D. A. Olsen scite author profile

Summary 1. We studied the relative contributions of the magnitude and direction of vertical hydrological exchange, subsurface sediment composition and interstitial physicochemistry in determining the distribution of hyporheic invertebrates in the Kye Burn, a fourth order gravel‐bed stream in New Zealand. 2. In winter 2000 and summer 2001, we measured vertical hydrological gradient (VHG), dissolved oxygen, water temperature and water chemistry using mini‐piezometers, each installed in a different upwelling or downwelling zone. Next to every piezometer, a freeze core sample was taken to quantify the sediment, particulate organic matter and invertebrates. 3. Dissolved oxygen concentration at 25 cm was high on both occasions (>9 mg L−1) but was higher in winter than summer. Interstitial water temperature was higher in down than upwellings and was substantially higher in summer than winter. Other features of the subsurface sediments and interstitial nitrate–nitrite concentrations were similar on both occasions and in up and downwellings. Interstitial ammonium and soluble reactive phosphorous concentrations were higher in winter than summer and ammonium was higher in up than downwelling areas. 4. The proportion of fine sediment (63 μm–1 mm), sediment heterogeneity and VHG accounted for the greatest proportion of variance in invertebrate distributions in both summer and winter. 5. The hyporheos was numerically dominated by early instar leptophlebiid mayfly nymphs and asellotan isopods. Water mites were a taxonomically diverse group with 13 genera. Taxonomic diversity (Shannon–Weaver), but not taxon richness, was higher in upwelling areas, reflecting lower numerical dominance by a few taxa in these locations. 6. Sediment composition (particularly the amount of fine sediments) and vertical hydrological exchange determined the composition and distribution of the hyporheos. Patchiness in these factors is important in planning sampling regimes or field manipulations in the hyporheic zone.

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Flood effects on invertebrates, sediments and particulate organic matter in the hyporheic zone of a gravel‐bed stream

Olsen

Townsend

2005

Freshwater Biology

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1. We investigated the effects of a flood on the fauna and physical habitat of the hyporheic zone of the Kye Burn, a fourth order gravel-bed stream in New Zealand. 2. Freeze core hyporheic samples (to 50 cm depth) and benthic samples (to 10 cm) were taken, along with measurements of vertical hydrological gradient, before, 2 days after and 1 month after the flood (estimated return period: 1.5 years, estimated Q max ¼ 10.4 m 3 s )1 ). 3. The composition of the hyporheos differed over the three sampling occasions with fewer taxa collected immediately postflood than preflood. The equitability of the community was higher on both postflood occasions, consistent with the reduced densities of two abundant taxa (Leptophlebiidae and Copepoda). 4. Total invertebrate abundance was lower on the postflood occasions than preflood in both benthic (0-10 cm) and hyporheic (10-50 cm) sediments. Several taxa, including asellotan isopods and amphipods, recovered within 1 month of the event. Hyporheic densities of larval Hydora and nematodes did not differ among the three sampling occasions, but the water mite Pseudotryssaturus was more abundant 1 month after the flood than preflood. There was no evidence of vertical movements (to 50 cm) by any taxa in response to the flood. 5. The proportion of fine sediments (<1 mm) in the subsurface sediments (10-50 cm) increased over the three sampling occasions and median particle size declined, but sediment porosity did not change. More particulate organic matter was found in the sediments after the flood. 6. Our study provides little evidence that the hyporheic zone (to 50 cm) acted as a significant refuge during the flood event, although movements to or recolonisation from sediments deeper than 50 cm could explain the recovery of many crustacean and mite taxa within 1 month.

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Habitat suitability curves for benthic macroinvertebrates from a small New Zealand river

Shearer

Hayes

Jowett³

et al. 2015

New Zealand Journal of Marine and Freshwater Research

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Influence of reach geomorphology on hyporheic communities in a gravel‐bed stream

Olsen¹,

Townsend

Matthaei

2001

New Zealand Journal of Marine and Freshwater Research

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Importance des interactions entre les eaux de surface et les eaux souterraines pour les modèles thermiques au niveau de biefs et pour le potentiel de croissance des truites: exemple de la rivière de Motueka (Nouvelle Zélande)

Olsen

Young

2008

Hydrogeol J

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D. A. Olsen

Hyporheic community composition in a gravel‐bed stream: influence of vertical hydrological exchange, sediment structure and physicochemistry

Flood effects on invertebrates, sediments and particulate organic matter in the hyporheic zone of a gravel‐bed stream

Habitat suitability curves for benthic macroinvertebrates from a small New Zealand river

Influence of reach geomorphology on hyporheic communities in a gravel‐bed stream

Importance des interactions entre les eaux de surface et les eaux souterraines pour les modèles thermiques au niveau de biefs et pour le potentiel de croissance des truites: exemple de la rivière de Motueka (Nouvelle Zélande)

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