about
Ultramafic geoecology of South and Southeast AsiaRange extension of Christisonia scortechinii from mainland Southeast Asia into Borneo, and notes on the distinction between Aeginetia and Christisonia (Orobanchaceae).Pittosporum peridoticola (Pittosporaceae), a new ultramafic obligate species restricted to Kinabalu Park (Sabah, Malaysia)Actephila alanbakeri (Phyllanthaceae): a new nickel hyperaccumulating plant species from localised ultramafic outcrops in Sabah (Malaysia).Copper and cobalt accumulation in plants: a critical assessment of the current state of knowledge.Environmental geochemistry of the abandoned Mamut Copper Mine (Sabah) Malaysia.Nickel biopathways in tropical nickel hyperaccumulating trees from Sabah (Malaysia)Agromining: farming for metals in the future?Multi-element concentrations in plant parts and fluids of Malaysian nickel hyperaccumulator plants and some economic and ecological considerations.Commentary: Toward a more physiologically and evolutionarily relevant definition of metal hyperaccumulation in plants.Extreme nickel hyperaccumulation in the vascular tracts of the tree Phyllanthus balgooyi from Borneo.X-ray elemental mapping techniques for elucidating the ecophysiology of hyperaccumulator plants.A global database for plants that hyperaccumulate metal and metalloid trace elements.Phyllanthus rufuschaneyi: a new nickel hyperaccumulator from Sabah (Borneo Island) with potential for tropical agromining.Simultaneous hyperaccumulation of nickel and cobalt in the tree Glochidion cf. sericeum (Phyllanthaceae): elemental distribution and chemical speciation.Contrasting nickel and zinc hyperaccumulation in subspecies of Dichapetalum gelonioides from Southeast Asia.Hyperaccumulator plants from China: a synthesis of the current state of knowledgeSynchrotron-Based X-Ray Fluorescence Microscopy as a Technique for Imaging of Elements in PlantsImpacts of ultramafic outcrops in Peninsular Malaysia and Sabah on soil and water qualityX-Ray Fluorescence Ionomics of Herbarium CollectionsAbnormal concentrations of Cu-Co in Haumaniastrum katangense, Haumaniastrum robertii and Aeolanthus biformifolius: contamination or hyperaccumulation?Sustaining metal-loving plants in mining regionsDistribution and chemical form of selenium in Neptunia amplexicaulis from Central Queensland, AustraliaPhylogenetic and geographic distribution of nickel hyperaccumulation in neotropical PsychotriaAbsorption of foliar-applied Zn in sunflower (Helianthus annuus): importance of the cuticle, stomata and trichomesSpatially-resolved localization and chemical speciation of nickel and zinc in Noccaea tymphaea and Bornmuellera emarginataEndosperm prevents toxic amounts of Zn from accumulating in the seed embryo - an adaptation to metalliferous sites in metal-tolerant Biscutella laevigataAssessing radiation dose limits for X-ray fluorescence microscopy analysis of plant specimensElemental distribution and chemical speciation of copper and cobalt in three metallophytes from the copper-cobalt belt in Northern ZambiaDistribution of aluminium in hydrated leaves of tea (Camellia sinensis) using synchrotron- and laboratory-based X-ray fluorescence microscopyConfocal Volumetric μXRF and Fluorescence Computed μ-Tomography Reveals Arsenic Three-Dimensional Distribution within Intact Pteris vittata FrondsSpatially Resolved Localization of Lanthanum and Cerium in the Rare Earth Element Hyperaccumulator Fern Dicranopteris linearis from ChinaStress responses and nickel and zinc accumulation in different accessions of Stellaria media (L.) Vill. in response to solution pH variation in hydroponic cultureMethods to Visualize Elements in PlantsUptake, translocation and accumulation of nickel and cobalt in Berkheya coddii, a 'metal crop' from South Africa
P50
Q30376749-A377D42C-4694-459F-999C-FA8786D10262Q33680605-FE2C3CF0-36B3-482D-B844-65E90560F371Q33691115-4466C4DF-FBC8-4D0C-81C5-16DBEA3F9185Q33691138-53C20549-A167-4DEA-A0F2-C6E222C627B8Q36131982-0A0C38D5-8337-42DE-9536-7A6440B8B015Q36193689-C028A5A9-C218-41BA-8142-B3D590A2B1CAQ37644363-0C714901-ED98-49C4-ADE3-E21FDE3B9444Q39037028-247FD345-A3C6-446A-8074-1A3981E45424Q39548881-3B5E3234-3DAC-4614-BF59-AB7A2E5D7F2EQ42251327-7C7F4F89-B31C-4F59-93A9-B97CF6422B04Q46527597-207D09CD-F011-4DC1-8698-9F34C0E1E233Q47906692-3EF9BA0C-3206-43BE-BC6A-044713B200A0Q48302500-5B3C705B-BCC4-4911-92E4-4EDDC7A7EDE3Q52626337-6CD1EEE9-AE31-491F-BAAE-A99412957BC7Q55425311-6E1EB0B8-25E3-498D-BC8D-4267A170F36DQ55428348-9AAA1FD4-D002-48F5-8A8D-33389CE67867Q57054749-8C64FFBB-E91E-49FC-98BF-73B987783F01Q57145118-541318E4-B07D-4A4B-BE90-DD2B32406690Q57861187-14FE5371-F821-40B7-994F-66AA42F771F5Q64082620-7C1125D3-B987-47DE-B01B-8F8528F5CDB3Q64360417-CFBE8E7F-BEB2-4ABB-9EFC-DD5F9E3249D2Q84943100-275E24A9-655F-427A-9471-8043A904A8AEQ89705254-2199256E-62DB-43CC-8FE3-1228B2DB120AQ90278202-055A4B09-E8F2-4A24-B747-8711DDCE74F1Q90312577-0813E496-1A8B-41AE-B04B-04923A6BA235Q90937427-EEB25CE3-4305-438C-B28A-E7F1321D8960Q91263782-48D4B8F1-E089-4693-BD6A-02CE40A82487Q91504113-4E4CE348-CC33-42E9-A794-1F8266BFAE03Q91627675-00666BAE-A4FA-4143-8C93-3CB95C49CA16Q91719023-2C909AF4-C7B7-4ACF-B358-3E3A0C9BE97BQ92348975-3EF5CA94-70E0-41C4-914E-F9E71AC896D7Q92728292-2083A798-BCC5-4417-8E26-BB8A3263948BQ92774337-4B9CCB88-7365-4C8A-B8AD-070FBA39BD54Q92888371-3A481B6D-6540-41F5-98D3-AB5DB533C518Q96588812-6E801382-CCFC-47CC-B17E-C1553CD424EC
P50
description
researcher ORCID ID = 0000-0003-0922-5065
@en
wetenschapper
@nl
name
Antony van der Ent
@ast
Antony van der Ent
@en
Antony van der Ent
@es
Antony van der Ent
@nl
type
label
Antony van der Ent
@ast
Antony van der Ent
@en
Antony van der Ent
@es
Antony van der Ent
@nl
prefLabel
Antony van der Ent
@ast
Antony van der Ent
@en
Antony van der Ent
@es
Antony van der Ent
@nl
P1153
55221967200
P21
P31
P496
0000-0003-0922-5065