TY  - GEN
A1  - Dietze, Michael
A1  - Krautblatter, Michael
A1  - Illien, Luc
A1  - Hovius, Niels
T1  - Seismic constraints on rock damaging related to a failing mountain peak
BT  - The Hochvogel, Allgäu
T2  - Zweitveröffentlichungen der Universität Potsdam : Mathematisch-Naturwissenschaftliche Reihe
N2  - Large rock slope failures play a pivotal role in long-term landscape evolution and are a major concern in land use planning and hazard aspects. While the failure phase and the time immediately prior to failure are increasingly well studied, the nature of the preparation phase remains enigmatic. This knowledge gap is due, to a large degree, to difficulties associated with instrumenting high mountain terrain and the local nature of classic monitoring methods, which does not allow integral observation of large rock volumes. Here, we analyse data from a small network of up to seven seismic sensors installed during July-October 2018 (with 43 days of data loss) at the summit of the Hochvogel, a 2592 m high Alpine peak. We develop proxy time series indicative of cyclic and progressive changes of the summit. Modal analysis, horizontal-to-vertical spectral ratio data and end-member modelling analysis reveal diurnal cycles of increasing and decreasing coupling stiffness of a 260,000 m(3) large, instable rock volume, due to thermal forcing. Relative seismic wave velocity changes also indicate diurnal accumulation and release of stress within the rock mass. At longer time scales, there is a systematic superimposed pattern of stress increased over multiple days and episodic stress release within a few days, expressed in an increased emission of short seismic pulses indicative of rock cracking. Our data provide essential first order information on the development of large-scale slope instabilities towards catastrophic failure. (c) 2020 The Authors. Earth Surface Processes and Landforms published by John Wiley & Sons Ltd
T3  - Zweitveröffentlichungen der Universität Potsdam : Mathematisch-Naturwissenschaftliche Reihe - 1360 
KW  - environmental seismology
KW  - fatigue
KW  - fundamental frequency
KW  - HVSR
KW  - mass
KW  - wasting
KW  - mountain geomorphology
KW  - natural hazard
KW  - noise cross
KW  - correlation
KW  - seismic monitoring
KW  - slope failure
Y1  - 2021
U6  - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:kobv:517-opus4-568787
SN  - 1866-8372
IS  - 2
ER  - 
TY  - GEN
A1  - Emberson, Robert
A1  - Hovius, Niels
A1  - Galy, Albert
A1  - Marc, Odin
T1  - Oxidation of sulfides and rapid weathering in recent landslides
T2  - Postprints der Universität Potsdam : Mathematisch-Naturwissenschaftliche Reihe
N2  - Linking together the processes of rapid physical erosion and the resultant chemical dissolution of rock is a crucial step in building an overall deterministic understanding of weathering in mountain belts. Landslides, which are the most volumetrically important geomorphic process at these high rates of erosion, can generate extremely high rates of very localised weathering. To elucidate how this process works we have taken advantage of uniquely intense landsliding, resulting from Typhoon Morakot, in the T'aimali River and surrounds in southern Taiwan. Combining detailed analysis of landslide seepage chemistry with estimates of catchment-by-catchment landslide volumes, we demonstrate that in this setting the primary role of landslides is to introduce fresh, highly labile mineral phases into the surface weathering environment. There, rapid weathering is driven by the oxidation of pyrite and the resultant sulfuric-acid-driven dissolution of primarily carbonate rock. The total dissolved load correlates well with dissolved sulfate - the chief product of this style of weathering - in both landslides and streams draining the area (R-2 = 0.841 and 0.929 respectively; p < 0.001 in both cases), with solute chemistry in seepage from landslides and catchments affected by significant landsliding governed by the same weathering reactions. The predominance of coupled carbonate-sulfuric-acid-driven weathering is the key difference between these sites and previously studied landslides in New Zealand (Emberson et al., 2016), but in both settings increasing volumes of landslides drive greater overall solute concentrations in streams.

Bedrock landslides, by excavating deep below saprolite-rock interfaces, create conditions for weathering in which all mineral phases in a lithology are initially unweathered within landslide deposits. As a result, the most labile phases dominate the weathering immediately after mobilisation and during a transient period of depletion. This mode of dissolution can strongly alter the overall output of solutes from catchments and their contribution to global chemical cycles if landslide-derived material is retained in catchments for extended periods after mass wasting.
T3  - Zweitveröffentlichungen der Universität Potsdam : Mathematisch-Naturwissenschaftliche Reihe - 553 
KW  - physical erosion
KW  - Mountain Belt
KW  - Southwestern Taiwan
KW  - athmospheric CO2
KW  - New-Zealand
KW  - climatic controls
KW  - Himalayan Rivers
KW  - Southern Alps
KW  - carbon-cycle
KW  - model
Y1  - 2019
U6  - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:kobv:517-opus4-412326
SN  - 1866-8372
IS  - 553
ER  - 
TY  - JOUR
A1  - Bufe, Aaron
A1  - Cook, Kristen L.
A1  - Galy, Albert
A1  - Wittmann, Hella
A1  - Hovius, Niels
T1  - The effect of lithology on the relationship between denudation rate and chemical weathering pathways
BT  - evidence from the eastern Tibetan Plateau
JF  - Earth surface dynamics
N2  - The denudation of rocks in mountain belts exposes a range of fresh minerals to the surface of the Earth that are chemically weathered by acidic and oxygenated fluids. The impact of the resulting coupling between denudation and weathering rates fundamentally depends on the types of minerals that are weathering. Whereas silicate weathering sequesters CO2, the combination of sulfide oxidation and carbonate dissolution emits CO2 to the atmosphere. Here, we combine the concentrations of dissolved major elements in stream waters with Be-10 basin-wide denudation rates from 35 small catchments in eastern Tibet to elucidate the importance of lithology in modulating the relationships between denudation rate, chemical weathering pathways, and CO2 consumption or release. Our catchments span 3 orders of magnitude in denudation rate in low-grade flysch, high-grade metapelites, and granitoid rocks. For each stream, we estimate the concentrations of solutes sourced from silicate weathering, carbonate dissolution, and sulfide oxidation using a mixing model. We find that for all lithologies, cation concentrations from silicate weathering are largely independent of denudation rate, but solute concentrations from carbonates and, where present, sulfides increase with increasing denudation rate. With increasing denudation rates, weathering may therefore shift from consuming to releasing CO2 in both (meta)sedimentary and granitoid lithologies. For a given denudation rate, we report dissolved solid concentrations and inferred weathering fluxes in catchments underlain by (meta)sedimentary rock that are 2-10 times higher compared to catchments containing granitoid lithologies, even though climatic and topographic parameters do not vary systematically between these catchments. Thus, varying proportions of exposed (meta)sedimentary and igneous rocks during orogenesis could lead to changes in the sequestration and release of CO2 that are independent of denudation rate.
Y1  - 2022
U6  - https://doi.org/10.5194/esurf-10-513-2022
SN  - 2196-6311
SN  - 2196-632X
VL  - 10
IS  - 3
SP  - 513
EP  - 530
PB  - Copernicus
CY  - Göttingen
ER  - 
TY  - JOUR
A1  - Menges, Johanna
A1  - Hovius, Niels
A1  - Andermann, Christoff
A1  - Dietze, Michael
A1  - Swoboda, Charlie
A1  - Cook, Kristen L.
A1  - Adhikari, Basanta R.
A1  - Vieth-Hillebrand, Andrea
A1  - Bonnet, Stephane
A1  - Reimann, Tony
A1  - Koutsodendris, Andreas
A1  - Sachse, Dirk
T1  - Late holocene landscape collapse of a trans-himalayan dryland
BT  - human impact and aridification
JF  - Geophysical research letters
N2  - Soil degradation is a severe and growing threat to ecosystem services globally. Soil loss is often nonlinear, involving a rapid deterioration from a stable eco-geomorphic state once a tipping point is reached. Soil loss thresholds have been studied at plot scale, but for landscapes, quantitative constraints on the necessary and sufficient conditions for tipping points are rare. Here, we document a landscape-wide eco-geomorphic tipping point at the edge of the Tibetan Plateau and quantify its drivers and erosional consequences. We show that in the upper Kali Gandaki valley, Nepal, soil formation prevailed under wetter conditions during much of the Holocene. Our data suggest that after a period of human pressure and declining vegetation cover, a 20% reduction of relative humidity and precipitation below 200 mm/year halted soil formation after 1.6 ka and promoted widespread gullying and rapid soil loss, with irreversible consequences for ecosystem services.
KW  - geomorphology
KW  - paleoclimate
KW  - human activity
KW  - Tibetan plateau
KW  - late Holocene
Y1  - 2019
U6  - https://doi.org/10.1029/2019GL084192
SN  - 0094-8276
SN  - 1944-8007
VL  - 46
IS  - 23
SP  - 13814
EP  - 13824
PB  - American Geophysical Union
CY  - Washington
ER  - 
TY  - JOUR
A1  - Hemingway, Jordon Dennis
A1  - Hilton, Robert G.
A1  - Hovius, Niels
A1  - Eglinton, Timothy I.
A1  - Haghipour, Negar
A1  - Wacker, Lukas
A1  - Chen, Meng-Chiang
A1  - Galy, Valier V.
T1  - Microbial oxidation of lithospheric organic carbon in rapidly eroding tropical mountain soils
JF  - Science
N2  - Lithospheric organic carbon ("petrogenic"; OCpetro) is oxidized during exhumation and subsequent erosion of mountain ranges. This process is a considerable source of carbon dioxide (CO2) to the atmosphere over geologic time scales, but the mechanisms that govern oxidation rates in mountain landscapes are poorly constrained. We demonstrate that, on average, 67 +/- 11% of the OCpetro initially present in bedrock exhumed from the tropical, rapidly eroding Central Range of Taiwan is oxidized in soils, leading to CO2 emissions of 6.1 to 18.6 metric tons of carbon per square kilometer per year. The molecular and isotopic evolution of bulk OC and lipid biomarkers during soil formation reveals that OCpetro remineralization is microbially mediated. Rapid oxidation in mountain soils drives CO2 emission fluxes that increase with erosion rate, thereby counteracting CO2 drawdown by silicate weathering and biospheric OC burial.
Y1  - 2018
U6  - https://doi.org/10.1126/science.aao6463
SN  - 0036-8075
SN  - 1095-9203
VL  - 360
IS  - 6385
SP  - 209
EP  - +
PB  - American Assoc. for the Advancement of Science
CY  - Washington
ER  - 
TY  - JOUR
A1  - Marc, Odin
A1  - Hovius, Niels
A1  - Meunier, P.
T1  - The mass balance of earthquakes and earthquake sequences
JF  - Geophysical research letters
N2  - Large, compressional earthquakes cause surface uplift aswell as widespread mass wasting. Knowledge of their trade-off is fragmentary. Combining a seismologically consistent model of earthquake-triggered landsliding and an analytical solution of coseismic surface displacement, we assess how the mass balance of single earthquakes and earthquake sequences depends on fault size and other geophysical parameters. We find that intermediate size earthquakes (M-w 6-7.3) may cause more erosion than uplift, controlled primarily by seismic source depth and landscape steepness, and less so by fault dip and rake. Such earthquakes can limit topographic growth, but our model indicates that both smaller and larger earthquakes (M-w < 6, M-w > 7.3) systematically cause mountain building. Earthquake sequences with a Gutenberg-Richter distribution have a greater tendency to lead to predominant erosion, than repeating earthquakes of the same magnitude, unless a fault can produce earthquakes with M-w > 8 or more.
Y1  - 2016
U6  - https://doi.org/10.1002/2016GL068333
SN  - 0094-8276
SN  - 1944-8007
VL  - 43
SP  - 3708
EP  - 3716
PB  - American Geophysical Union
CY  - Washington
ER  - 
TY  - JOUR
A1  - Illien, Luc
A1  - Sens-Schönfelder, Christoph
A1  - Andermann, Christoff
A1  - Marc, Odin
A1  - Cook, Kristen L.
A1  - Adhikari, Lok Bijaya
A1  - Hovius, Niels
T1  - Seismic velocity recovery in the subsurface
BT  - transient damage and groundwater drainage following the 2015 Gorkha Earthquake, Nepal
JF  - Journal of geophysical research : Solid earth
N2  - Shallow earthquakes frequently disturb the hydrological and mechanical state of the subsurface, with consequences for hazard and water management. Transient post-seismic hydrological behavior has been widely reported, suggesting that the recovery of material properties (relaxation) following ground shaking may impact groundwater fluctuations. However, the monitoring of seismic velocity variations associated with earthquake damage and hydrological variations are often done assuming that both effects are independent. In a field site prone to highly variable hydrological conditions, we disentangle the different forcing of the relative seismic velocity variations delta v retrieved from a small dense seismic array in Nepal in the aftermath of the 2015 M-w 7.8 Gorkha earthquake. We successfully model transient damage effects by introducing a universal relaxation function that contains a unique maximum relaxation timescale for the main shock and the aftershocks, independent of the ground shaking levels. Next, we remove the modeled velocity from the raw data and test whether the corresponding residuals agree with a background hydrological behavior we inferred from a previously calibrated groundwater model. The fitting of the delta v data with this model is improved when we introduce transient hydrological properties in the phase immediately following the main shock. This transient behavior, interpreted as an enhanced permeability in the shallow subsurface, lasts for similar to 6 months and is shorter than the damage relaxation (similar to 1 yr). Thus, we demonstrate the capability of seismic interferometry to deconvolve transient hydrological properties after earthquakes from non-linear mechanical recovery.
KW  - earthquake damage
KW  - earthquake hydrology
KW  - relaxation
KW  - Gorkha earthquake
KW  - seismic monitoring
KW  - ambient noise
Y1  - 2022
U6  - https://doi.org/10.1029/2021JB023402
SN  - 2169-9313
SN  - 2169-9356
VL  - 127
IS  - 2
PB  - American Geophysical Union
CY  - Washington
ER  - 
TY  - JOUR
A1  - Emberson, Robert
A1  - Galy, Albert
A1  - Hovius, Niels
T1  - Weathering of Reactive Mineral Phases in Landslides Acts as a Source of Carbon Dioxide in Mountain Belts
JF  - Journal of geophysical research : Earth surface
N2  - Bedrock landsliding in mountain belts can elevate overall chemical weathering rates through rapid dissolution of exhumed reactive mineral phases in transiently stored deposits. This link between a key process of erosion and the resultant weathering affects the sequestering of carbon dioxide through weathering of silicate minerals and broader links between erosion in active orogens and climate change. Here we address the effect on the carbon cycle of weathering induced by bedrock landsliding in Taiwan and the Western Southern Alps of New Zealand. Using solute chemistry data from samples of seepage from landslide deposits and river discharge from catchments with variable proportions of landsliding, we model the proportion of silicate and carbonate weathering and the balance of sulfuric and carbonic acids that act as weathering agents. We correct for secondary precipitation, geothermal, and cyclic input, to find a closer approximation of the weathering explicitly occurring within landslide deposits. We find highly variable proportions of sulfuric and carbonic acids driving weathering in landslides and stable hillslopes. Despite this variability, the predominance of rapid carbonate weathering within landslides and catchments where mass wasting is prevalent results at best in limited sequestration of carbon dioxide by this process of rapid erosion. In many cases where sulfuric acid is a key weathering agent, a net release of CO2 to the atmosphere occurs. This suggests that a causal link between erosion in mountain belts and climate change through the sequestration of CO2, if it exists, must operate through a process other than chemical weathering driven by landsliding. Plain Language Summary There is a long-standing debate surrounding the link between erosion and climate. It is often suggested that as temperatures increase, rainier and stormier weather could increase erosion of rock; as that rock is exposed, silicate minerals within could break down, which, on long time scales, can remove CO2 from the atmosphere, lowering global temperatures and acting as a negative feedback. Recent studies have shown that landslide deposits are key locations for the link between chemical weathering and physical erosion in some mountain belts. To test how landslides affect the erosion-climate link, we used samples of water seeping through landslides in Taiwan and New Zealand to calculate the amount of carbon dioxide that is either absorbed or released through this chemical reaction. We find that the large amount of freshly exposed rock in Taiwanese landslide deposits contains significant carbonate rock and sulfide minerals; the net result of the weathering of these minerals is a release of carbon dioxide, which inverts the traditional perspective on the role erosion plays in controlling carbon dioxide release. In some mountain belts, it seems that increased erosion and resulting landsliding may act to increase carbon dioxide in the air, opening further questions into the nature of erosional-climatic links.
KW  - chemical weathering
KW  - landslides
KW  - erosion-climate link
KW  - carbon dioxide
Y1  - 2018
U6  - https://doi.org/10.1029/2018JF004672
SN  - 2169-9003
SN  - 2169-9011
VL  - 123
IS  - 10
SP  - 2695
EP  - 2713
PB  - American Geophysical Union
CY  - Washington
ER  - 
TY  - JOUR
A1  - Struck, Martin
A1  - Andermann, Christoff
A1  - Hovius, Niels
A1  - Korup, Oliver
A1  - Turowski, Jens M.
A1  - Bista, Raj
A1  - Pandit, Hari P.
A1  - Dahal, Ranjan K.
T1  - Monsoonal hillslope processes determine grain size-specific suspended sediment fluxes in a trans-Himalayan river
JF  - Geophysical research letters
N2  - Sediments in rivers record the dynamics of erosion processes. While bulk sediment fluxes are easily and routinely obtained, sediment caliber remains underexplored when inferring erosion mechanisms. Yet sediment grain size distributions may be the key to discriminating their origin. We have studied grain size-specific suspended sediment fluxes in the Kali Gandaki, a major trans-Himalayan river. Two strategically located gauging stations enable tracing of sediment caliber on either side of the Himalayan orographic barrier. The data show that fine sediment input into the northern headwaters is persistent, while coarse sediment comes from the High Himalayas during the summer monsoon. A temporally matching landslide inventory similarly indicates the prominence of monsoon-driven hillslope mass wasting. Thus, mechanisms of sediment supply can leave strong traces in the fluvial caliber, which could project well beyond the mountain front and add to the variability of the sedimentary record of orogen erosion.
KW  - Himalayas
KW  - erosion
KW  - grain size
KW  - suspended sediments
KW  - landslide
KW  - river transport
Y1  - 2015
U6  - https://doi.org/10.1002/2015GL063360
SN  - 0094-8276
SN  - 1944-8007
VL  - 42
IS  - 7
SP  - 2302
EP  - 2308
PB  - American Geophysical Union
CY  - Washington
ER  - 
TY  - JOUR
A1  - Marc, Odin
A1  - Hovius, Niels
A1  - Meunier, Patrick
A1  - Uchida, Taro
A1  - Hayashi, Shin-Ichiro
T1  - Transient changes of landslide rates after earthquakes
JF  - Geology
N2  - Earthquakes impart an impressive force on epicentral landscapes, with immediate catastrophic hillslope response. However, their legacy on geomorphic process rates remains poorly constrained. We have determined the evolution of landslide rates in the epicentral areas of four intermediate to large earthquakes (M-w, 6.6-7.6). In each area, landsliding correlates with the cumulative precipitation during a given interval. Normalizing for this meteorological forcing, landslide rates have been found to peak after an earthquake and decay to background values in 1-4 yr, with the decay time scale probably proportional to the earthquake magnitude. The transient pulse of landsliding is not related to external forcing such as rainfall or aftershocks, and we tentatively attribute it to the reduction and subsequent recovery of ground strength. Observed geomorphic trends are not linked with groundwater level changes or root system damage, both of which could affect substrate strength. We propose that they are caused by reversible damage of rock mass and/or loosening of regolith. Qualitative accounts of ground cracking due to strong ground motion abound, and our observations are circumstantial evidence of its potential importance in setting landscape sensitivity to meteorological forcing after large earthquakes.
Y1  - 2015
U6  - https://doi.org/10.1130/G36961.1
SN  - 0091-7613
SN  - 1943-2682
VL  - 43
IS  - 10
SP  - 883
EP  - 886
PB  - American Institute of Physics
CY  - Boulder
ER  -