† treatment residuals as a plant-available phosphorus source. Chemosphere.¬†247: 125949.¬†
  • Ippolito, J.A., D.L. Bjorneberg, M. Massey, and S.W.¬†Blecker. 2019. Mechanisms responsible for¬†soil phosphorus availability differences¬†between sprinkler and furrow irrigation. J. Environ. Qual. 48:1-10.¬†
  • Litaor, M.I., S. Schechter, I. Zohar, M.S. Massey, and¬†J.A. Ippolito. 2019. Making phosphorus fertilizer from dairy wastewater with¬†aluminum water treatment residuals. Soil Sci. Soc. Am. J. 83:649-657.¬†
  • Massey, M.S., I. Zohar,¬†J.A. Ippolito, and I.M. Litaor. 2018. Phosphorus sorption to aluminum-based water treatment residuals reacted with dairy wastewater: 2. X-ray absorption spectroscopy. J. Environ. Qual. 47:546-553.¬†
  • Zohar, I., Litaor, M.I.,¬†J.A. Ippolito, and M. Massey. 2018.¬†Phosphorus¬†sorption characteristics in aluminum-based water treatment residuals reacted with dairy wastewater, 1: Isotherms, XRD and SEM-EDS analysis.¬†J. Environ. Qual. 47:538-545.¬†
  • Zohar, I., Litaor, M.I.,¬†J.A. Ippolito, and M. Massey. 2017. Innovative approach for agro-wastewater phosphorus removal using water treatment residuals. Chemosphere.¬†168:234-243.¬†
  • Ippolito, J.A.¬†2015. Aluminum-based water treatment residuals use in a constructed wetland for capturing urban runoff phosphorus: Column study. Water, Air, and Soil Pollution.¬†226:334.¬†
  • Bjorneberg, D.L., A.B. Leytem,¬†J.A. Ippolito, and A.C. Koehn. 2015. Phosphorus losses from an irrigated watershed in the northwestern U.S.: Case study of the Upper Snake Rock Watershed. J. Environ. Qual. 44:552-559.¬†
  • Ippolito, J.A, R. Spackman, J.A. Entry, and R.E¬†Sojka. 2014.¬†Removal of vegetative clippings reduces dissolved phosphorus loss in runoff.¬†Commun. Soil Sci. Plant Anal.¬†45:1555-1564.¬†
  • Ippolito, J.A., and N.O. Nelson. 2013. Assessment of phosphorus retention in irrigation canals. J. Soil Water¬†Conserv.¬†68:450-459.¬†
  • Hines, S., A. Moore, B. Brown, M.¬†Chahine, R.¬†Norell, M.E.¬†deHaro¬†Marti, C.¬†Falen, T. Fife, S. Parkinson, and¬†J. Ippolito. 2012. Using¬†extension phosphorus uptake research¬†to improve Idaho‚Äôs nutrient management planning program. Journal of Extension [On-line], 50(5), Article 5RIB10. Available at:¬†http://www.joe.org/joe/2012october/rb10.php.¬†
  • Ippolito, J.A., K.A. Barbarick, and H.A. Elliott. 2011.¬†Drinking water treatment residuals: A review of recent uses. J. Environ. Qual. 40:1-12.¬†
  • Ippolito, J.A., S.W.¬†Blecker, C.L. Freeman‚Ć, R.L.¬†McCulley, J.M. Blair, and E.F. Kelly. 2010.¬†Phosphorus biogeochemistry across a precipitation gradient in grasslands of central North America. J. Arid Environ. 74:954- 961.¬†
  • Massey, M.S.,¬†J.A. Ippolito, J.G. Davis, and R.E. Sheffield. 2010. Macroscopic and microscopic variation in recovered magnesium phosphate materials: Implications for phosphorus removal processes and product re-use.¬†Bioresour. Technol. 101:877-885.¬†
  • Massey, M., J. Davis,¬†J. Ippolito, and R. Sheffield. 2009. Effectiveness of recovered magnesium phosphates as fertilizers in neutral and¬†slightly alkaline soils. Agronomy¬†J. 101:323-329.¬†
  • Bayley, R.M.,¬†J.A. Ippolito, M.E. Stromberger, K.A. Barbarick, and M.W. Paschke. 2008. Water treatment residuals and biosolids co-applications affect the activity of phosphatases in a semi-arid rangeland soil.¬†Commun. Soil Sci. Plant Anal.¬†39:2812-2826.¬†
  • Bayley, R.M.,¬†J.A. Ippolito, M.E. Stromberger, K.A. Barbarick, and M.W. Paschke. 2008. Water treatment residuals and biosolids¬†coapplications¬†affect semi-arid rangeland phosphorus cycling. Soil Sci. Soc. Am. J. 72:711-719.¬†
  • Blecker, S.W.,¬†J.A. Ippolito, J.E. Barrett, D.H. Wall, R.A. Virginia, and¬†K.L.¬†Norvell.¬†2006. Phosphorus fractionation implications in soils of Taylor Valley, Antarctica. Soil Sci. Soc. Am. J. 70:806-815.¬†
  • Ippolito, J.A., and K.A. Barbarick. 2006. Phosphorus extraction methods from water treatment residual-amended soil.¬†Commun. Soil Sci. Plant Anal.¬†37:859-870.¬†
  • Ippolito, J.A., K.A. Barbarick, D.M.¬†Heil, J.P. Chandler, and E.F. Redente. 2003. Phosphorus retention mechanisms of a water treatment residual.¬†J. Environ. Qual. 32:1857-1864.¬†

Metals in the Environment

  • Li, L., Y. Zhang,¬†J.A. Ippolito, W. Xing, and C. Tu. 2021. Lead smelting alters wheat flour heavy metal concentrations and health risks. J. Environ. Qual.¬†50:454-464.¬†
  • Xing, W., H. Yang,¬†J.A. Ippolito, Q. Zhao, Y. Zhang, K.G. Scheckel, and L. Li. 2020. Atmospheric deposition of As, Cd, Cu, Pb and Zn near an operating and an abandoned lead smelter. J. Environ. Qual. 49:1667-1678.¬†
  • Xing, W., H. Yang,¬†J.A. Ippolito, Y. Zhang, K.G. Scheckel, and L. Li. 2020. Lead source and bioaccessibility in windowsill dusts within a Pb smelting-affected area. Environ.¬†Pollut.¬†266:115110.¬†
  • Li, L., W. Xing, H. Liu, T. Banet, H. Wang, and¬†J.A. Ippolito. 2020. Cadmium, copper, lead and zinc accumulation in wild plant species near a lead smelter.¬†Ecotox. Environ. Safe.¬†198:110683.¬†
  • Li, L., Y. Zhang,¬†J.A. Ippolito, W. Xing, K. Qiu, and Y. Wang. 2020. Cadmium foliar application affects wheat Cd, Cu, Pb and Zn accumulation. Environ.¬†Pollut.¬†262: 114329.¬†
  • Li, L., Y. Zhang,¬†J.A. Ippolito, W. Xing, and Y. Cheng. 2020. Lead smelting effects heavy metal concentrations in soils, wheat, and potentially humans. Environ.¬†Pollut.¬†257:113641.¬†https://doi.org/10.1016/j.envpol.2019.113641.¬†
  • Miner, G.L.,¬†J.A. Delgado,¬†J.A. Ippolito, K.A. Barbarick, C.E. Stewart, D.K. Manter, S.J. Del Grosso, A.D. Halvorson, B. Floyd, and R. D‚ÄôAdamo. 2018. Influence of long-term nitrogen fertilization on crop and soil micronutrients in a no-till maize cropping system. Field Crops Res. 228:170-182.¬†
  • Ippolito, J.A., D.G. Strawn, and K.G. Scheckel. 2013. Investigation of copper sorption by sugar beet processing lime waste. J. Environ. Qual. 42:919-924.¬†
  • Miguel, R.E.,¬†J.A. Ippolito, A.A. Porta, R.B. Banda Noriega, and R.S. Dungan. 2013.¬†Use of standardized procedures to evaluate metal leaching from waste foundry sands. J. Environ. Qual. 42:615-620.¬†
  • Miguel, R.E.,¬†J.A. Ippolito, A.B. Leytem, A.A. Porta, R.B. Banda Noriega, and R.S. Dungan. 2012. Analysis of total metals in waste molding and core sands from ferrous and non-ferrous foundries. J. Environ. Manage.¬†110:77-81.¬†
  • Ippolito, J.A., T.F. Ducey, and D.D. Tarkalson. 2011. Interactive effects of copper on alfalfa growth, soil copper, and soil bacteria. World J. Agric. Sci. 3:138-148.¬†
  • Ippolito, J.A., T.F. Ducey, and D.D. Tarkalson. 2010. Copper¬†impacts on¬†corn, soil extractability, and the soil bacterial community. Soil Sci. 175:586-592.¬†
  • Ippolito, J.A., K.G. Scheckel, and K.A. Barbarick. 2009. Selenium adsorption to aluminum-based water treatment residuals. J. Colloid¬†Interf. Sci. 338:48-55.¬†
  • Ghasemi-Fasaei, R.,¬† M.¬†Maftoun, A. Ronaghi, N.¬†Karimian, J.¬†Yasrebi, M.T Assad, and¬†J. Ippolito. 2006. Kinetics of copper desorption from highly calcareous soils.¬†Commun. Soil Sci. Plant Anal.¬†37:797-809.¬†

Other Environmental Articles

  • Harris, F.,¬†J. Dobbs, D. Atkins,¬†J.A. Ippolito, and J.E. Stewart. 2021. Soil fertility interactions with¬†Sinorhizobium-legume symbiosis in a simulated Martian regolith; effects on nitrogen content and plant health.¬†PLOS One.¬†16¬†(9): e0257053 DOI:‚ÄĮ10.1371/journal.pone.0257053.¬†
  • Lentz, R.D., and¬†J.A. Ippolito. 2021. Cross-linked polymers¬†increase nutrient sorption in¬†degraded soils. Agronomy J.¬†1-15.¬†
  • Bjorneberg, D., B. King, A. Koehn, and¬†J.A. Ippolito. 2020. Moving toward sustainable irrigation in a southern Idaho¬†irrigation project. Trans. ASABE.¬†https://doi.org/10.13031/trans.13955.¬†
  • Dungan, R., A. Leytem,¬†J. Ippolito, and D. Tarkalson. 2017. Greenhouse gas emissions from an irrigated dairy forage rotation as influenced by fertilizer and manure applications. Soil Sci. Soc. Am. J. 81:437-545.¬†
  • Tarkalson, D.D., and¬†J.A. Ippolito. 2011.¬†Clinoptilolite¬†zeolite influence on nitrogen in a manure amended sandy agricultural soil.¬†Commun. Soil Sci. Plant. Anal.¬†42:2370-2378.¬†
  • Ippolito, J.A., D.D. Tarkalson, and G.A.¬†Lehrsch. 2011. Zeolite soil application method affects inorganic nitrogen, moisture, and corn growth. Soil Sci. 176:136-142.¬†
  • Ippolito, J.A., K.A. Barbarick, and H.A. Elliott. 2011.¬†Drinking water treatment residuals: A review of recent uses. J. Environ. Qual. 40:1-12.¬†
  • Tarkalson, D.D., and¬†J.A. Ippolito. 2010.¬†Clinoptilolite¬†zeolite influence on inorganic nitrogen in silt loam and sandy agricultural soils. Soil Sci. 175:357-362.¬†
  • Blecker, S.W., S.L. King, L.A. Derry, O.A. Chadwick,¬†J.A. Ippolito, and E.F. Kelly. 2007. The ratio of germanium to silicon in plant¬†phytoliths: Quantification of biological fractionation under controlled experimental conditions.¬†Biogeochem. 86:189-199.¬†
  • Ippolito, J.A., E.F. Redente, and K.A. Barbarick. 2005. Amendments affect pH and salt content of bauxite residue. Soil Sci. 170:832-841.¬†
  • Bauder, T.A., K.A. Barbarick,¬†J.A. Ippolito, J.F. Shanahan, and P. Ayers. 2005.¬†Soil properties affecting wheat yields following drilling-fluid application. J. Environ. Qual. 34:1687-1696.¬†
  • Ippolito, J.A., and K.A. Barbarick. 2000. Modified nitric acid plant tissue digest method.¬†Commun. Soil Sci. Plant Anal.¬†31:2473-2482.¬†
  • Soltanpour, P.N., M.M. Al-Wardy,¬†J.A. Ippolito, J.B. Rodriguez, J. Self, M.¬†Gillaume, and D. Mathews. 1999.¬†¬†Chloride versus sulfate salinity effects on alfalfa shoot growth and ionic balance. Soil Sci. Soc. Am. J. 63:111-116.¬†

Big Data and Educational Materials

  • Harmel, D., P. Kleinman, M. Eve,¬†J.A. Ippolito, S. Beebout, J. Delgado, B. Vandenberg, and M. Buser. 2021. Partnerships for Data Innovations (PDI): Facilitating stewardship and catalyzing research engagement in the digital age. Agric. Environ. Letters.¬†https://doi.org/10.1002/ael2.20055.¬†
  • Mamo, M.,¬†J. Ippolito, T.¬†Kettler, R. Reuter, D.¬†McCallister, P.¬†Morner, D.¬†Husmann, and E. Blankenship. 2011. Learning gains and response to digital lessons on soil genesis and development.¬†J.¬†Geosci. Ed.¬†59:194-204.¬†
  • McCallister, D., C.¬†Geiss, M. Mamo, T.¬†Kettler,¬†J. Ippolito, R. Reuter, P.¬†Morner, and J.¬†Soester. 2009. Soil genesis¬† and development, lesson 1: Rocks, minerals, and soil.‚ÄĮ J. Nat. Res. Life Sci. Ed. 38: 238. (web-based¬†lesson available at:¬†http://plantandsoil.unl.edu/croptechnology2005/soil_sci/).¬†
  • Mamo, M., T.¬†Kettler,¬†J. Ippolito, R. Reuter, D.¬†McCallister, P.¬†Morner, and J.¬†Soester. 2009. Soil genesis and development, lesson 2: Weathering processes of rocks and minerals. J. Nat. Res. Life Sci. Ed. 38:238. (web-based¬†lesson available at:¬†http://plantandsoil.unl.edu/croptechnology2005/soil_sci/).¬†
  • Ippolito, J., M. Mamo, T.¬†Kettler, R. Reuter, D.¬†McCallister, P.¬†Morner, and J.¬†Soester. 2009. Soil genesis and¬†development, lesson 3: Soil Forming Factors. J. Nat. Res. Life Sci. Ed. 38:239.¬†(web-based¬†lesson available at:¬†¬†http://plantandsoil.unl.edu/croptechnology2005/soil_sci/).¬†
  • Reuter, R., M. Mamo, T.¬†Kettler,¬†J. Ippolito, D.¬†McCallister, P.¬†Morner, and J.¬†Soester. 2009. Soil genesis and development, lesson 4: Soil Profile Development. J. Nat. Res. Life Sci. Ed. 38:239. (web-based¬†lesson available at:¬†http://plantandsoil.unl.edu/croptechnology2005/soil_sci/).¬†
  • Kettler, T., W.¬†Zanner, M. Mamo,¬†J. Ippolito, R. Reuter, D.¬†McCallister, P.¬†Morner, and J.¬†Soester. 2009. Soil genesis and development, lesson 5: Soil Classification and geography. J. Nat. Res. Life Sci. Ed. 38:240.¬†(web-based¬†lesson available at:¬†¬†http://plantandsoil.unl.edu/croptechnology2005/soil_sci/).¬†
  • Barbarick, K.A.,¬†J.A. Ippolito, G. Butters, and G.M.¬†Sorge. 2005. An infiltration exercise for introductory soil science.¬†J. Nat. Res. Life Sci. Ed.¬†34:72-76.¬†
  • Barbarick, K.A., and¬†J.A. Ippolito.¬†2003. Does the number of hours¬†studied¬†affect exam performance?¬†J. Nat. Res. Life Sci. Ed. 32:32-35.¬†
  • Ippolito, J.A.¬†and K.A. Barbarick. 2003. A simple C/N assay for Introductory Soil Science classes.¬†J. Nat. Res. Life Sci. Ed. 32:69-72.¬†
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