Geoconservation Research
Volcanism & Geoconservation
2023, Volume 6 / Issue 1 / pages(29-52)
Original Article
Károly Németh *,1,2,3,4, Mohammed Rashad Moufti 5, Ashor Mahmoud 1, Abdulrahman Sowaigh 1, Turki Hablil 1, Khalid Hassan 1, Turki Sehli 1
1Saudi Geological Survey, National Program of Earthquakes and Volcanoes, Jeddah, Saudi Arabia
2Institute of Earth Physics and Space Science, Sopron, Hungary
3Volcanic Risk Solutions, Massey University, Palmerston North New Zealand
4Istituto Nazionale di Geofisica e Vulcanologia, Bologna, Italy
5King Abdul-Aziz University, Jeddah, Kingdom of Saudi Arabia
Abstract
Four small scoria cones in the western outskirts of Al Madinah City, the Kingdom of Saudi Arabia, form a distinct young volcanic landmark. These volcanoes, despite their very small size, provide one of the most fundamental sources of information about the early eruption mechanism of rising mafic magma in the context of an active volcanic field located next to a city with over one million people. An initial study of the area in 2012–2013 confirmed that these sites had a significant phrea-
Károly Németh Saudi Geological Survey National Program of Earthquakes and Volcanoes Jeddah, Saudi Arabia
ORCID: 0000-0003-1026-0407
tomagmatic phase in their opening stage, leaving behind characteristic pyroclastic successions likely to be covered by subsequent eruptive products. The fact that in this location, unequivocal evidence emerged to show that explosive magma-water interaction driven eruptions occurred in the largely magmatic (“dry”) explosive style, and volcanic field evolution confirmed that this site has high geoheritage val- ue. Since the first research was 20 years ago, a restudy of the present-day condition of the scoria cone was conducted. Applying satellite imagery, remote sensing and direct site visit, we find that about a third of the cone surface area has been modi- fied and at least a quarter of its volume has vanished. Further excavation for cone material however opened the entire western side of the cone, exposing a nearly 5-m-thick succession of accidental lithic pyroclast-dominated lapilli tuff and tuff breccia, confirming that this location had a significant phreatomagmatic phase in its opening eruptions. This location shows graphically the need for geoconservation to preserve such sites that are potentially the only, or best locations to show the potential eruptive styles and scenarios of future eruptions if they occur in similar environments.
Keywords: Pyroclastic, Volcaniclastic, Volcanic geoheritage, Scoria, Degradation, Urban expansion, Hazard resilience
Article information |
Received: 2023-04-04 Accepted: 2023-05-24 First Publish Date: 2023-05-29 DOI: 10.30486/GCR.2023.1982893.1135 How to cite: Németh K, Moufti MR , Mahmoud A, Sowaigh A, Hablil T, Hassan K & Sehli T (2023). The vanishing volcanic geoheritage of a key scoria cone and its significance in volcanic hazard resilience of the active monogenetic volcanic field near Al Madinah, Kingdom of Saudi Arabia. Geoconservation Research. 6(1): 29-52. doi: 10.30486/ gcr.2023.1982893.1135 Geoconservation Research e-ISSN: 2588-7343 p-ISSN: 2645-4661 © Author(s) 2023, this article is published with open access at https://gcr.isfahan.iau.ir/ |
Volcanic geoheritage is an increasingly recog- nized value of abiotic nature (Németh et al. 2017a; Németh et al. 2017b; Sheth et al. 2017; Zangmo et al. 2017; Fepuleai & Németh 2019; Kil et al. 2019; Dóniz-Páez et al. 2020; Quesada-Roman et al. 2020). Volcanic geoheritage in many protected landscapes forms the core aspect of nature conser- vation, as well as having geotouristic and geoed- ucation values (Showstack 2015). Volcanism is a very attractive aspect of Earth processes, and fas- cinates visitors (Erfurt-Cooper 2011; Erfurt-Coo- per 2014). Volcanic rocks, even in old geological settings, function as a key aspect of storytelling about the evolution of abiotic nature as their for- mation is associated with processes that fit into the human timescale (Wang et al. 2014; Migon & Pijet-Migon 2016; Szepesi et al. 2017; Zacek et al. 2017). This is especially true of those eruptive rocks from small volcanic edifices, commonly de- fined as monogenetic volcanoes (Smith & Németh 2017), which provide a very human scale to the un- derstanding geological processes, and in active re- gions their formation can be experienced (Németh & Moufti 2013; Németh 2016 a,b; Németh 2017). With well-designed geoeducational programs that are linked to geotourism ventures, volcanic regions are one of the main attractions in terms of geolog- ical and geomorphological processes (Khoshraftar & Farsani 2019; Migon & Pijet-Migon 2019; Mo- lenda 2019; Raska et al. 2019; Beltran-Yanes et al. 2020; Bidias et al. 2020). Following this, many regions put significant energy into utilizing the “magic” of volcanism to get the society to engage with geology (Ozkaymak et al. 2017; Asrat 2018; Erfurt-Cooper 2018; Kaygili et al. 2018; Careddu & Grillo 2019; Galindo et al. 2019). Volcanic geo- heritage is a particularly powerful tool to develop resilience against volcanic disasters, hence an in- creasing number of geoeducational programs are looking for the link between geoheritage values and their potential usage for volcanic hazard re-
silience programs (Petrosino et al. 2019; Guilbaud et al. 2020; Fepuleai et al. 2021; Guilbaud et al. 2021).
While such works normally focus on polygenetic, long-lived stratovolcanoes, where repeated and re- current volcanic eruptions occur from a vent that is relatively stable in its position in human time scales, recently the same approach has been taken in dispersed volcanic regions, or volcanic fields. Volcanic fields are commonly defined as a group of volcanoes that erupted over a relatively short period of time in geological terms, forming small volcanic landforms with very distinct time frame when they formed (Smith & Németh 2017). In active volcanic fields, where Holocene or Pleis- tocene volcanoes formed, volcanic geoheritage is crucial in transmitting volcanic hazard resilience messages, as while the field is active, actual ac- tivity can be absent over many generations, such as in the Auckland Volcanic Field in New Zealand where the last eruption occurred about 600 years ago (Hopkins et al. 2021). This concept is nor- mally difficult to convey to the population in the absence of direct experiences of volcanic erup- tions. But once a new vent opens, within days to years new volcanic geosites may develop often with dramatically different consequences or haz- ards. This scenario is even more pronounced in areas where very small volumes of melt rising can interact with ground and surface waters, and small volume of magma rise can generate impactful ex- plosive events considered to be high and unpre- dictable hazards (Kereszturi et al. 2014).
Most of the volcanic fields in the Arabian Penin- sula show such characteristics. Just south of Al Madinah City (Fig. 1), the Harrat Rahat is a mono- genetic volcanic field where explosive magma and water interaction driven eruptions are known from the Pleistocene, commonly associated with more evolved magmas like trachyte (Moufti & Németh 2013). The latest eruption of the volcanic field
formed a chain of scoria cones along a 2.3 km long fissure that emitted lava flows over 12 km in length well within the current city limit of Al Ma- dinah (Camp et al. 1991). About 500 monogenetic volcanoes of this volcanic field formed, and they are overwhelmingly scoria cones, that are mild to moderately explosive in their activity, probably grown over days to years, but there is little evi- dence that they had intermittent phreatomagmatic (magma and water interaction driven) explosive phases during their eruptions (Downs et al. 2018). This was a paradoxical situation especially around Al Madinah City, in a low-lying region with sus- pected good shallow subsurface water sources. Until 2012–2013 there was no evidence known for explosive magma-water interaction driven erup- tions in this region. In 2012-13 however, some ac- cidentally opened communal scoria pits identified some locations where very thin 1–2 m basal tephra was exposed that were clearly phreatomagmatic in origin (Murcia et al. 2015). As an immediate re-
sponse to these findings, proposals were prepared and published to highlight the key geoheritage el- ements of the young volcanism around Al Madi- nah, particularly pointing out the significance of four cones named as Al-Du’aythah volcanic cones just on the western edge of the Al Madinah urban areas (Moufti et al. 2013). The same cones due to their young morphology were also provisionally suggested to be a “legendary” source event of vol- canic eruptions mentioned in some historic oral traditions, hence referred to as the AD 641 cones (Moufti et al. 2013). Recent geological mapping, however, provided radiometric dates that were much older, around 14 ka (Downs et al. 2018). These four cones are in interesting locations in re- lation to the growing Al Madinah urban area (Fig. 1). They are along a Neoproterozoic horst that fol- lows a NW-SE trend (Figs. 2, 3).
A magnetotelluric survey conducted in 2012-13 also confirmed fluid, inferred to be water (water
saturated sediments) about 300–400 m below the surface beneath these cones, further confirming the potential that phreatomagmatic activity like- ly took place at least in the initial phase of three of these scoria cones (Murcia et al. 2015). This revealed typical evidence of phreatomagmatism in the exposed thin lapilli tuff, and tuff breccia (Fig. 4). Here we report additional evidence to support this idea from new exposures with more
than a 5 m thick pyroclastic succession (Fig. 5). The new exposures are the result of some local community quarrying of construction material, rubbish pit opening and some expansion of failed development of some orchards nearby. This new finding highlights the urgent need to prevent further degradation of this location as they hold crucial information on understanding the eruption scenarios uture eruptions in the region may follow.
We conducted site visits in 2023 to check visually the status of the location. This visit was part of a field campaign of the Saudi Geological Survey to collect direct field observation data to better characterize the potential eruption scenarios in the greater Al Madinah region. During this field visit, direct photo documentation of the status of the sites was completed. As the last detailed study dates to 2012-13, a complete satellite imagery study was performed by applying Google Earth Pro satellite
imagery through the available historic data sets. The data sets go back to 2004, providing an excel- lent array of spatial information to trace landform changes over a nearly 20-year period (2004– 2023). This is valuable information, as ten years ago such diverse image data sets were not accessi- ble, and the resolution of the available images was unsuitable for the detail of observations needed. In addition, a basic survey was conducted through available Sentinel satellite imagery. This data set has a useful image library since 2017, hence only
the last six years of land use changes can be deter- mined. The highest resolution of these images is 9 m, so they cannot be used to identify great detail of the cones, but they are sufficient to see the con- text of the location of these cones within the basin of Al Madinah. We used three types of satellite images: moisture index map (sensitive for wa- ter-rich substances or surfaces); short wavelength infrared imagery (SWIR; sensitive to vegetation and water availability in the near surface regions); and false color (urban) images normally used to locate vegetation and urbanization. For spatial information, ALOS -PALSAR Terrain Corrected digital elevation models were obtained that pro- vided 12.5 m resolution elevation data. This data was not useful directly to trace the small volca- nic cone morphological changes. It was instead used to characterize the morphology of the greater Al Madinah Basin. On these elevation maps, key man-made features such as highways, buildings, mosques, and orchards were also shown, extracted from spatial data available from the Open Street Map services. Direct field observations were also accompanied by basic macroscopic documenta- tion of the exposed volcanic lithologies.
The greater Al Madinah Basin is a lowland just north of the Harrat Rahat volcanic field. The basin itself has functioned as an oasis since its early set- tlement and provides an agricultural base for the growing population. Al Madinah became an im- portant center for agriculture for growing dates, market vegetables and herbs such as the famous mint (Sayed & Masrahi 2023). All this indicates that the region had access to water from dug wells and surface water for centuries. Groundwater is abundant beneath the surface but highly saline and nitrate-rich around the established standards for ir- rigation and drinking (Al-Harbi et al. 2006; Bob et
al. 2016). Most of the ground water is suitable for irrigation of salt-resistant crops (El Maghraby et al. 2013). The aquifers are recharged through rain- water filtration over century long cycles (Al-Harbi et al. 2006). In modern times drilled wells reach- ing depths of 200-300 m lift water at temperatures ranging between 35 and 50 °C (Fig. 6).
Higher water temperature water wells are located just north of the city, mostly for community use or market gardening and perhaps associated with some relatively weak geothermal processes. Water is channeled across the entire volcanic field and exists in various wells within or in the marginal regions of the fields like in the SE (Fig. 7).
All these observations and current uses for the re- gion indicate that relatively shallow ground water sources are abundant in the region. This original- ly suggested that geologists look for evidence of magma and water interaction in the region where a large number of Pleistocene to Holocene vol-
canoes formed. Sentinel satellite imagery of the greater Al Madinah region in the January to March 2023 period was studied, when the region expe- rienced an unusually wet season. The elevated moisture is clearly visible (Figs. 8– 10).
Figure 8. Sentinel SWIR Satellite Image of the greater Al Madinah region. Note the young lava flows, the green regions where vegetation flourish, and the large temporal lake marked by dark blue. The image was taken on 27 March 2023.
Figure 9. Sentinel False (Urban) satellite image showing the urban expansion of Al Madinah City well. The image was taken on 27 March 2023.
After finding new exposures during the 2023 field campaign, we explored land degradation of
the Al-Du’aythah volcanic cones. Following the available satellite data sets of the Google Earth Pro service, we selected the best possible images by
visual inspection. Each image was georeferenced and incorporated in a GIS database within Q-GIS for comparison of the geometrical changes (e.g., surface area and cliff positions) between 2004 and 2023. We intended to select images that were tak- en in wintertime where the contrast is high due to moisture content. The earliest available image date back to November 2004 when the cone shows clear and intact morphological elements (Fig. 11). The eastern edge and limit of the cone still show nearly the original extent and mark a steep eastern slope with some original erosional ravines.
The central part of the cone is still in its prima- ry morphological appearance, marking a “soft- er” surface area in the west, that is distinct from a south-easterly crater zone with steep features and a complex lava dome at its northern edge. In this image, it is also evident that the cone itself
has a complex crater morphology suggesting an actual eruptive vent shift in a very short period. It is also indicating that the western, smooth- er cone was somehow overgrown by the eastern cone complex. Further from the cone toward the NW it is obvious that a layer of dark ash covers the otherwise smooth morphology, all indicating some sort of magma fragmentation style change in the growth of the volcano from a more explosive (hence fine-grained ash producing) phase to more regular scoria fall producing eruptions. The cone already suffered some quarrying on its SW side in the 2004 image, but the excavation was likely for local community need rather than large-scale landscape modifying quarrying. These condi- tions were relatively stable until May 2009, when the scoria pit became more obvious and deeper, with some local road construction initiated on the southern margin of the cone (Fig. 12).
Figure 12. May 2009
By May 2012, a two-lane asphalt road construc- tion started in the western side of the cone while by August 2013 (Fig. 13) new housing develop-
ment created a line of houses in the immediate vi- cinity of the cone on the eastern side. This is the scenario when first-time evidence of a basal tuff
ring was found in thin beds at the eastern side of the cone. During, this time the northern side of the cone became a communal and likely uncontrolled rubbish pit (Fig. 13).
By January 2015, land development started along the NW side of the cone with some landscaping and cut back of the cone (Fig. 14) with signifi-
cant modification of the cone by October 2016. This stage was accompanied by rubbish dumping and some orchards in the entire western sector of the cone (Fig. 15). By December 2018, the entire western sector of the cone suffered significant landscaping and cut back as well as developing a date orchard and some organized rubbish pits providing clean cliff surfaces suspected to have excellent outcrops (Fig. 16). By August 2020, a new clearance removed the former rubbish pit but made the cone cut back about 10-15 m, and losing its entire distal section (Fig. 17). This time, despite the significant alteration of the original landform, a functioning orchard guaranteed the relatively tidy appearance of this side of the cone, potentially offering excellent outcrops. About a year later, this situation had changed by removal of the orchard,
some clearance and landscaping, apparently an attempt at tourism and geoconservation develop- ment (Fig. 18). This situation remained more or less the condition of the cone up to 2023 (Fig. 19). Today, some clearance is apparent, but also, as the land is open to the public, local rubbish dump- ing has started as well as the gradual collection of communal use of scoria. By now the eastern side of the cone has also been cut back a further 5–10 m, forming a characteristic cliff side deeply cut into the core of the cone and losing its origi- nal morphology. Similarly, an articulated circular zone has been developed on the western edge that has left only the core of the former tuff ring. In the crater zone digging activity made the cone’s orig- inal crater morphology hard to recognize, leav- ing behind few segments that can be recognized
probably only by trained experts. Interestingly, the cone’s northern side where a small lava dome and some short lava flow poured out remained intact,
probably due to its hard nature which made it dif- ficult to blast it off. The cone now has its heavily modified core complex only.
Figure 18. July 2021
suggest explosive phreatomagmatic eruptions to be responsible for their formation. Such coarse grained breccias were suspected but not known in 2012–13 and have not been reported yet from this location, or anywhere else in the Harrat Rahat volcanic field. These breccias are best interpreted as proximal pyroclasts of a tuff ring or small maar volcano. These tuff breccias are also grade into an accidental lithic dominated lapilli tuff toward the west (Fig. 22) and show repeated fine–coarse alternation of pyroclastic beds indicating the pul- sating nature of explosive phases. The tuff layers showing plastering and presence of accretionary lapilli attest to their phreatomagmatic origin (Fig. 22). The new exposures in the west cut directly into the crest of a former tuff ring where the basal phreatomagmatic pyroclastic succession reach- es nearly 10 m in thickness (Fig. 23), which is gradually draped over by typical black scoria and lapilli erupted from the easterly vents of the cone complex. These outcrops are new. Now the new outcrops form a coherent array of deposits that show vital information to support explosive phre- atomagmatism as a key eruption scenario which needs to be incorporated into volcanic hazard esti- mates of the greater Al Madinah region.
It is evident that the volcanic cone suffered a dra- matic anthropogenic alteration in the last 20 years.
Tracing the original cone outlines using histor- ic satellite images is useful to follow the spatial changes (Fig. 24). Following the outline of cone changes it is evident that about a third of the sur- face area of the original cone has been removed within 20 years (Fig. 24). This means that the distal deposits of the cone are gone forever and that the integrity of the landform is compromised. As integrity forms a very fundamental aspect of geoheritage valorization, such loss normally trans- lates to the loss of geoheritage value (Newsome & Johnson 2013; White & Wakelin-King 2014; Tav- ares et al. 2015; Zangmo et al. 2015; Pena et al. 2017; Cetiner et al. 2018; Koroglu & Kandemir 2019; Rodrigues Ferreira et al. 2019; Yaseen et al. 2019; Yoon 2019; Bidias et al. 2020; Mikhailen- ko et al. 2020; Pourfaraj et al. 2020; Vereb et al. 2020).
If we look at the original central crater morphol- ogy, we can see clearly that the cone’s original
crater rim has been modified so much that it is hard to recognize its original shape (Fig. 24). It is also important to note that there are some “gains” along the margins depending on the actual excava- tion status of the cone. Steep cliffs can be eroded after rainfall, and the material washed away is cre- ating ash covered fans along the newly excavated but subsequently abandoned cliff faces. This is an issue, as while now the cliff faces expose very in- teresting sections vital to understand the eruptive mechanism of the cone, but if such cliff faces are not stabilized or maintained, they can erode away rather quickly leaving behind a debris fan-covered face where the original texture and bedding can no longer be seen.
The Al-Du’aythah volcanic cones, and their stud- ied central northern cone complex provide clear evidence for the debate about geoconservation of small volcanic cones like scoria cones, their nat- ural resource values and geoheritage. It has long been discussed how we approach human-modified sites, including active and abandoned quarries. On the one hand, quarrying and removal of sectors of the cones destroys the original landform, while on the other hand due to the excavation, the visitor can access sites that are vital to understand the geolog- ical processes responsible for the formation of the geoform itself (Németh et al. 2021; Nieto-Torres et al. 2022; Rito et al. 2022). Natural resource ex- traction through quarrying of high-quality scoria is tempting as the product is useful for construction (Moufti et al. 2000; Sabtan & Shehata 2000; Her- rera-Franco et al. 2022). However, such values conflict within an ecosystem/geosystem services concept (Bobylev et al. 2022). Abandoned quarry sites also attract ad hoc communal excavation and rubbish damping reducing the integrity and the aesthetic value of a geosite (Németh et al. 2021; Tessema et al. 2021; Krieger 2023). Such fragile geosystems also need attention after their protec- tion level is raised as visitation can damage their integrity as well (Santos et al. 2017; AbdelMak-
soud et al. 2018; Kong et al. 2020; He et al. 2023). Effective geotrails, even across abandoned quarry sites, can carry significant value for geoeducation (Guilbaud et al. 2021; Németh et al. 2021; Sallam et al. 2022; Singtuen & Anumart 2022; Alberico et al. 2023).
The Al-Du’aythah volcanic cones demonstrate this dilemma perfectly. Research carried out ten years ago predicted the potentially fundamental role of explosive phreatomagmatism during the initial phase of producing scoria cones in areas where ground water was expected such as in the great- er Al Madinah basin. This notion was supported by a thin veneer of phreatomagmatic tephra. Ten years ago, information that was highly speculative has now become definitive from the exposed thick sequence of such deposits. This means that, while the destruction of the original landform was sig- nificant, it led to a dramatic loss of its geoheritage value from a landform integrity and aesthetic point of view, however, the new exposures provide sig- nificant added value to the scientific understand- ing of the formation of this volcano.
This information is transferable to other locations and therefore has significant scientific value. If we accept the general trend to express and define abiotic features as geoheritage, it should be based on the scientific value, and the human intervention (regardless of whether it is intentional, or uninten- tional) that provides a strong increase in geoheri- tage values. This clearly is a paradoxical question. Similar concerns have been raised recently in many locations where extensive quarrying of basalt (and andesite) from monogenetic volcanoes for con- struction removed most of the cones, leaving be- hind only the core of the volcanoes such as in the Chaîne des Puys World Heritage site (Németh et al. 2021). Especially in Europe such quarries are abundant and most of them provide essential sci- entific information to our current understanding of how monogenetic volcanoes work (Németh et al.
2021). Such exposed interior parts of the cones in- clude interaction features between lava lakes and tephra rings, diatreme breccias or collapsed cone sectors within crater infilling deposits help to ad- vance our scientific knowledge of eruption mech- anisms. Such information would never have been accessible, as naturally occurring buttes are rare and if they exist, the associated debris fans com- monly cover key exposures. So, such quarry sites have significant scientific values, but the artificial modification of the original landscape can clearly cause massive scars on the natural landscape.
Many large monogenetic volcanoes such as those in Spain, France, Hungary, or Germany, provide locations where a proper geoconservation strategy can create a fantastic learning environment, which commonly forms the core of the geotourism pro- grams. For instance, one of the headquarter sites of the Bakony-Balaton UNESCO Global Geopark in Hungary is in Hegyestű, a former abandoned quarry with super columnar jointed basalt out- crops exposed during the active quarrying (Pál & Albert 2021a, b; van Wyk de Vries et al. 2022). Similarly, Vulcanica (https://www.vulcania.com/ en/), a major European geotourism center within the “Chaîne des Puys - Limagne fault tectonic are- na” UNESCO World Heritage site offers one of the most spectacular experiences to see into the core of a monogenetic volcano (van Wyk de Vries 2013; van Wyk de Vries et al. 2014; Delcamp et al. 2014). In that location, the original volcanic geoform is hardly recognizable. Adopting this vi- sion, the Al-Du’aythah volcanic cones should be treated similarly.On the one hand, what has been removed cannot be returned. There are some no- tions to restore original geoforms such as maar craters in the Eifel region in Germany (Koziol & Feelsberger-Ruuti 2011) and from South Korea’s Jeju Island (Shik et al. 2014), but to do that is more a bioconservation and landscape issue than a geo- logical restoration. As the Harrat Al Madinah has abundant scoria cones, a visitor can be directed to
landforms where original geoforms are still pres- ent such as the 1256 CE historic eruption site just about 15 km to the east of Madinah, while at Al- Du’aythah, the current state of the cone must be utilized for geoeducation and geotourism. As the Al-Du’aythah volcanic cones are the only location where we can look inside a monogenetic volcano of the region of Harrat Rahat at a scale that al- lows us to see how the eruptive products record the interface between wet to dry explosive phases, this location carries a high scientific value in the regional context. Moreover, the Al-Du’aythah volcanic cones also provide a globally signifi- cant aspect of monogenetic volcanism, namely the volume issue. If very low magma volume is involved in an eruption, it is likely that it will be very sensitive to local environmental effects such as the presence of ground and/or surface water. In the case of phreatomagmatic explosive eruptions, the impact or the so-called volcanic footprint of the eruptions will be much larger than if the same volume of magma just erupted in a “dry” manner, a conceptual model considered recently (Németh et al. 2012). Therefore, the Al-Du’aythah volcanic cones carry a vital aspect of volcanic hazard edu- cation, and the site should be treated as a flagship location to scale our understanding of this type of volcanism and its geohazards.
In this short report we provided a report of our recent revisit to a key geological site in the west- ern region of the urban area of Al Madinah City. This location was the first site in the Harrat Rahat volcanic field where clear evidence been identi- fied in the geological record to demonstrate that in the early stage of the basaltic eruptions explosive phreatomagmatism was a key and violent process. The first paper (Murcia et al. 2015) on this sub- ject rightfully recorded and communicated this finding but remained rather conservative about the extent of the interpretation as the exposed and preserved deposit was thin and had been recov-
ered only from sporadic and not interconnected outcrops. Ten years after this report and its recom- mendations to keep an eye on the geoconservation strategy of the Al-Du’aythah volcanic cones, a re- visit was concluded in 2023. The revisit located great thicknesses of well exposed and very char- acteristic deposits interpreted to be of explosive phreatomagmatic origin. As a follow up, checking the accessible historical satellite imagery through Google Earth Pro provided data of nearly 20-year period since 2004, showing the loss of the sur- face area of the original cone, but also the newly emerged exposures hosting unique and superb out- crops confirming the original inference on the role of phreatomagmatism. Our work here also demon- strated that phreatomagmatism might have been far more widespread in the region, but in places where substantial magma was available during the eruption, the original tuff rings were likely cov- ered completely, and the phreatomagmatic pyro- clastic successions have never been exposed; not as at the Al-Du’aythah volcanic cones. In this re- spect, despite the dramatic human modification of the original volcanic geoform, the exposures pro- vide fundamental values to define this location as a key geosite with high geoheritage value.
However, to manage all the concepts outlined above, there an effective geoconservation strate- gy is required. Geoconservation is the key to the fate and the future of the Al-Du’aythah volcanic cones. The original volcanic geoform has reached a metastable state when slight changes of land use (like new communal rubbish dumping or local ex- cavation of raw materials) can damage the newly exposed geosites to a level at which the geoheri- tage value has been lowered to a minimum. This is when an effective geoconservation strategy should be co-developed between research organizations, councils, and local communities. This work also highlights the role and purpose of geoconserva- tion. Also, without geoconservation research, this transdisciplinary research cannot be conducted
effectively and the geoheritage value would dete- riorate quickly.
As one of the Authors, Karoly Nemeth is mem- ber of the Editorial Board of Geoconservation Research, here it is declared that he has not been involved in any level of the review and editorial processes.
Logistical support by the Saudi Geological Sur- vey is highly appreciated to conduct site visits. Two anonymous reviewers’ comments, the Edi- tor-in-Chief’s (Prof. Mike Benton) and the Tech- nical Editor’s (Ms. Mahshid Pezeshki) sugges- tions helped to clarify our work.
AbdelMaksoud KM, Al-Metwaly WM, Ruban DA & Yashalova NN (2018). Geological heritage under strong urbanization pressure: El-Mokat- tam and Abu Roash as examples from Cai- ro, Egypt. Journal of African Earth Sciences. 141: 86-93. https://doi.org/10.1016/j.jafrears- ci.2018.02.008
Al-Harbi OA, Hussain G, Khan MM, Moallim MA & Al-Sagaby IA (2006). Evaluation of ground- water quality and its recharge by isotopes and solute chemistry in Wadi Malal, Al-Madinah Al-Munawarah, Saudi Arabia. Pakistan Jour- nal of Biological Sciences. 9(2): 260-269. DOI: 10.3923/pjbs.2006.260.269
Alberico I, Alessio G, Fagnano M & Petrosi- no P (2023). The effectiveness of geotrails to support sustainable development in the Cam- pi Flegrei active volcanic area. Geoheritage. 15(1): 15. https://doi.org/10.1007/s12371-022-
00778-6
Asrat A (2018). Chapter 19 - Potential geoheritage sites in Ethiopia: challenges of their promo- tion and conservation. In Reynard E & Brilha J
(eds) Geoheritage (pp 339-353). Elsevier.
Beltran-Yanes E, Doniz-Paez J & Esquivel-Sigut I (2020). Chinyero Volcanic Landscape Trail (Canary Islands, Spain): a geotourism proposal to identify natural and cultural heritage in vol- canic areas. Geosciences. 10(11): 453.https:// doi.org/10.3390/geosciences10110453
Bidias LAZA, Ilouga DCI, Moundi A & Nsan- gou A (2020). Inventory and assessment of the Mbepit Massif geomorphosites (Camer- oon Volcanic Line): assets for the development of local geotourism. Geoheritage. 12(2): 49. https://doi.org/10.1007/s12371-020-00471-6
Bob M, Abd Rahman N, Elamin A & Taher S (2016). Assessment of groundwater suitability for irrigation in Madinah City, Saudi Arabia. Arabian Journal of Geosciences 9(1):1-11. https://doi.org/10.1007/s12517-015-2024-z
Bobylev N, Syrbe RU & Wende W (2022). Geo- system services in urban planning. Sustainable Cities and Society. 85: 104041. https://doi. org/10.1016/j.scs.2022.104041
Camp VE, Roobol MJ & Hooper PR (1991). The Arabian Continental Alkali Basalt Province
2. evolution of Harrats Khaybar, Ithnayn, and Kura, Kingdom of Saudi-Arabia. Geological Society of America Bulletin. 103(3):363-391. https://doi.org/10.1130/0016-7606(1991)103< 0363:TACABP>2.3.CO;2
Careddu N & Grillo SM (2019). “Trachytes” from Sardinia: geoheritage and current use. Sustain- ability (MDPI - Switzerland) 11(13). https:// doi.org/10.3390/su11133706
Cetiner ZS, Ertekin C & Yigitbas E (2018). Evalu- ating scientific value of geodiversity for natural protected sites: the Biga Peninsula, Northwest- ern Turkey. Geoheritage. 10(1):49-65. https:// doi.org/10.1007/s12371-017-0218-3
Delcamp A, van Wyk de Vries B, Stephane P & Kervyn M (2014). Endogenous and exoge- nous growth of the monogenetic Lemptegy
volcano, Chaine des Puys, France. Geosphere. 10(5):998-1019.https://doi.org/10.1130/ GES01007.1
Dóniz-Páez J, Beltrán-Yanes E, Becerra-Ramírez R, Pérez NM, Hernández PA & Hernández W (2020). Diversity of volcanic geoheritage in the Canary Islands, Spain. Geosciences 10:390. https://doi.org/10.3390/geosciences10100390
Downs DT, Stelten ME, Champion DE, Dietterich HR, Nawab Z, Zahran H, Hassan K & Shawali J (2018). Volcanic history of the northernmost part of the Harrat Rahat volcanic field, Saudi Arabia. Geosphere. 14(3): 1253-1282. https:// doi.org/10.1130/GES01625.1
El Maghraby MMS, El Nasr AKOA & Hamouda MSA (2013). Quality assessment of groundwa- ter at south Al Madinah Al Munawarah area, Saudi Arabia. Environmental Earth Scienc- es. 70(4):1525-1538. https://doi.org/10.1007/ s12665-013-2239-9
Erfurt-Cooper P (2011). Geotourism in volcanic and geothermal environments: playing with fire? Geoheritage 3(3):187-193. https://doi. org/10.1007/s12371-010-0025-6
Erfurt-Cooper P (2014). Volcanic tourist destina- tions. In: Eder W, Bobrowsky PT & Martínez- Frías J (eds) Geoheritage, Geoparks and Geotourism. Springer, Heidelberg. https://doi. org/10.1007/978-3-642-16191-9
Erfurt-Cooper P (2018). Chapter 11: Geotourism development and management in volcanic regions. In Dowling R & Newsome D (eds) Handbook of Geotourism (pp. 152-167)Ed- ward Elgar Publishing, Cheltenham Glos, UK. https://doi.org/10.4337/9781785368868.00021
Fepuleai A & Németh K (2019). Geoheritage 11: 577-596 . https://doi.org/10.1007/s12371-018-
0306-z
Fepuleai A, Németh K & Muliaina T (2021). Geopark impact for the resilience of commu-
nities in Samoa, SW Pacific. Geoheritage. 13(3): 50. https://doi.org/10.1007/s12371-021-
00578-4
Galindo I, Romero C, Llorente M, Rubio JC, Díaz GA, Sánchez N, Martín-González E, Mangas J & Vegas J (2019). Geoheritage in the shal- low submarine slopes of an oceanic volca- nic edifice: a new option for diving geotour- ism. In Mateo E, Martínez-Frías J & Vegas J (eds) Lanzarote and Chinijo Islands Geopark: From Earth to Space (pp 85-98). Springer International Publishing, Cham. https://doi. org/10.1007/978-3-030-13130-2_6
Guilbaud MN, Ortega-Larrocea MP, Cram S & van Wyk de Vries B (2021). Xitle Volcano geoheritage, Mexico City: raising awareness of natural hazards and environmental sustain- ability in active volcanic areas. Geoheritage 13(1): 6. https://doi.org/10.1007/s12371-020-
00525-9
Guilbaud MN, van Wyk de Vries B, Németh K, Veréb V, Hagos M, Manrique N, Fermet-Quinet N, Irapta N, Vargas SV, Cortés GP, Navarro M & Leven CL (2020). UNESCO IGCP PROJ-
ECT 692. Geoheritage for geohazard resil- ience: a global initiative to share knowledge, raise awareness and communicate about nat- ural hazards. In Oxford Geoheritage Virtual Conference. Oxford (pp 67-68).
He H, Shen L, Wong SW, Cheng G & Shu T (2023). A “load-carrier” perspective approach for assessing tourism resource carrying capac- ity. Tourism Management. 94: 104651. https:// doi.org/10.1016/j.tourman.2022.104651
Herrera-Franco G, Apolo-Masache B, Escan- dón-Panchana P, Jácome-Francis K, Moran- te-Carballo F, Mata-Perelló J & Carrión-Mero P (2022). Perception of the geological-mining heritage to promote geotourism in Guayaquil, Ecuador. Geosciences. 12(9): 322. https://doi. org/10.3390/geosciences12090322
Hopkins JL, Smid ER, Eccles JD, Hayes JL, Hay- ward BW, McGee LE, van Wijk K, Wilson TM, Cronin SJ, Leonard GS, Lindsay JM, Németh K & Smith IEM (2021). Auckland Volcanic Field magmatism, volcanism, and hazard: a review. New Zealand Journal of Geology and Geophysics. 64(2-3):213-234. https://doi.org/1 0.1080/00288306.2020.1736102
Kaygili S, Sinanoglu D, Aksoy E & Sasmaz A (2018). Geotourism: some examples from Tur- key. Dnipropetrovsk University Bulletin Se- ries-Geology Geography. 26(1):79-87. https:// doi.org/10.15421/111809
Kereszturi G, Németh K, Cronin SJ, Procter J & Agustin-Flores J (2014). Influences on the variability of eruption sequences and style transitions in the Auckland Volcanic Field, New Zealand. Journal of Volcanology and Geothermal Research. 286:101-115. https:// doi.org/10.1016/j.jvolgeores.2014.09.002
Khoshraftar R & Farsani NT (2019). Geomytholo- gy: an approach for attracting geotourists (case study: Takht-e Soleyman - Takab World Her- itage Sites). Geoheritage. 11(4):1879-1888. https://doi.org/10.1007/s12371-019-00399-6
Kil Y, Ahn KS, Woo KS, Lee KC, Jwa Y-J, Jung W & Sohn YK (2019). Geoheritage values of the Quaternary Hantangang River Volcanic Field in the Central Korean Peninsula. Geoher- itage. 11(3):765-782. https://doi.org/10.1007/ s12371-018-0329-5
Kong W, Li Y, Li K, Chen M, Peng Y, Wang D & Chen L (2020). Urban geoheritage sites un- der strong anthropogenic pressure: example from the Chaohu Lake Region, Hefei, China. Geoheritage 12(3): 77. https://doi.org/10.1007/ s12371-020-00490-3
Koroglu F & Kandemir R (2019). Vulnerable geo- sites of Çayırbağı-Çalköy (Düzköy-Trabzon) in the Eastern Black Sea Region of NE Tur- key and their geotourism potential. Geoheri- tage. 11(3):1101-1111. https://doi.org/10.1007/
s12371-019-00358-1
Koziol M & Feelsberger-Ruuti S (2011). Six steps to restore a dry maar successfully. 4th Interna- tional Symposium on Restoration of Hanon Maar, Seogwipo, Jeju.
Krieger P (2023). Preserving geodiversity in Mex- ican hyper urban conflict zones: A geo-aes- thetic approach. International Journal of Geo- heritage and Parks. 11(1):64-81. https://doi. org/10.1016/j.ijgeop.2022.08.010
Migon P & Pijet-Migon E (2016). Overlooked geomorphological component of volcanic geo- heritage-diversity and perspectives for tourism industry, Pogrze Kaczawskie Region, SW Po- land. Geoheritage 8(4):333-350. https://doi. org/10.1007/s12371-015-0166-8
Migon P & Pijet-Migon E (2019). Natural di- sasters, geotourism, and geo-interpretation. Geoheritage. 11(2):629-640. https://doi. org/10.1007/s12371-018-0316-x
Mikhailenko AV, Ruban DA, Zorina SO, Nikashin KI & Yashalova NN (2020). The human im- print on the unique geological landscape of the Western Caucasus. Geologos. 26(3):233-244. https://doi.org/10.2478/logos-2020-0022
Molenda T (2019). Geotourism attractions of Georgia (on the example of selected objects from karst and volcanic areas). Acta Geo- graphica Silesiana. (34):95-110. http://www. ags.wnoz.us.edu.pl/download
Moufti MR & Németh K (2013). The intra-con- tinental Harrat Al Madinah Volcanic Field, Western Saudi Arabia: a proposal to establish Harrat Al Madinah as the first volcanic geopark in the Kingdom of Saudi Arabia. Geoheritage. 5(3):185-206. https://doi.org/10.1007/s12371-
013-0081-9
Moufti MR, Németh K, Murcia H, Al-Gorrry SF & Shawali J (2013). Scientific basis of the geoheritage and geotouristic values of the 641 AD Al Madinah eruption site in the Al Madi-
nah Volcanic Field, Kingdom of Saudi Arabia. The Open Geology Journal. 7:31-44. DOI: 10.2174/1874262920130702001
Moufti MR, Sabtan AA, El-Mahdy OR & She- hata WM (2000). Assessment of the indus- trial utilization of scoria materials in central Harrat Rahat, Saudi Arabia. Engineering Geol- ogy.57(3-4):155-162.https://doi.org/10.1016/ S0013-7952(00)00024-7
Murcia H, Németh K, El-Masry NN, Lindsay JM, Moufti MRH, Wameyo P, Cronin SJ, Smith IEM & Kereszturi G (2015). The Al-Du’aythah volcanic cones, Al-Madinah City: implications for volcanic hazards in northern Harrat Rahat, Kingdom of Saudi Arabia. Bulletin of Vol- canology 77(6): 54. https://doi.org/10.1007/ s00445-015-0936-9
Németh K (2016a). Geoheritage values of mono- genetic volcanic fields: a potential UNESCO World Heritage Site in the Arabian Peninsula. 6th International Maar Conference (pp. 67-68). inTech Open Publisher, Changchun, China - Rijeka, Croatia.
Németh K (2016 b). Volcanic geoheritage values of monogenetic volcanic fields in the global scale and from New Zealand perspective. Geo- science Society of New Zealand Miscellaneous Publication 145A: 59.
Németh K (2017). Pedagogical and indigenous aspects of geoeducation with special reference to the volcanic geoheritage of monogenetic volcanoes. IAVCEI 2017 Scientific Assembly. Portland, Oregon.
Németh K, Wu J, Sun C & Liu J (2017a). Update on the volcanic geoheritage values of the Plio- cene to Quaternary Arxan-Chaihe Volcanic Field, Inner Mongolia, China. Geoheritage. 9(3):279-297. https://doi.org/10.1007/s12371-
017-0224-5
Németh K, Casadevall T, Moufti MR & Marti J (2017b). Volcanic Geoheritage. Geoheritage.
9(3):251-254. https://doi.org/10.1007/s12371-
017-0257-9
Németh K, Cronin SJ, Smith IEM & Flores JA (2012). Amplified hazard of small-volume monogenetic eruptions due to environmen- tal controls, Orakei Basin, Auckland Volcanic Field, New Zealand. Bulletin of Volcanolo- gy. 74(9):2121-2137. https://doi.org/10.1007/ s00445-012-0653-6
Németh K, Gravis I & Németh B (2021). Dilem- ma of geoconservation of monogenetic vol- canic sites under fast urbanization and infra- structure developments with special relevance to the Auckland Volcanic Field, New Zea- land. Sustainability. 13(12): 6549. https://doi. org/10.3390/su13126549
Németh K & Moufti R (2013). Monogenetic volca- nic fields and their geoheritage values of west- ern Saudi Arabia and their implication to holis- tic geoeducation projects locally and globally (Invited). In American Geophysical Union, Fall Meeting 2013 (abstract id. ED13F-0813, pp ED13F-0813).
Newsome D & Johnson CP (2013). Potential Geotourism and the Prospect of Raising Aware- ness About Geoheritage and Environment on Mauritius. Geoheritage. 5(1):1-9. https://doi. org/10.1007/s12371-012-0070-4
Nieto-Torres A, Espinasa-Pereña R & Martin Del Pozzo AL (2022). The Xitle lava tubes in Méx- ico City, conservation or destruction? Geoher- itage. 14: 66. https://doi.org/10.1007/s12371- 022-00702-y
Ozkaymak C, Yildiz A, Karabasoglu A, Bag- ci M & Basaran C (2017). Determination of geoturism potential of Seydiler and Nearby Area (Afyonkarahisar, Turkey). Turkiye Jeo- loji Bulteni-Geological Bulletin of Turkey. 60(3):259-282. doi:10.25288/tjb.325426
Pál M & Albert G (2021a). Examining the spatial variability of geosite assessment and its rele- vance in geosite management. Geoheritage.
13(1): 8. https://doi.org/10.1007/s12371-020-
00528-6
Pál M & Albert G (2021b). Refinement propos- als for geodiversity assessment—a case study in the Bakony–Balaton UNESCO Global Geopark, Hungary. ISPRS International Jour- nal of Geo-Information. 10(8).
Pena L, Monge-Ganuzas M, Onaindia M, Fer- nandez de Manuel B & Mendia M (2017). A holistic approach including biological and geological criteria for integrative management in protected areas. Environmental Manage- ment. 59(2):325-337. https://doi.org/10.1007/ s00267-016-0781-4
Petrosino P, Iavarone R & Alberico I (2019). Enhancing social resilience through fruition of geological heritage in the Vesuvio National Park. Geoheritage. 11:2005-2024. https://doi. org/10.1007/s12371-019-00404-y
Pourfaraj A, Ghaderi E, Jomehpour M & Fer- dowsi S (2020). Conservation management of geotourism attractions in tourism destinations. Geoheritage. 12: 80. https://doi.org/10.1007/ s12371-020-00500-4
Quesada-Roman A, Zangmo GT & Perez-Umana D (2020). Geomorphosite comparative anal- ysis in Costa Rica and Cameroon Volcanoes. Geoheritage. 12:90. https://doi.org/10.1007/ s12371-020-00515-x
Raska P, Pokorny R, Krmicek L, Kubouskova S & Mortensen L (2019). Basaltic dyke with specific volcanogenic structures and its geo- morphic evolution: unique geoheritage of the Faroe Islands (North Atlantic Ocean). Geoher- itage. 11(2):417-426. https://doi.org/10.1007/ s12371-018-0296-x
Rito C, Boretto G, Bazzano G & Cioccale M (2022). Assessment of geomorphodiversi- ty and the impacts of urban growth in Puer- to Madryn, Patagonia, Argentina. Journal of South American Earth Sciences. 119. https://
doi.org/10.1016/j.jsames.2022.104018 Rodrigues Ferreira AR, Santos Lobo HA & de Je-
sus Perinotto JA (2019). Inventory and quan- tification of geosites in the State Tourist Park of Alto Ribeira (PETAR, Sao Paulo State, Brazil). Geoheritage. 11:783-792. https://doi. org/10.1007/s12371-018-0331-y
Sabtan AA & Shehata WM (2000). Evaluation of engineering properties of scoria in cen- tral Harrat Rahat, Saudi Arabia. Bulletin of Engineering Geology and the Environ- ment. 59(3):219-225. https://doi.org/10.1007/ s1006400000.61
Sallam ES, Ruban DA & Ermolaev VA (2022). Geoheritage resources and new direction of infrastructural growth in Egypt: From geosite assessment to policy development. Resources Policy. 79. https://doi.org/10.1016/j.resour- pol.2022.103127
Santos DS, Mansur KL, Gonçalves JB, Arruda ERJ & Manosso FC (2017). Quantitative as- sessment of geodiversity and urban growth impacts in Armação dos Búzios, Rio de Janei- ro, Brazil. Applied Geography. 85: 184-195. https://doi.org/10.1016/j.apgeog.2017.03.009
Sayed OH & Masrahi YS (2023). Climatology and phytogeography of Saudi Arabia. A review. Arid Land Research and Management. 37(3): 311-368. https://doi.org/10.1080/15324982.20
23.2169846.
Sheth H, Samant H, Patel V & D’Souza J (2017). The volcanic geoheritage of the Elephanta Caves, Deccan Traps, Western India. Geoher- itage. 9(3):359-372. https://doi.org/10.1007/ s12371-016-0214-z
Shik KE, Chul YY & Chang LS (2014). A study on restoration plans of Jeju Hanon Maar Crater. WEIS (World Environment and Is- land Studies). [http://islandstudies.net/weis/ weis_2014v04/v04n2_Keith_et_al_A.pdf – re-
tried on 14 February 2023] 4(2):45-82 Showstack R (2015). New commission aims
to protect volcanic geoheritage. EOS 96. doi:10.1029/2015EO032343.
Singtuen V & Anumart A (2022). Characterisa- tion and evaluation of columnar basalt geoher- itage in Thailand: Implication for geotourism management in post-quarrying area. Quaes- tiones Geographicae. 41(1):37-50. https://doi. org/10.2478/quageo-2022-0003
Smith IEM & Németh K (2017). Source to sur- face model of monogenetic volcanism: a crit- ical review In Németh K, Carrasco-Nuñez G, Aranda-Gomez JJ & Smith IEM (eds) Mono- genetic Volcanism (pp 1-28). The Geological Society Publishing House, Bath, UK. https:// doi.org/10.1144/SP446.14
Szepesi J, Harangi S, Esik Z, Novák TJ, Lukács R & Soós I (2017). Volcanic geoheritage and geotourism perspectives in Hungary: a case of an UNESCO World Heritage Site, Tokaj Wine Region Historic Cultural Landscape, Hun- gary. Geoheritage. 9(3):329-349. https://doi. org/10.1007/s12371-016-0205-0
Tavares AO, Henriques MH, Domingos A & Bala A (2015). Community involvement in geo- conservation: a conceptual approach based on the geoheritage of south Angola. Sustainabil- ity. 7(5):4893-4918. https://doi.org/10.3390/ su7054893
Tessema GA, Poesen J, Verstraeten G, Van Rom- paey A & Van Der Borg J (2021). The scenic beauty of geosites and its relation to their sci- entific value and geoscience knowledge of tourists: A case study from southeastern Spain. Land. 10(5):460. https://doi.org/10.3390/ land10050460
van Wyk de Vries B (2013). Lemptégy volcano. How a hilltop removal became a major geo-ed- ucational facility. Geological Society of Amer- ica Abstracts with Programs. 45(7):792
van Wyk de Vries B, Marquez A, Herrera R, Granja Bruna JL, Llanes P & Delcamp A (2014). Cra- ters of elevation revisited: forced-folds, bulg- ing and uplift of volcanoes. Bulletin of Volca- nology. 76(11): 875. https://doi.org/10.1007/ s00445-014-0875-x
van Wyk de Vries B, Karátson D, Gouard C, Németh K, Rapprich V & Aydar E (2022). Inverted volcanic relief: Its importance in il- lustrating geological change and its geoheri- tage potential. International Journal of Geo- heritage and Parks. 10(1):47-83. https://doi. org/10.1016/j.ijgeop.2022.02.002
Vereb V, van Wyk de Vries B, Guilbaud M-N & Karátson D (2020). The urban geoheritage of Clermont-Ferrand: from inventory to manage- ment. Quaestiones Geographicae. 39(3):5-3. https://doi.org/10.2478/quageo-2020-0020
Wang L, Tian M, Wen X, Zhao L, Song J, Sun M, Wang H, Lan Y & Sun M (2014). Geocon- servation and geotourism in Arxan-Chaihe Volcano Area, Inner Mongolia, China. Qua- ternary International 349:384-391. https://doi. org/10.1016/j.quaint.2014.06.024
White S & Wakelin-King GA (2014). Earth sci- ences comparative matrix: a comparative method for geoheritage assessment. Geo- graphical Research. 52(2):168-181. https://doi. org/10.1111/1745-5871.12062
Yaseen M, Ghani M, Anjum MN, Sajid M, Jan IU, Mehmood M, Ullah E & Muzaffir W (2019). A novel approach to evaluate, highlight, and
conserve the geologically significant geoher- itage sites from the Peshawar Basin, Khyber Pakhtunkhwa, Pakistan: insights into their geoscientific, educational, and social impor- tance. Geoheritage. 11(4):1461-1474. https:// doi.org/10.1007/s12371-019-00390-1
Yoon SH (2019). Geoheritage value and utiliza- tion plan of the Hanon volcanic crater, Jeju Is- land. Journal of the Geological Society of Ko- rea. 55(3):353-363.
Zacek V, Hradecky P, Kycl P, Sevcik J, Novotny R & Baron I (2017). The Somoto Grand Canyon (Nicaragua) - a volcanic geoheritage site one decade after discovery: from field geological mapping to the promotion of a geopark. Geo- heritage 9(3):299-309. https://doi.org/10.1007/ s12371-017-0221-8
Zangmo GT, Kagou AD, Nkouathio DG, Gountie MD & Kamgang P (2017). The volcanic geo- heritage of the Mount Bamenda Calderas (Cameroon Line): assessment for geotouristic and geoeducational purposes. Geoheritage. 9(3):255-278. https://doi.org/10.1007/s12371-
016-0177-0
Zangmo GT, Kagou AD, Nkouathio DG, Wandji P & Gounte MD (2015). Geomorphological fea- tures of the Manengouba Volcano (Cameroon Line): assets for geotourism and other anthro- pogenic activities. In Errami E, Brocx M & Se- meniuk V (eds) From Geoheritage to Geoparks: Case Studies from Africa and Beyond (pp 183-198). https://doi.org/10.1007/978-3-319-
10708-0_13
