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The atmosphere of Triton in greater detail 20 Apr 2022

Geometry of the 5 October 2017 occultation by Triton. The 90 red and blue lines are "occultation chords", trajectories of the background star relative to Triton, as observed by 90 telescopes across Europe and north East USA. The blue chords produced light curves that had sufficient signal-to-noise ratio to be included in a global atmospheric fit. Image from Figure 5 of the paper described in the text.

A recent paper by J. Marques Oliveira characterises the structure of the atmosphere of Neptune's largest moon Triton in greater detail than before.

In "Constraints on the structure and evolution of Triton’s atmosphere from the 5 October 2017 stellar occultation and previous observations" (Oliveira, Sicardy et al, Astronomy & Astrophysics, Vol. 659, Article A136, March 2022), the authors primarily discuss the occultation of a 12.7-magnitude star by Triton.

Stellar occultations by foreground planets and/or moons can reveal details about the atmosphere of the occulting body. Instead of disappearing suddenly behind Triton at ingress, the background star dimmed more slowly as the increasingly dense layers of Triton's atmosphere moved in front of it. The light curves at both ingress and egress effectively probed the atmospheric layers at those two points above Triton's surface.

As seen from the Earth, Triton passed in front of the star Gaia EDR3 2610107911326516992 (hereafter "G26") just before midnight on 5th October 2017. It cast a shadow that sped across Europe, NW Africa and eastern USA at ~20km/s. More than 100 observatories in the shadow's path attempted to observe the occultation. Ninety light curves were produced, of which three (one from the LT's RISE fast-readout camera) had the best signal-to-noise ratio and were used for determining a detailed model of the atmosphere's density, pressure and temperature. They found a slight negative temperature gradient below ~30km altitude, implying a mesosphere just above an expected stratosphere, with a positive temperature gradient connecting the atmosphere to the cold surface.

Adding the next best 49 light curves enabled the creation of a synthetic and smoothed model of the density, pressure and temperature profiles, from an altitude of 47km down to the surface.

Occultation lightcurve taken with the LT's RISE fast-readout camera. Image from Figure 6 of the paper.

There have now been five occultation measurements of Triton's atmosphere, the first being in 1989 obtained by observing Voyager 2's radio signals as it passed behind the moon. A survey of all five measurements show that a transient pressure increase reported from a single chord transit in 1989 (and absent in the authors' 2017 data) was probably real, but remains debatable. This is due to the scarcity of high SNR light curves, and the lack of a fully consistent analysis of the best data sets used by other teams. The authors also explored a volatile transport model (VTM) by another author and found it supported only a modest increase of surface pressure over the same time period.

This VTM also concludes that for the pressure increase to be both weak and then absent by 2017, there must be N2 present between the equator and latitude 30°S, and a north polar cap extending as far south as 45°N.

Near the centre line of the shadow path, 42 observatories in northern Italy, the south of France, and central Spain observed a flash at mid-occultation as light from G26 refracted around Triton's atmosphere. Twenty-three of the light curves had a high enough signal-to-noise ratio to enable measurements that showed the atmosphere is spherical, with only a slight possibility of gravity waves. This implies that it's unlikely there are any supersonic winds in Triton's atmosphere.

Further work based on the occultation data will investigate these gravity waves, as well as the possible presence of haze layers and of a troposphere just above Triton's surface.

First maintenance on LT in two years 30 Mar 2022

The Liverpool Telescope, March 2022. Image ©2022 Iain Steele.

Summary

• Many long overdue mechanical, hydraulic, pneumatic and electrical maintenance tasks, to ensure continued reliability.
• Horizon limit lowered from 35° to 26° elevation
• Mirrors cleaned, increasing zeropoint by 0.5 magnitudes
• New photometric shutter reduces minimum recommended integration with IO:O from 20s to 0.01s

Due to travel restrictions imposed by a global pandemic and a volcano on La Palma, it had been two years since the last maintenance trip from Liverpool to the LT. Fortunately due to the remote efforts of LT staff and on-site support by Dirk Raback, the telescope continued to observe over that time.

By early this year a large list of things to do had nonetheless built up and a maintenance trip was very welcome. Travel restrictions eased in March, and on the 10th telescope director Iain Steele and engineering manager Stuart Bates flew to La Palma for two weeks to address the most pressing items.

Part of the telescope's altitude axis encoder tape had become contaminated with "calima" dust from the Sahara, preventing observations below an altitude of 35°. This tape was cleaned, restoring observations down to 26° altitude.

The telescope focuses by adjusting the position of the secondary mirror, and the machine control system that governs this needed replacing. This wasn't a simple task as it sits inside the secondary mirror enclosure at the top of the telescope. By erecting scaffolding inside the enclosure and tilting the telescope down to meet it, the control unit was replaced.

Primary mirror being cleaned by Stuart Bates.

Over two years the primary mirror had built up a coating of calima that reduced reflectivity to 55%. It wasn't possible to strip and recoat the mirror with a fresh layer of aluminium, so it was washed instead. "Washing" actually consisted of very carefully dabbing the surface with cotton wool soaked with a cleaning solution.

The Acquisition and Guidance ("A&G") box, the structure that the instruments are mounted on, had been removed along with the instruments in anticipation of removing the primary mirror for cleaning. However a cold snap at the mountaintop meant the roads were too icy for the crane to drive up from sea level, so the mirror had to be cleaned in-situ. This made the task more difficult but not impossible. It took two days, but reflectivity was increased to 76%. While the A&G box was off the telescope, the science fold (tertiary) mirror was also cleaned, improving its reflectivity from 63% to 83%.

IO:O's iris shutter was replaced with a travelling-curtain shutter. As well as providing more even illumination for short exposures, integration times as small as 1 millisecond are now possible (10ms recommended for photometry). This means targets much brighter than before are now potentially observable with IO:O. MOPTOP's cameras were replaced with more robust models that should cope better with the dusty calima environment.

There are more maintenance tasks to do, and they will be addressed in future site visits through the year.

Tracking the JWST 21 Jan 2022

Artist's impression of JWST.

It's well-known that the LT is designed to observe transient natural sidereal phenomena (e.g. supernovae, gamma-ray bursts, optical counterparts of gravity wave events) and non-sidereal targets (near-Earth asteroids and comets). However, it can also track some artificial satellites and spacecraft too, one example being the Gaia space observatory. Since its launch in 2013, Gaia has been tracked by the LT to monitor its position accurately in its halo orbit about a special position in space known as the second Sun-Earth Lagrange point (L2).

This position is one of five Lagrange points in the Sun-Earth co-rotating orbital plane where the gravitational forces of both bodies balance each other. A spacecraft placed at any of them needs very little orbit correction fuel to maintain its position relative to Earth. L2 lies ~1.5 million kilometres "behind" the Earth as seen from the Sun, about four times further away than the Moon. That area is becoming an increasingly-preferred location for space observatories. From L2 (or a halo orbit around it) both Earth and Sun appear close together, so it's much easier to thermally shield temperature-sensitive telescopes from both bodies.

A few weeks ago one of the most exciting telescope-related events of 2021 was the launch of the James Webb Space Telescope (JWST). It began its journey with an accurate launch into L2 transfer orbit at 12:20UT on 25th December 2021, and was observed by the LT that night. By then JWST was 139,000km above the Atlantic Ocean, and still moving at over 2.1 km/s relative to the Earth's centre.

Top: The JWST is the streak near the centre of this 60-second LT image taken early 26th December 2021. Bottom: Animation of ten 10-second LT images of JWST, taken on 11th January 2022. See text for more details of both images. Credit: LJMU/LT/J.Marchant

The LT imaged JWST again on 11th January 2022 in a sequence of ten 10-second images. By then it was 1.14 million kilometres away and considerably slower, moving at just ~300 metres/second. Both image sets featured here were taken using the LT's IO:O instrument, the facility's main workhorse imager.

JWST is a revolutionary telescope, and astronomers and engineers across the world have waited patiently for its completion and launch for many years. Because they're located outside Earth's atmosphere, space observatories like the Hubble Space Telescope (HST) and JWST avoid the filtering and turbulent effects of the atmosphere and obtain the best view of the Universe for a telescope of that size.

The HST with its 2.4-metre primary mirror has provided astronomers with incredibly deep images of distant galaxies, but JWST will have a 6.5 metre mirror, capable of catching more photons and therefore probing even further into the depths of our Universe.

The JWST will look back over 13.5 billion years at our Universe in optical and infrared wavelengths and explore the formation of the first stars and galaxies. As JWST is designed to allow for measurements at infrared wavelengths, it is perfectly primed to see through the dust enshrouding many objects in the Universe such as stars and planetary systems. JWST will also explore distant exoplanet systems and objects within our own Solar System.

At time of writing, JWST has successfully deployed its sunshield and primary mirror, and is on course for starting its manoeuvre on 23rd January to enter L2 halo orbit. This rocket burn corrects any residual trajectory errors and adjusts the final L2 orbit. Due mainly to the accuracy of the launch however, less propellant will be needed for midcourse corrections than expected. The extra fuel remaining can therefore be used for stationkeeping and momentum management/attitude control instead, effectively extending JWST's stay at L2 from its original estimate of maybe 10 years to perhaps as much as 20 years.

Liverpool Telescope Unveils a New Type of Cosmic Explosion, Possibly Linked to Black Hole Formation 12 Jan 2022

Hubble Space Telescope image of the star WR 124, surrounded by hot clumps of its own outer atmosphere ejected into space by fierce stellar winds over the last ten thousand years. This star is similar to those which created the supernovae SN 2021csp and SN 2019hgp mentioned in the text. Credits: original image ©1998 NASA/ESA, reprocessed version ©2015 Judy Schmidt.

Liverpool Telescope observations have helped to unveil a previously unknown class of cosmic explosion.

Exactly what happens to the most massive stars at the end of their lives has long been mysterious. From observations of stellar populations within our own Milky Way galaxy and its neighbours, we know that many such stars lose their outer hydrogen layers to become Wolf-Rayet stars — very hot and luminous stars that are rapidly shedding material into space in high-velocity winds. Some models predict that such stars should eventually collapse to form black holes, but observational evidence of this has so far been lacking.

In work recently published in Nature and soon to be published in the Astrophysical Journal [preprint], a team of astronomers used the Liverpool Telescope (LT) alongside other facilities worldwide to identify a new class of supernova — dubbed type "Icn" — that may reveal this transition.

The first such event (known as SN 2019hgp) was discovered in 2019 by the Zwicky Transient Facility (ZTF), a survey telescope in California. LT astronomers were able to obtain follow-up imaging observations (with IO:O) and spectroscopy (with SPRAT) within a day of discovery, giving crucial insight into the early phases of the explosion. The spectrum of the supernova was dominated by narrow lines of highly-excited carbon, oxygen, and neon — a combination never seen before in any cosmic transient. The properties of these lines suggested that material ejected at high velocities by a dying star had slammed into a dense sphere of carbon and oxygen rich material, much as one would expect from the explosion of a Wolf-Rayet star. The study of this event has recently been published in Nature by a team led by Avishay Gal-Yam, a scientist at the Weizmann Institute for Science in Israel.

The second event (known as SN 2021csp) was discovered in February 2021, also by ZTF. The Liverpool Telescope was the first facility on the scene after discovery, again acquiring SPRAT and IO:O observations that showed a fast and luminous supernova with strong, narrow carbon and oxygen lines — much like in SN 2019hgp. This provided the impetus for an LJMU-led team to quickly obtain crucial ultraviolet observations from the Hubble Space Telescope before the source faded away, providing even stronger evidence in favor of a Wolf-Rayet like progenitor. Additionally, continued observations from the Nordic Optical Telescope (one of the Liverpool Telescope's "neighbours" on the island of La Palma) showed the explosion to fade away almost to nothing within just two months — quite unlike normal supernovae, which take years to fade. The team interpreted this as evidence that most of the star's mass had collapsed into a black hole, rather than being ejected into space. This study was led by Daniel Perley, a staff member at LJMU's Astrophysics Research Institute, and has recently been accepted by the Astrophysical Journal [preprint].

Together, these two events suggest a new scenario for the fates of the most massive stars: they may produce a special kind of fast and fleeting supernova dominated by interaction between a small amount of material ejected outward early in the collapse and the pre-existing Wolf-Rayet stellar wind.

Type Icn supernovae are rare events and cannot on their own represent the deaths of all Wolf-Rayet stars. However, luminous events like SN 2019hgp and SN 2021csp may be just the tip of the iceberg: "If a similar explosion occurred, but the material was expelled more slowly or if the Wolf-Rayet wind was weaker, we would never know it even happened," points out Dr Perley.

Future, more sensitive surveys — such as with the upcoming Vera Rubin Observatory coupled to follow-up facilities like the New Robotic Telescope — will have a chance of unveiling such "hidden" transients in the coming years.

Monitoring Maintenance in Geostationary Orbit 3 Nov 2021

Artist's impression of MEV-1 (silver satellite at right) docked with Intelsat-901 (gold satellite). Credit: Northrop Grumman / Space Logistics.

For the first time, remote-controlled spacecraft have begun servicing communications and Earth observation satellites in geostationary orbit to extend the amount of time they can remain in service.

Geostationary Earth Orbit (GEO), a circular equatorial orbit at an altitude of 35,786km, allows a satellite placed there to remain apparently fixed over a point on the Earth's surface. Being very useful for communications, navigation and Earth observation, this orbit has become home to hundreds of satellites from many nations over the decades. These "GEOsats" use onboard propellant for attitude control and to maintain their exact position in orbit ("stationkeeping"). Over the years this fuel runs out, and so using the last dregs, the otherwise still-functional satellite is consigned to a "graveyard orbit" some 300km higher than GEO, where it is switched off.

In recent years however it has become feasible to start sending servicing spacecraft to rendezvous with near-empty GEOsats, and perform on-orbit servicing and mission extension activities, such as taking over stationkeeping duties. Many companies are now beginning to offer these services.

The first of these companies to launch a servicing mission was SpaceLogistics, a wholly-owned subsidiary of Northrop Grumman. It began operating its Mission Extension Vehicle (MEV) fleet of commercial on-orbit servicing spacecraft in 2019-2020.

Once launched into an initial elliptical orbit, a MEV would spend months using its electric propulsion system near-continuously to raise and circularise its orbit to match that of its target client satellite. After some time in rendezvous and proximity operations (RPO), a MEV would use telerobotics to dock with the satellite. It would then use its own propulsion system to take over manoeuvering and attitude control duties, extending the satellite's functional lifetime for however long the client wished. The MEVs have enough fuel to service several satellites in this way, and can move from one satellite to another as and when client contracts dictate.

The first two missions were monitored by a coalition of optical and radio ground-based facilities. Tasks included determining MEV/client detection and tracking capabilities, and maintaining continuous coverage by autonomously networking time-critical information between observing stations.

IO:O image of MEV-2 and Intelsat 10-02, 1.5km apart, during approach and docking.
Credit: LJMU, UoL.

The first MEV mission in 2019-2020 saw "MEV-1" return Intelsat 901 back to active service. This satellite had been dormant for some time in graveyard orbit. MEV-1 repositioned Intelsat 901 back into geostationary orbit, where it will remain in service for several years until completion of contract. MEV-1 will then put it back where it came from and move on to the next client. Lessons learned during observations of this mission were applied to those of the "MEV-2" mission in 2020-2021.

The MEV-2 mission saw the first servicing of an active satellite in GEO, Intelsat 10-02. MEV-2's orbit-raising manoeuvres to GEO were followed closely by the coalition, which for this mission included the LT using its IO:O hi-res camera. The LT became involved through a request from the University of Liverpool (UoL) who had been involved with the coalition for some time. IO:O also provided imagery for the RPO phase of the mission, where MEV-2 circled Intelsat 10-02 at close quarters and then docked. Observations by the LT and others in the coalition also proved that during RPO the two satellites could still be separated in the data using spectroscopy and polarimetry.

These observations are described in detail in a recent paper by George, S., et al: "PHANTOM ECHOES 2: A Five-Eyes SDA Experiment on GEO Proximity Operations", Proceedings of Advanced Maui Optical and Space Surveillance Technologies Conference (AMOS) Conference 2021 [download paper].

At the same time, a separate team used the LT's MOPTOP polarimeter to also observe the spacecraft in polarised light, both before and after docking. The team, led by Klaas Wiersema and Paul Chote of University of Warwick Astronomy and Astrophysics Group found the two spacecraft could be well separated in the data. Observations continued for several weeks after docking so that the polarimetric signature of the "combined stack" could be compared to those of the separate spacecraft previously.

Their data shows the polarisation of MEV-2 and Intelsat 10-02 does indeed differ after docking. The team will now compare the measured polarisation values as a function of viewing angle, with detailed numerical models of the reflection off the flat solar panels and main body. Comparing them to the known orientation of the satellites will determine if polarisation observations can indeed provide independent measurements of spacecraft orientations.

David Carter 24 May 2021
Dave Carter at the LT construction site around 2001.

We are sad to report the death over the weekend of our friend and colleague Professor David Carter. Dave obtained his PhD from the Institute of Astronomy, Cambridge in 1977 working on the surface brightness profiles of galaxies. He subsequently worked at the University of Oxford and the Anglo-Australian, Mount Stromlo and Siding Spring Observatories, before moving on to the Isaac Newton Group on La Palma and at RGO Cambridge where he combined his research with involvement in cutting edge instrumentation.

Dave joined LJMU in 1996 as Project Scientist for the Liverpool Telescope and his determined efforts played a large part in keeping the project on track during a difficult construction phase. He was an outstanding scientist who always took a constructively sceptical approach to the prevailing consensus, and an excellent mentor to younger colleagues and students. He was also a keen cricketer!

Dave took early retirement from LJMU in 2012 but continued to work on the major HST/ACS Coma Cluster survey he established as well as being a regular participant in group seminars and journal clubs. This also gave him the opportunity to step up his work at the Neston Methodist Church and Community Centre and become a local parish councillor. Dave was a great family man, and we send our condolences to his wife and three sons at this difficult time. He will be sadly missed by all.

Walk around the LT site 25 Mar 2021

A scene from the site tour, featuring navigation icons, the site annexe/workshop on the left, and the telescope enclosure on the right. Click the image to go to the Site Tour page.

A virtual tour of the Liverpool Telescope site in La Palma is on this website at the Site Tour page. You can walk around the site, even into the telescope enclosure itself, and switch between day and night views.

Liverpool John Moores University's Press Office approached the LT group with a 360° camera and the suggestion we could borrow it to promote the telescope in any way we liked. We decided to use the camera to make a "Google Streetview" style tour around the site.

The images were made with a RICOH Theta S camera during a site maintenance trip in July 2019. They were processed into a tour using the Holobuilder interface (an adapted version of which also hosts the tour) and released on the website in October 2020. It's planned to integrate this tour into Google Streetview in the future.

Two new nova shells discovered 5 Mar 2021

Artist's impression of classical nova. Hydrogen spiralling onto the white dwarf's surface from the red giant has just ignited. See text for details.
Image credit: David A. Hardy www.astroart.org

The expanding debris shells from two separate novae that were seen to erupt decades ago, have been discovered and characterised in the recent paper "Two new nova shells associated with V4362 Sagittarii and DO Aquilae", Harvey et al, Monthly Notices of the Royal Astronomical Society (MNRAS), Vol 499, Issue 2, December 2020 (doi: 10.1093/mnras/staa2896).

Because these nova shells are big enough to make out their structure, they are rare objects and of great interest to astronomers. That's because analysis of the debris shells' shapes can reveal insights into the mechanics of the nova eruptions that created them, and also shed light on conditions leading up to the event.

##### Classical novae

Classical novae occur in close stellar binary systems, with one star a white dwarf and a main sequence star as its companion. The stars are close enough that hydrogen from the companion's outer layers can transfer over to the white dwarf and spiral down to its surface, forming an accretion disk as it does so (see illustration at right).

The infalling hydrogen forms a shallow hydrogen atmosphere at tremendous pressure and temperature. Over time as more hydrogen builds up, pressures and temperatures in the lower layers build up to the point where a runaway thermonuclear reaction starts. The bottom of the white dwarf's atmosphere ignites; heat released from the hydrogen fusing to helium raises the temperature further, increasing the fusion rate and driving the reaction more. This is the third most energetic stellar explosion in nature, and the energy release blows out the remaining atmosphere at speeds of 1000 km/s or more.

This debris of unburnt hydrogen and thermonuclear reaction products flies away from the binary system as an expanding shell. However, rather than being a perfect sphere, the shells that can be made out from Earth take the form of an axisymmetric set of zones. Usually the pattern is one of an equatorial belt and polar cones, but often more complex shapes are formed.

##### Rare specimens

Classical novae are actually non-destructive — both stars survive the event. This leaves them in place for the accretion process to begin again, potentially leading to another nova many years later. It's thought about 50 novae occur every year in the Milky Way galaxy alone, though fewer are actually observed due to intervening dust and gas obscuring the view.

Novae have also been observed in other galaxies, identified as such by their lightcurves and spectra, but none are close enough to make out any shells they might have. Of the few hundred novae in the Milky Way observed over the years, of order only 50 have discernible shells, so only that many sources of extra clues to the inner workings of novae have been observed and characterised. Any addition to this rare subgroup is therefore noteworthy, and the two new shells discussed in the paper by Harvey at al certainly qualify.

##### Observations

The team selected 12 reasonably bright nova systems that erupted more than 15 years before the start of the survey in 2015. Those regions had previously been scanned by the Wide-Field Infrared Survey Explorer (WISE) space telescope as part of its all-sky survey, and showed plausible hints of nebulosity. They then performed deeper narrowband imaging using the 3.2m Aristarchos telescope in H-alpha plus NII (6578A) and OIII (5011A) bands. Shells were found around two systems, V4362 Sagittarii and DO Aquilae.

The Liverpool Telescope's SPRAT spectrograph was used to apply velocity constraints and first-pass nebular analysis of the shells. Hi-resolution spectra were obtained of the V4362 Sgr nova shell using the second version of the Manchester Echelle Spectrograph, installed on the San Pedro Mártir Observatory 2.1m telescope.

DO Aquilae

Narrowband images of DO Aquilae and V4362 Sagittarii taken in 2016 & 2017 by Harvey et al using the Aristarchos 3.2m telescope. This image adapted from Figures 3 & 4 in the paper. Click image for bigger version.

DO Aquilae (DO Aql) was observed to go nova in 1925. The observations in this study, made in 2015 & 2017, reveal a previously undiscovered nova shell, expanding at a rate of about 0.07 arcseconds/year. The team estimate this system to be 6.7±3.5 kiloparsecs (22±11 thousand light years) distant.

V4362 Sagittarii

V4362 Sagittarii (V4362 Sgr) was discovered in 1994. Observations made two months later of polarised light emitted by the shell suggested it was axisymmetric, and possibly consisting of a circular equatorial ring and narrow conical polar caps.

Harvey et al processed data from the 1.3m Skinakas Telescope in Crete made in 2006, and found the nova shell back then to be 2.5x3.1 arcseconds in size, in Halpha+NII narrowband imagery. The 2016 data obtained with the Aristarchos telescope gave dimensions as 5.2x5.6" in Hα+NII and 5.2x5.5" in OIII, implying an expansion rate of 0.32 arcseconds/year.

The probable inclination of the system is 70-80°, based on lightcurves taken in 2018 with the RISE2 instrument on the Aristarchos telescope that suggest the system is eclipsing. If eclipses are observed then the system is probably being viewed nearly edge-on to the plane of its orbit. However, eclipses don't always mean edge-on viewing, so more detailed observations of this system are needed to make sure.

Spectral measurements show the shell velocity is relatively slow at just 350 km/s, rather than the average 1000 km/s. Coupling that with the observed increase in angular diameter over a known period of time and taking due notice of the shell's non-sphericity (the expansion parallax method), the distance to the system is found to be just $$0.5_{-0.2}^{+1.4}$$ kiloparsecs (between 1-6 thousand light years), making it one of the closest and brightest nova shells known.

Detail adapted from Figure 12 of the paper, showing a model of the shell's emission in the NII and OIII lines, see text for more details. The full figure shows the shell in other wavelengths and viewing angles. Click image for bigger version.

The shell of V4362 Sgr is poorly resolved in the Aristarchos imagery, so the team tried to visualise its shape and dynamics. They settled on a morphology of an equatorial belt, tropical rings and polar cones. The image at right shows a pseudo-3D photoionisation model of the shell's structure seen from an angle 10° above the orbit plane. There are two views, showing the shell in the light of singly-ionised nitrogen ("NII") at 6584Å, and doubly-ionised oxygen ("OIII") at 5007Å. The model replicates the ratio of NII to OIII emission observed. Note the NII emission structure is larger than the OIII, which is often seen in nova shells. The NII structure's more extended polar caps in this model may be why the real thing is so bright at these wavelengths.

##### Summing up

This paper shows that new nova shells can be found from archive data and new limited multi-epoch followup data from small to medium-sized research telescopes — two previously unknown nova shells were discovered and characterised in this way.

There are potentially very many nova shells remaining to be discovered, because (a) so far only 10% of the observed nova system population of the Milky Way galaxy are known to have shells, and (b) it should be possible to detect and determine the structure of more shells if larger aperture and/or space-based telescopes are used.

Because the processes at play during nova events leave their fingerprints in the shell's structure, and nova systems previously thought to be shell-less might actually harbour shells after all, the authors would like there to be more deep followup observations of historical novae. Untangling the geometry of new shell structures would lead not only to a better understanding of the geometry, ionisation conditions and abundances of chemicals in the nova systems, but also reveal information on the chemical enrichment of the interstellar medium through elements created during the thermonuclear process in the nova events themselves.